Post on 09-Jul-2022
IMAGING OF THE FETAL CENTRAL NERVOUS SYSTEM
Lou Pistorius
IMAGING OF THE FETAL CENTRAL NERVOUS SYSTEM
Beeldvorming van het foetale centrale zenuwstelsel
(met een samenvatting in het Nederlands)
Proefschrift
ter verkrijging van de graad van doctor aan de Universiteit Utrecht op gezag van
de rector magnificus, prof. dr. J.C. Stoof, ingevolge het besluit van het college voor
promoties in het openbaar te verdedigen op dinsdag 11 november 2008 des middags
te 4:15 uur
door
Lourens Rasmus Pistorius
geboren op 27 april 1963 te Potchefstroom, Zuid Afrika
Promotoren: Prof.dr. G.H.A. Visser
Prof.dr. L.S. de Vries
Co-promotoren: Dr. R.H.J.M. Gooskens
Dr. F. Groenendaal
Dr. Ph. Stoutenbeek
ISBN: 978-90-393-49380
Layout and
publishing by: Gildeprint Drukkerijen B.V., Enschede, The Netherlands
Front page: Imagining the fetal brain (mola patchwork by Ronel Pistorius)
Publication of this thesis was financially supported by the University Medical Centre
Utrecht, BMA BV (Mosos), General Electric Healthcare and Toshiba Medical Systems.
Ek kry ‘n klein beiteltjie,
ek tik hom en hy klink;
toe slyp ek en ek slyp hom
totdat hy klink en blink.
N.P. van Wyk Louw
Vir Ronel, Wilma en Hantie
J
CONTENTS
Introduction 9
CHAPTER 1: Aims of the thesis 11
CHAPTER 2. Fetal neuro-imaging: ultrasound, MRI, or both? 15
Obstet Gynecol Survey 2008, in press
Physiology 45
CHAPTER 3. First trimester neurosonoembryology with automated follicle 47
tracking: Preliminary fi ndings
J Matern Fetal Neonatal Med 2008, in press
CHAPTER 4. Grade and symmetry of normal fetal cortical development: 55
a longitudinal two and three dimensional ultrasound study
Ultrasound Obstet Gynecol (provisionally accepted)
CHAPTER 5. A longitudinal ultrasound study of the size and symmetry 79
of the fetal lateral cerebral ventricles
Submitted
CHAPTER 6. Fetal cerebellar volume and symmetry on three-dimensional 95
ultrasound: volume measurement with multiplanar and VOCAL techniques
Ultrasound Med Biol 2008 (in press))
Pathology 109
CHAPTER 7. The role of prenatal ultrasound in predicting survival and 111
mental and motor functioning in children with spina bifi da
Ultrasound Obstet Gynecol 2008 (in press)
CHAPTER 8. Middle cerebral artery pulsatility index in fetal central nervous 127
system abnormalities
Ultrasound Obstet Gynecol (under revision)
CHAPTER 9. Disturbance of cerebral migration following congenital 141
Parvovirus B19 infection
Fetal Diagn Ther 2008 (in press)
CHAPTER 10. Fetal central nervous system abnormalities: ultrasound, 151
MRI or multidisciplinary discussions?
Submitted
CHAPTER 11. Lactate to Creatinine Ratio in Amniotic Fluid: a Pilot Study 163
Submitted
Summary 171
CHAPTER 12. General discussion and recommendations 173
Appendix 183
Nederlandse samenvatting 184
Afrikaanse opsomming 192
Acknowledgments 201
Curriculum vitae 203
List of publications 205
INTRODUCTION
Chapter 1AIMS OF THE THESIS
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The fetal brain is the most complex organ and one that carries on developing in size,
intricacy and function throughout all three trimesters of pregnancy (and certainly
thereafter!) The fetal central nervous system and other fetal organs can be visualized
in increasingly fi ne detail as imaging equipment becomes ever more sophisticated. This
answers many questions, but continually poses new ones, as we have to re-evaluate
accepted knowledge in the light of new fi ndings. This forms the basis of this thesis:
an investigation of imaging of normal and abnormal development of the fetal central
nervous system.
INTRODUCTION
Chapter 2: review of the literature to evaluate the knowledge and gaps in the available
knowledge about ultrasound (US) and magnetic resonance imaging (MRI) imaging of
normal and abnormal development of the fetal central nervous system. We attempted
to identify the strengths and weaknesses of each modality from the literature, and to
arrive at practical recommendations for which conditions and at which gestational
age ultrasound, MRI or both would be most suitable.
PHYSIOLOGY
Chapter 3: to determine whether new ultrasound hardware and software can facilitate
imaging of fetal brain development in the late embryological period.
Chapter 4: evaluation of the grade and symmetry of cortical development in the latter
half of pregnancy as demonstrated in a longitudinal ultrasound study and to evaluate
whether three dimensional or two dimensional ultrasound is more reproducible or
time-consuming.
Chapter 5: assessment of the size and symmetry of the lateral cerebral ventricles in
the latter half of pregnancy as demonstrated in a longitudinal ultrasound study, and
to evaluate whether new technical developments such as volume contrast imaging are
more useful or reproducible than traditional methods.
Chapter 6: measurement of the fetal cerebellar volume and symmetry in the latter
half of pregnancy as demonstrated in a longitudinal ultrasound study, and to evaluate
which method of volume measurement has the best inter observer agreement.
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PATHOLOGY
Chapter 7: evaluation of the prediction of survival and mental and motor functioning
in children with spina bifi da by means of prenatal ultrasound imaging, and whether
the accuracy in determining the lesion level has improved with new, high resolution
and 3D equipment.
Chapter 8: investigation of the prognostic value of Doppler ultrasound measurement
of blood fl ow in the middle cerebral artery in fetuses with central nervous system
abnormalities.
Chapter 9: presentation of a case of a fetus who developed malformations of cortical
development after requiring intra-uterine transfusion for a severe Parvovirus B19
infection. This serves as introduction to the next aim, namely:
Chapter 10: evaluation whether the diagnosis made with ultrasound, with MRI or
during a multidisciplinary discussion was more accurate in diagnosing complex fetal
central nervous system abnormalities in a retrospective cohort.
Chapter 11: preliminary examination of the possibility to determine the degree of fetal
asphyxia by MR spectroscopy by measuring amniotic fl uid lactate levels.
Chapter 2FETAL NEURO-IMAGING:
ULTRASOUND, MRI, OR BOTH?
L. R. Pistorius1, P. M. Hellmann1, G.H.A. Visser1, G. Malinger2, D. Prayer3
1Department of Obstetrics, Division Perinatology and Gynaecology, University Medical Centre Utrecht, The Netherlands
2Prenatal Diagnosis Unit, and Fetal Neurology Clinic, Edith Wolfson Medical Center, Holon, Israel3Department of Neuroradiology, University Clinic of Radiodiagnostics, Vienna, Austria
Obstet Gynecol Survey 2008, in press
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ABSTRACT
Much has been written recently about the relative merits and demerits of fetal imaging
with ultrasound and MRI. Unfortunately, the arguments often generate more heat
than light. We attempted to identify the strengths and weaknesses of each modality
from the literature, and to arrive at some practical recommendations on when to use
which imaging modality.
• In conclusion, combining neurosonography and MRI is mostly redundant, but
occasionally complementary.
• Both are operator dependant and neither technique obviates the need for a thorough
knowledge of normal and abnormal neuro-anatomy.
• In early pregnancy, and where repeated assessment is needed, ultrasound has the
obvious advantage.
• Where ultrasound is diffi cult, as in the obese patient or a patient with severe
oligohydramnios, better images might be obtained by MRI examination, although a
special MR system is required for patients weighing more than 150kg. MRI might also
identify fetal ischemic lesions early after an insult such as severe maternal trauma or
death of a monochorionic co-twin.
• There is a synergy between ultrasound and MRI for the diagnosis of certain conditions,
such as congenital cytomegalovirus infection or cerebellar telangiectasis.
Local conditions and expertise obviously infl uence the accuracy of both modalities.
Both ultrasound and MRI should be performed to the highest possible standard, and
the fi nal diagnosis should be made in a multidisciplinary setting.
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INTRODUCTION
Much has been written about the merits and demerits of fetal imaging with ultrasound
and MRI. The arguments often generate more heat than light. What is needed is an
evaluation of the strengths and weaknesses of each modality as illustrated by the
literature, and practical recommendations on when to use which modality (Table 1) .
Table 1. Recommendations: ultrasound, MRI or a combination of both in fetal brain imaging
Ultrasound preferred: Repeated examinationsScreeningMRI contra-indicated or failedEarly diagnosis (< 20w)Assessment of fetal movements (up to 3rd trimester)Assessment of cerebral blood fl owEvaluation of associated (especially cardiac) abnormalities
MRI preferred: OligohydramniosEngaged fetal head and ruptured membranesAssessment of fetal movements (late 3rd trimester)Detecting and determining age of intracranial bleedingDetecting intracranial tuberous sclerosisSchizencephalyAcute asphyxiaPostmortem brain imagingPosterior fossa abnormalitiesSevere microcephaly
Combination preferred: Suspected cerebellar telangiectasisFetal brain deathCytomegaloviral infectionIntracranial tumorsTraumaVein of Galen abnormalitiesGerminal matrix and intraventricular bleedingSuspected hemimegalencephalySepto-optic dysplasia
Either US or MRI appropriate: VentriculomegalyHoloprosencephaly (after 20 weeks)Corpus callosum abnormalities (after 20 weeks)Craniosynostosis
A detailed description of technical aspects is beyond the scope of this review, but the
basics are explained in a thesaurus (Table 2).
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Table 2. Thesaurus
Ultrasound – see also (1:2)
• How does ultrasound work? Electrical impulses cause piezo-electrical crystals in an ultrasound transducer to produce ultrasound waves. The ultrasound image is generated by the refl ection of ultrasound waves onto the transducer, in which the piezo-electrical crystals translate sound energy again into electrical impulses. These impulses are then depicted on a display and arranged longitudinally according to the amount of time it took since the impulse was sent out, and laterally according to the place on the transducer array where the impulse was received.
• A-mode ultrasound: ultrasound imaging with a one-dimensional display, where the distance between structures producing echoes and the amplitude of the echoes are represented by a graph. This was the only available ultrasound prior to the 1970’s, and is currently used mainly in ophthalmology where precise measurements are required.
• Grey scale: a display where the amplitude of the echo is represented by the intensity of a dot of light on a screen.
• M-mode ultrasound: ultrasound imaging where A-mode ultrasound images are repeated over time and displayed consecutively in a grey scale. This is used for displaying heart muscle and valve leafl et movements.
• B-mode ultrasound: cross-sectional ultrasound imaging with a two-dimensional display – in other words, what most of us are using most of the time.
• 3D ultrasound: ultrasound imaging where ultrasound is acquired as a volume rather than cross-sectional; this can be displayed in multiplanar mode (where three orthogonal, or cross-sectional planes perpendicular to each other, are displayed) or rendered mode, where a volume is displayed as it would appear to the naked eye
• Neurosonogram: a multiplanar ultrasound examination of the central nervous system (CNS), performed where there is an increased risk of a CNS abnormality or where a screening examination was suggestive of CNS abnormality (3)
MRI – see also (4:5)
• How does MRI work?: Normally, individual MR-active atomic nuclei (such as hydrogen nuclei) are randomly aligned, and each has its own magnetic fi eld which is caused by its rotation. When an external magnetic fi eld is applied, the nuclei are aligned parallel or in opposition to the magnetic fi eld. The cumulative magnetic fi eld of all the nuclei is called the net magnetization vector. If a radiofrequency (RF) pulse is applied, the net magnetization vector is fl ipped by a certain angle, with a longitudinal and transverse component. The transverse component induces a current in a receiver coil, which is translated into a MR signal. The nuclei gradually move out of phase and the signal in the coil therefore decreases (or “decays”).
• T1 recovery involves the recovery of longitudinal magnetization because of energy released into the environment.
• T2 decay involves a decrease of the transverse magnetization because of the individual nuclei moving out of phase and interaction of the individual magnetic fi elds.
• Tissue contrast on MRI is the result of differences between T1 recovery, T2 decay and proton (hydrogen nuclei) density.
• Repetition time (TR) is the time between two different RF pulses.• Echo time (TE) is the time from the RF pulse until the MR signal is measured.• With a short TR, the difference between the T1 recovery of water and fat signals is maximal.• With a long TE, the difference between the T2 decay of water and fat signals is maximal.• For T1 weighted imaging, both the TR and TE are therefore short. Water appears hypointense and fat
hyperintense• For T2 weighted imaging, both the TR and TE are therefore long. Water appears hyperintense.• If the TR is long and the TE is short, there is little difference between the T1 recovery or T2 decay of water
and fat, and contrast is due to difference in proton density.• The two fundamental MR pulse sequences are the SE (Spin echo) and GRE (gradient echo)• FLAIR (Fluid attenuated inversion-recovery) is used to suppress the water signal, by applying a RF pulse at
a time when the net magnetization vector of the water signal is very weak therefore enhancing contrast
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in tissues (with a bright signal) and suppressing the water signal (which would appear dark.) STIR (short T1 inversion recovery) is used in a similar way to suppress the fat signal.
• Single shot fast spin echo (SSFSE) and half-Fourier acquisition turbo spin echo (HASTE) are different terms used by different manufacturers of MR systems for essentially the same thing: a multiple-echo variant of SE which allows imaging in a shorter time, enabling fetal MRI without sedation.
• Diffusion weighted imaging (DWI) allows the distinction between protons (or water) diffusing freely or in a restricted way. This is useful to detect anisotropy, where there is a difference of movement in a specifi c direction, such as is the case in premyelinating structures such as the corpus callosum in early pregnancy. DWI is also useful in distinguishing between vasogenic and cytotoxic oedema.
• The ADC (apparent diffusion coeffi cient) is a way of quantifying DWI by means of the ratio of two image sets; one obtained with and one without a diffusion gradient. This can be used or to predict lung maturity by detecting the anisotropy caused by vascularization of terminal tubules.
• Other factors that infl uence the quality of the image include the positioning of the coil, with the receiver ideally positioned directly over the region of interest. A small fi eld of view is optimal (as it allows maximal resolution), but might increase the risk of artefacts.
• The frame rate, or number of images obtained per second, depends on the time to complete one sequence. Dynamic sequences can be obtained at frame rates of up to 6 frames per second, which allow the observation of fetal limb, breathing and swallowing movements.
• The slice thickness refers to the thickness of the slice through the target organ which is averaged to obtain the MRI signal. The thicker the slice, the fewer slices are needed, and the less the total imaging time, but the ability to detect a small structure or lesion decreases.
• MRS (magnetic resonance spectroscopy) provides information on the chemical composition of a target volume. Each different molecule has a different electron cloud, which causes a slight shift in frequency of the magnetic fi eld. This chemical shift is a very small effect, and measured in parts per million (ppm) of the magnetic fi eld. PMRS (Proton MRS) is used to evaluate levels of inositol, choline, aspartate and lactate in the brain, and phosphorus MRS is used to evaluate products of energy metabolism, and estimate pH levels. Because of the tiny effect, the magnetic fi eld has to be calibrated (“shimmed”) very carefully.
• BOLD (blood oxygen level dependant) imaging depends on the difference of magnetic properties of oxyhemoglobin (not magnetic) and deoxyhemoglobin (magnetisable) to generate different MRI signals depending on the oxygen saturation. This can be used to map brain activity (with an increase in deoxyhemoglobin in activated parts of the brain because of an increase in local oxygen consumption).
ULTRASOUND
General aspects
Since the early days of ultrasound, it has been possible to diagnose abnormalities of the
fetal brain using A-mode ultrasound (6). With the advent of B-mode ultrasound, two-
dimensional images of the fetal brain could be obtained. Subsequent improvements
in resolution have been so dramatic that it is now possible to visualize the early
embryonic development of the central nervous system in vivo (7-10). Each new
generation of ultrasound machines is so impressive that it is easy to forget how much
of an improvement the previous generation of machines had been.
The advantages of using three-dimensional ultrasound to evaluate the fetal brain
include the ability to visualize planes which would otherwise be inaccessible and to
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accurately measure the volumes of structures such as the cerebellum (11-13). Three
dimensional ultrasound might thus be more useful than two-dimensional diameters
in diagnosing, monitoring and understanding pathology.
The fetal neurosonogram
Traditionally, the brain was examined in axial planes. Evaluation of these planes
is widely used as a screening tool (14;15). However, examining the brain in coronal
and sagittal planes by aligning the transducer with the fontanelles is also possible,
sometimes by means of gentle manipulation of the fetus (16).
The fetal neurosonogram is a detailed, multiplanar ultrasound examination of
the central nervous system performed by someone with specifi c expertise using
sophisticated equipment. It is performed when there is an increased risk of a CNS
abnormality or when a basic or screening ultrasound examination suggests a CNS
abnormality. If the fetus is in cephalic presentation, transvaginal ultrasonography can
be used to allow higher ultrasound frequencies with a higher resolution. Although
not yet universally applied, fetal neurosonography is of greater diagnostic value than
conventional ultrasound, especially in fetuses with complex malformations (3).
Structural evaluation
It is diffi cult to imagine a part of the fetal brain for which a range of normal values has
not been described by ultrasound imaging. These include the lateral (17), third (18), and
fourth (19) ventricles, corpus callosum (20;21), cavum septum pellucidum (22), cerebellar
diameter and vermis (23;24), cisterna magna (22), pons (25), subarachnoid space (26),
and even the intracranial circulation (27) and patterns of cortical development (28-
31). Using mainly transvaginal ultrasound, it is possible to diagnose CNS pathology as
early as the late fi rst trimester. In addition to exencephaly (32), the presence of Dandy-
Walker malformations (33), an encephalocoele, hydranencephaly or holoprosencephaly
(34-36) have been diagnosed in the fi rst trimester. Later in pregnancy, the range of
brain abnormalities, including malformations of cortical development, which can be
diagnosed by ultrasound, is too great to mention in detail (37).
Evaluation of perfusion
Power or color Doppler ultrasound is useful to delineate vascular lesions such as an
aneurysm of the vein of Galen or other intracranial arteriovenous malformations
(3;38). Decreased regional fl ow in the circle of Willis or carotid artery can help to
determine the origin of pathology such as schizencephaly (39). Evaluation of middle
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cerebral arterial fl ow is widely used in the management of growth-restricted fetuses
and in the diagnosis of fetal anemia (40).
Functional evaluation
Fetal movements are routinely evaluated as part of the biophysical profi le, which
assesses fetal well-being (41). Evaluation of fetal movements can also be used
to asses the integrity of the fetal nervous system (42). Although the assessment
of fetal movements has not yet been adopted as a standard component of fetal
neurosonography (3), it may be used more widely in the near future (43).
Safety
Despite concerns recently raised as result of animal studies (44), there is no evidence
that the human fetus is harmed while performing diagnostic ultrasound according to
the ALARA (as low as reasonably achievable) principle (45).
MAGNETIC RESONANCE IMAGING
General aspects
Despite the advantages of ultrasound, MRI is useful when there is a relative contra-
indication to transvaginal ultrasound such as vaginismus (46) or ruptured membranes
and when it is diffi cult to obtain a good acoustic window transabdominally, such as in a
fetus with a well engaged head or an obese patient. Morbidly obese patients weighing
more than 150kg cannot be examined in a traditional MRI, and have to be examined in
a large bore cylindrical or vertical open MRI system.
MRI tissue contrast is infl uenced by the fat and water content and proton density of
tissues. The signals can be enhanced or suppressed by manipulating the repetition
time or echo time, or by using specifi c techniques to nullify the fat or water signal (4).
Fast, ultra-fast and real-time sequences have made fetal imaging possible without the
need for fetal paralysis (47;48), although sedation is still sometimes used (49-52).
T2 weighted imaging is typically used to demonstrate fetal anatomy. T1 weighted
imaging is useful to depict hemorrhages, calcifi cations or lipomas (5), as well as the
cortical plate, brain stem and basal ganglia in late gestation. Diffusion-weighted
imaging is sensitive for the detection of hypoxic-ischemic brain lesions and useful for
identifying premyelinating structures, such as the corpus callosum, in early pregnancy (5).
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Structural evaluation
The normal development of the cerebral cortex has been well defi ned with fetal MRI
(53). A typical fetal lamination pattern is seen on T1WI from 23 to 28 weeks’ gestation
(54) and refl ects the migration of neurons from the ventricular and subventricular
zones to the cerebral cortex, in which six histological layers can be seen. Growing
pathways that cross in the periventricular region (the “periventricular crossroads”) can
be demonstrated by MRI, especially from 29 to 32 weeks, and are seen as periventricular
echodensities by ultrasound (55). Anatomically, this area is a grid of projection,
commissural and associative fi bers embedded in the extracellular matrix, which is
increased and rich in axonal guidance molecules during this stage of development.
This is the area where periventricular leukomalacia is most likely to develop (56). The
development of gyri is also well described on MRI (57-59). Although myelination occurs
mainly postnatally, white matter tracts can be observed prenatally by anisotropy on
diffusion weighted imaging. In addition, development of the hippocampus, basal
ganglia, brain stem, and cerebellum are all well described by MRI studies (53).
In case of stillbirth or neonatal demise, MRI may be a useful adjunct to autopsy,
by helping to guide sampling for post-mortem histological diagnosis, and may be
particularly useful for evaluation of the central nervous and skeletal systems (60-62).
Evaluation of perfusion, bleeding and ischemia
T1WI is a sensitive modality to detect the presence and the age of an intracranial
hemorrhage (5). An early sub acute bleed gives rise to a hyper-intense signal on T1WI
and a hypo-intense signal on T2WI (63). Hemoglobin can also be detected with gradient
echo (GRE) sequences which detect the signal loss caused by local magnetization of the
iron in hemoglobin. Although the distinction between acute (1-3 days), early subacute
(3–7 days) and late subacute (7-30 days) hemorrhages can be made with a combination
of T1WI and T2WI in the neonate and adult (64), this has not been reported in a fetus.
It is possible that the difference between fetal and adult hemoglobin would infl uence
the appearance and accuracy of antenatal imaging (5).
The apparent diffusion coeffi cient (ADC) is obtained by subtracting images with and
without the application of a diffusion gradient, and decreases within minutes to
an hour of the occurrence of ischemia (65) due to intracellular fl uid retention (66).
Combining T1WI, T2WI and ADC might be useful in determining the age of a prenatal
infarct (67-69). However, the age of a hemorrhage or infarct cannot be determined by
MRI with suffi cient accuracy for forensic or legal purposes.
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Functional evaluation
Fetal movement can also be evaluated by means of dynamic MRI sequences with a
large fi eld of view (FOV) and at a frame rate of 4–6 per second (5). Although not of
immediate clinical value, in the future, specialized techniques may allow determination
of brain oxygenation by means of blood oxygen level-dependent (BOLD) imaging (70)
by functional MRI (FMRI) as early as 33 weeks (71), measurement of pO2 by means
of quantitative images of fl uid oxygenation on standard single-shot fast-spin echo
(SSFSE) sequences (72), or determination of fetal brain lactate by magnetic resonance
spectroscopy (MRS).
Safety
Although widely regarded to be safe, an MRI examination does expose the fetus to noise,
albeit fi ltered by the maternal abdominal and uterine walls, and to a static magnetic
fi eld ten thousand times stronger than the earth’s (73), as well as radiofrequency and
time-varying gradient electromagnetic fi elds. As is the case with ultrasound, there is
no evidence that the human fetus is harmed while performing MRI examinations in
pregnancy (74), while using 1.5T apparatus (4). A ten-year follow-up study of infants
exposed to MRI in utero is underway (75).
ULTRASOUND OR MRI?
With two such powerful techniques available, it is no surprise that the literature
abounds with publications evaluating the added value of MRI relative to ultrasound
for the diagnosis of fetal brain abnormalities. The publications range from case reports
to case series and reviews, but only few compare high quality neurosonography with
high quality MRI. It is diffi cult to pool the data from very different articles, but the
available data are presented below, according to a classifi cation used in pediatric
neuroradiology (76).
Failure of dorsal induction
Anencephaly is reliably diagnosed by ultrasound in the late fi rst trimester (77) when
MRI is of little value. Although encephalocoeles can also be well delineated by axial
ultrasound, neurosonography and MRI may be of value in helping to diagnose possible
additional abnormalities, such as the posterior fossa abnormalities associated with
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Joubert syndrome, before 24 weeks’ gestation (78). The intracranial signs of spina bifi da,
such as the Chiari malformation, are also diagnosed accurately by ultrasound, whether
early in pregnancy or after 24 weeks (79). MRI might be of value in delineating posterior
fossa lesions more accurately (80), and is as accurate as ultrasound for determining the
anatomical level of the spinal defect between 20 and 30 weeks. Because the functional
neurologic level might not correspond to the anatomic level, the ultimate neurologic
outcome cannot be predicted with accuracy by either modality (81).
Failure of ventral induction
Holoprosencephaly
Holoprosencephaly has been diagnosed prior to 10 weeks by means of transvaginal
ultrasound (34;35). However, in other studies using lower resolution ultrasound, both
semilobar and lobar holoprosencephaly have been correctly diagnosed by MRI after 20
weeks’ gestation in fetuses with an ultrasound diagnosis of ventriculomegaly (82;83).
Cerebellar and posterior fossa abnormalities
Several authors have found MRI useful for the evaluation of the posterior fossa.
Examples include providing additional information on areas of hemorrhage in a
tumor during the third trimester (49), excluding false positive ultrasound fi ndings (84),
diagnoses of posterior fossa cysts (85;86), or identifi cation of pontine abnormalities
after 20 weeks’ gestation (87;88). MRI fi ndings have also infl uenced the management
of pregnancies in which the fetus has a posterior fossa cyst between 21 and 39 weeks
(89;90), unilateral cerebellar defi ciency at 25 weeks (91) or Chiari malformation after
24 weeks’ gestation (82).
The posterior fossa has remained an area where MRI excels. In one study, half (6/12) of
ultrasound diagnoses of the posterior fossa were proved wrong by postnatal imaging or
autopsy (92). However, these were all transabdominal ultrasound examinations, and it
can be diffi cult to visualize the posterior fossa well on transabdominal ultrasound in the
late third trimester. Transvaginal ultrasound was necessary in two studies between 20
and 33 weeks’ gestation to accurately distinguish between conditions such as rotation
versus hypoplasia of the vermis, two conditions with very different prognoses (93-
97). In one study, prenatal MRI diagnoses of vermian agenesis, brain stem hypoplasia,
or destructive lesions of the posterior fossa at 25 to 36 weeks’ gestation correlated
well with postnatal fi ndings, but MRI incorrectly diagnosed vermian hypoplasia in
4 of 12 cases and had diffi culty identifying cerebellar hypoplasia at 32 to 36 weeks’
(98). The development of the posterior fossa can be seen by MRI (99) but structures
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such as the vermian fi ssures are seen by MRI as much as fi ve weeks later than their
fi rst visualization in anatomic studies. This can be explained by the fact that MRI may
fail to identify small structures or lesions situated between consecutive planes (100).
Cerebellar and pontine hypoplasia can be seen with either MRI or ultrasound, but more
detailed visualisation of the brain stem can be diffi cult prenatally with either modality
(101). Whichever technique is used, it is essential to come to a standardized anatomic-
developmental diagnosis (102).
Failure of neuronal proliferation, differentiation and histogenesis
Hemimegalencephaly
Asymmetry of the cerebral hemispheres or ventricles at 20 weeks’ gestation can lead to
the suspicion of hemimegalencephaly (103). MRI is useful for depicting the associated
accelerated myelination antenatally at 35 weeks’ gestation or postnatally (89;104),
increased cellularity at 32 weeks (105), and abnormal position of the ipsilateral ventricle
postnatally (106). However, the diagnosis of asymmetry is fraught with uncertainty.
Asymmetric ventriculomegaly can be identifi ed in less than 1% of fetuses, whereas
it is seen in 21-44% of neonates (107). This might refl ect a real difference, or the fact
that usually only one ventricle is visualized clearly prenatally (108). However, in vitro
anatomic studies show that the left cerebral hemisphere may be up to 20% larger
than the right (109;110), and there is some evidence of structural (111) and functional
(112) asymmetry identifi ed by ultrasound. In cases with pathology, there seems to be
a larger degree of asymmetry of the ventricular volume when measured by MRI (113).
Asymmetry of the development of the temporal lobe has also been demonstrated
with MRI, with the right side developing earlier (Unpublished data, Kasprian, G).
Tumors
Doppler ultrasound can identify tumors with increased blood fl ow at 35 weeks (114).
Hemorrhage into a tumor has also been suggested by a sudden increase in tumor
size or the development of a mass within the mass at 39 weeks’ gestation (115).
MRI can also be used to determine cellularity (66), exclude areas of hemorrhage or
necrosis, distinguish tumors from hematomas, and confi rm the presence of fat in
lipomas (116). The intracranial nodules of tuberous sclerosis have been consistently
found with greater sensitivity by MRI, both antenatally between 20 and 32 weeks’
gestation or postnatally, usually in fetuses in which an intracardiac mass indicative of
a rhabdomyoma was found (117-122).
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Microcephaly
Microcephaly has traditionally been defi ned as a head circumference more than three
standard deviations below the mean. In cases in which the head is not quite this small,
it may be useful to assess the (relative) size of the frontal lobe (123;124) and to assess
cerebral blood fl ow with Doppler ultrasound (125). In severe cases of microcephaly, in
which the acoustic window is very limited due to small fontanelles, MRI may be of use.
Microcephaly, like ventriculomegaly, is anatomic fi nding rather than a diagnosis, and
should prompt a search for the underlying cause.
Failure of neuronal migration
Schizencephaly, lissencephaly, pachygria, polymicrogyria and neuronal heterotopias
MRI often adds to the diagnosis of malformations of cortical development between 21
and 32 weeks’ gestation (82;85;119;126-131). This might be partially due to an inherent
advantage of MRI. Although it is feasible to evaluate cortical gyration and sulcation by
means of either MRI or ultrasound in the second half of pregnancy (28-31;132;133),
myelination and migration can only be evaluated by MRI (134-136). Myelination occurs
predominantly after birth, but the protein and lipid signals of the white matter sheath
can be seen by MRI from 30 weeks onward, and the premyelinating formation of white
matter tracts can be demonstrated antenatally with diffusion weighted imaging
(53;137). The dynamic changes in the layered appearance of the cortex also help to
confi rm normal migration (138). However, development as seen by MRI can lag behind
anatomic studies by up to two weeks due to factors such as slice thickness or MRI planes
which are not quite orthogonal (135;139). Ultrasound can also identify malformations
of cortical development, such as an increased echogenicity found at 25 weeks’
gestation in areas where polymicrogyria later became evident (140), ventriculomegaly,
midline cysts, and abnormal opercular formation found at 24 to 32 weeks’ gestation
(141), or abnormal appearing gyri and sulci (142). A retrospective study confi rmed that
it is possible to identify delayed cortical development on ultrasound images obtained
between 20 and 33 weeks’ gestation in fetuses that were subsequently proved to
have Miller-Dieker syndrome (143). In another, prospective study, 23 out of 24 cases
of abnormal cortical development were diagnosed by ultrasound between 18 and 40
weeks. The 24th case had periventricular nodular heterotopia, which was missed by
both ultrasound and prenatal MRI (37). Visualization of polymicrogyria may be age
dependent, as such malformations may develop secondary to vascular problems and
thus will not manifest before the end of the second trimester (144). MRI may also
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be better than ultrasound for differentiating schizencephaly from other differential
diagnoses prenatally (32 - 38 weeks) and postnatally (65;145).
Corpus callosum
Although the callosum can be measured in detail by ultrasound from 16 weeks onward
(20;21), and the premyelinated corpus callosum does not show up well on MRI before
late gestation (47), it is interesting that MRI is better in diagnosing partial or complete
absence of the corpus callosum in many studies done between 21 and 34 weeks’
gestation (50;82;83;85-87;92;119;122;129;146;147). However, this probably refl ects
poorly performed ultrasound studies rather than an inherent technical disadvantage
of ultrasound. In studies in which a midsagittal view was used to evaluate the corpus
callosum, ultrasound was shown to be as good (95;148) or better (149) than MRI for
the diagnosis of corpus callosum abnormalities between 21 and 34 weeks’ gestation.
In addition to indirect signs such as colpocephaly, the corpus callosum can be visualised
directly on multiplanar neurosonography to diagnose complete or partial absence of
the corpus callosum (148). Three dimensional and Doppler ultrasound (95) may also be
of benefi t for visualizing the midline structures and the pericallosal arteries (148).
The optic chiasm is well visualized by MRI from 19 weeks onward (150) and by three
dimensional ultrasound from 22 weeks (11). Olfactory bulbs and sulci are visible by
MRI at 30 to 34 weeks and by ultrasound from 24 weeks (29).
Failure of myelination
Failure of myelination may be a sign of a metabolic defect. However, during fetal life
the maternal metabolism can compensate for metabolic defects in the fetus, with the
result that abnormal myelination as a morphological manifestations of these disorders
is rarely seen prenatally or at birth. Some metabolic disorders may be morphologically
identifi ed prenatally because they are associated with different pathology, such as
parenchchymal lesions, which are found in pyruvate dehydrogenase defi ciency, or
cysts and impaired cortical development, which are common in Zellwegers disease
(144). Defi nitive prenatal diagnosis requires chorionic villus sampling or amniocentesis
for molecular genetic testing, and is generally done when the fetus is at increased risk
because there is a family history of the disease (151).
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Acquired Lesions
Ischemia
Ischemia might be demonstrated by MRI minutes to hours after an insult in the third
trimester, if it results in a hyperintense DWI signal and reduced ADC (66;67;152). Chronic
changes are more commonly seen, and appear as increased T2WI and decreased T1WI
signals due to subcortical leukomalacia (51). In one study (154), intracranial ultrasound
abnormalities were seen sonographically at 21 to 28 weeks’ gestation within hours to
two weeks after the death of a monochorial co-twin, and indicated the development
of cortical abnormalities. However, in another case at 23 weeks (126), the same
diagnosis was not suspected after axial ultrasound but was made by MRI. In cases of
fetal stroke, MRI has demonstrated hemorrhagic lesions in 90%, and porencephaly in
13% of affected fetuses (153). In a severe case, a combination of cardiotocography,
Doppler ultrasound, and MRI made it possible to diagnose fetal brain death at 23 weeks’
gestation (154). MRI has also added to the clinical information about fetuses with a
sonographic diagnosis of porencephaly, schizencephaly, periventricular leukomalacia
and other lesions of the brain parenchyma between 21 and 34 weeks’ (49;50;83;86;
126;129;155).
Infections
Intra-uterine infection with cytomegalovirus can lead to microcephaly, ventriculomegaly
and porencephaly, which are easily seen by ultrasound at 29 weeks’ gestation (156).
More subtle signs of infection include borderline ventriculomegaly with focal areas of
increased echogenicity and small cysts which are situated symmetrically in the lateral
periventricular areas at 22 to 29 weeks’ gestation (157;158). The combination of this
typical ultrasound fi nding with an MRI study showing hyper-intense germinal matrices
bulging into the lateral ventricles at 33 to 35 weeks is very specifi c to the diagnosis of
congenital cytomegalovirus infection (159), and is another example of how ultrasound
and MRI can complement each other. Another case demonstrating synergy between
ultrasound and MRI and the dynamic nature of fetal diagnosis involved a fetus in whom
ventriculomegaly and a large posterior fossa were initially diagnosed by ultrasound.
MRI demonstrated cerebellar hypoplasia and inappropriate cortical gyrations at 34
weeks’ gestation. Days later, parenchymal calcifi cations were seen by ultrasound
(49) and congenital cytomegalovirus infection was confi rmed. In a similar case, MRI
demonstrated lissencephaly and cerebellar atrophy at 37 to 39 weeks’ gestation (160).
In the rare case of congenital herpes infection, severe parenchymal destruction might
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be seen on MRI. Diffusion weighted imaging might be useful for the detection and
monitoring of brain abscesses and herpetic encephalopathy from 35 weeks’ onward
(161).
Trauma
Although our knowledge of the prevalence and evolution of fetal neurological damage
resulting from maternal trauma is limited, fetal central nervous system pathology
such as schizencephaly, vermian haemorrhage (162) and epidural haemorrhage (163)
have been noted by both ultrasound and MRI after maternal trauma as early as at 23
weeks’ gestation.
Germinal matrix bleeding
Germinal matrix and intraventricular bleeding (GMIVH) is another example of an
abnormality for which accurate diagnosis is more likely when both ultrasound and
MRI are used. Ventriculomegaly resulting from GMIVH is visible by ultrasound, with
blood appearing as hyper- or isoechogenic material inside the ventricle. Using MRI,
this material appears as a structure with a central hypointense area surrounded by a
hyperintense signal on T1WI and mixed hypo- and isointensity on T2WI. Hemosiderin
might also be visualized in the parenchyma as a hypointense signal on T2WI from 24
to 33 weeks’ gestation. MRI can identify hemorrhage, even without a mass effect such
as seen with grade I hemorrhage (52;164).
Brainstem watershed injuries
Watershed injuries of the brainstem might cause neurologic abnormalities that can
lead to conditions like Möbius syndrome or the Pierre-Robin sequence, but are beyond
the resolution of antenatal ultrasound or MRI (165). However, when both ultrasound
and MRI have been used at 24 to 29 weeks’ gestation to evaluate an echogenic area in
the cerebellum, hemorrhage (166) could be distinguished from telangiectasis (167).
Ventriculomegaly
Ventriculomegaly is a description, not a diagnosis. Aqueduct stenosis can be inferred
from the presence of dilated lateral and third ventricles with a small fourth ventricle,
along with the absence of any sign of intraventricular bleeding or other intracranial
pathology (168). Sonographic screening for ventriculomegaly is usually done by
evaluating the width of the ventricle at the atrium, in the axial plane (3;169). There is
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a good correlation between ultrasound and MRI measurements of the ventricles (170).
Normal values have been established for measurements of the lateral, third and fourth
ventricles from 12 to 40 weeks’ gestation (17-19;171). When MRI is done at 21 to 37
weeks for the sonographic diagnosis of fetal ventriculomegaly, additional fi ndings have
included lissencephaly (172), holoprosencephaly (83), meningocoele (50) and evidence
of intraventricular hemorrhage (49;63;90;173;174). Conversely, ventriculomegaly has
been ruled out in fetuses between 19 and 33 weeks’ gestation after an ultrasound
exam has suggested mild asymmetrical ventriculomegaly (49;90;91;149;173). MRI
fi ndings that have prompted a change in management include periventricular
leukomalacia or other evidence of ischemic brain injury (83;91), lissencephaly,
polymicrogyria or cortical heterotopia at 25 to 37 weeks’ gestation (83;90;119;174-
177), hydranencephaly (82), holoprosencephaly (82;83), Chiari malformation (82),
corpus callosum agenesis (83;90;119), haemorrhage (83), vein of Galen malformation
(83), Dandy Walker malformation (83) and tuberous sclerosis at 20 to 30 weeks. Because
other reports have confi rmed that all these conditions can be diagnosed by ultrasound
(12;114;140;172;174;178-182), it is unclear whether MRI is intrinsically better for the
diagnosis of conditions associated with ventriculomegaly, or whether the difference
lies in the detail and expertise with which the ultrasound is performed (181).
Craniosynostosis
Craniosynostosis can be diagnosed by ultrasound between 20 and 32 weeks’ gestation
(183;184). Three dimensional ultrasound has been used to aid the diagnosis at 26 weeks’,
and helps to visualize the frontal and metopic sutures (185-188). MRI has also been
found to be accurate in the diagnosis of craniosynostosis at 26 to 37 weeks (189).
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CONCLUSIONS
1. Neurosonography and MRI are often redundant, but occasionally complementary
tests. Both should be performed to a high standard. Although it is appropriate to
use a technique in which one is experienced to supplement another technique in
which one is less experienced, that cannot be taken as evidence that one technique
is inherently superior to the other.
2. Both neurosonography and MRI is operator dependant, and neither obviates the
need for a thorough knowledge of normal and abnormal neuroanatomy, and a
multidisciplinary approach to diagnosis.
3. There are some conditions in which either ultrasound or MRI is clearly the
diagnostic method of choice. In early pregnancy, and where repeated assessment
is needed, ultrasound has an obvious advantage. When ultrasound is diffi cult, as
in the obese patient or a patient with severe oligohydramnios, an MRI examination
may be more informative. MRI may also identify fetal ischemic lesions very quickly
after an insult, such as severe maternal trauma or death of a monochorionic co-
twin, and help to guide sampling for post-mortem histological diagnosis.
4. There is synergy between ultrasound and MRI for the diagnosis of certain conditions,
such as congenital cytomegalovirus infection or cerebellar telangiectasis.
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PHYSIOLOGY
Chapter 3FIRST TRIMESTER
NEUROSONOEMBRYOLOGY WITH
AUTOMATED FOLLICLE TRACKING:
PRELIMINARY FINDINGS
L.R. Pistorius, Ph. Stoutenbeek, G.H.A. Visser
L.R. Pistorius, Ph. Stoutenbeek, G.H.A. VisserDepartment of Obstetrics, Division Perinatology and Gynaecology, University Medical Centre Utrecht,
The Netherlands
J Matern Fetal Neonatal Med 2008, in press
| Ch
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ABSTRACT
We evaluated the feasibility of demonstration of the embryonic cerebral ventricles
using three dimensional transvaginal ultrasonography and software which has been
developed to automatically calculate the volume of ovarian follicles after ovarian
stimulation. In four out of six subsequent ultrasound examinations which were done
for determination of gestational age from eight to ten gestational weeks, suffi cient
resolution was obtained to demonstrate the embryonic cerebral ventricles with
automated volume calculation software, yielding striking images of a dramatic stage
of embryonic development.
| Firs
t trim
este
r neu
roso
noem
bryo
logy
with
aut
omat
ed fo
llicl
e tra
ckin
g: P
relim
inar
y fi n
ding
s
49
INTRODUCTION
The study of the development of the human embryo has become possible in vivo more
than two decades ago with the introduction of real-time ultrasonography, allowing
the study of fetal movements and development of the motor component of the fetal
central nervous system (1) as well as the structural development of the embryonic
central nervous system (2). The fi rst three-dimensional reconstructions were reported
a decade later using an experimental 7,5MHz annular array transvaginal transducer
(3). To improve on the resolution obtainable with commercially available transvaginal
transducers, intrauterine sonography with a 20MHz transducer has been performed
to describe the normal development of cerebral ventricles prior to fi rst trimester
pregnancy termination (4).
Commercially, transvaginal transducers with a frequency of 6 – 12MHz and harmonic
frequencies up to 18MHz are now available. Imaging software include automated
volume calculation (SonoAVC, General Electrical Medical Systems, Zipf, Austria) which
was developed to eliminate observer bias and reduce the time needed for volume
measurements of ovarian follicles. As suggested recently, this technology might be
useful for obstetrical applications such as the demarcation of fetal cerebral ventricles
(5).
METHODS
We decided to evaluate the applicability of the combination of three dimensional
ultrasound with a high-frequency transvaginal transducer and automated follicle
tracking in normal clinical practice by evaluating six subsequent patients presenting
for fi rst trimester ultrasound for determination of gestational age.
The ultrasound examination was performed with a General Electric Voluson E8 fi tted
with the RIC6-12-D 6-12 MHz transvaginal probe with high harmonic frequency
and with the optional CRI (crossbeam imaging) and SRI (speckle reduction imaging)
activated. The three-dimensional data were aquired at “high-2”or “max” quality, and
subsequently analysed with 4DView version 7.0 (General Electrical Medical Systems,
Zipf, Austria). The orientation of the images were standardized as described by Merz
et al (6) to facilitate the identifi cation of the right and left side. Measurements were
taken of the ventricles of the telencephalon, diencephalon, mesencephalon and
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rhombencephalon on sectional planes, and the volumes of these ventricles were
calculated with automated volume calculation by right-clicking the separate ventricles,
and by merging parts of the lateral ventricles anterior and posterior to choroid plexus
volumes into a single volume. The “growth” algorithm was set to “max”, and the
“separation” algorithm set to “mid” or “max”, depending on the best visual result.
Figure 1 CRL=19mm
8w3dCRL=22mm
8w6dCRL=28mm
9w2d
Lateral
Oblique
Frontal
Telencephalon
Diencephalon
Mesencephalon
Rhombencephalon
1 cm
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RESULTS
In all six pregnancies, it was easy to reconstruct the appropriate plane to measure
the crown rump length. In four out of six pregnancies, the cerebral ventricles could
be visualized with suffi cient resolution for two dimensional measurements and
evaluation with automated volume calculation. In one pregnancy, there was an
acutely retroverted uterus with too large a distance between the ultrasound probe
and the embryo, and in another pregnancy there was a set of triplets, where suffi cient
resolution for the SonoAVC software could not be obtained. The mechanical index (MI)
ranged from 0.5 to 1.2, and the thermal index (TI) from <0.1 to 0.2.
The images of three embryos are displayed to scale in Figure 1, showing the rapid
development of cerebral ventricles in less than a week of gestational age, and the
identifi cation of the lateral ventricles developing from the telencephalon, third
ventricle developing from the diencephalon, future aqueduct developing from the
mesencephalon and the fourth ventricle developing from the rhombencephalon.
DISCUSSION
The visual results compare favourably with those obtained in a research setting with
an experimental 7.5MHz transvaginal probe (3) and with intra-uterine sonography
with a 20MHz ultrasound probe (4)
Unfortunately, it is not possible to choose the particular colour which is used to display
a particular ventricle, which would make longitudinal assessment visually more
intuitive.
The software has also been developed for automated follicle measurement after
ovarian hyperstimulation, and has not been validated for volume calculation of
the irregular shape and smaller size of the embryonic brain ventricles. However,
the algorithm used for automated calculation is based on the number of coloured
voxels and does not assume a spheric shape which should yield an accurate volume
measurement in addition to a visual display which allows subjective assessment of
normality. The volumes of the different ventricles were often less than the minimum
volume of 0.01ml which is displayed by the automated software, and this would need
to be improved in order to use this technology to generate a normal data set this early
in pregnancy.
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The rapid development of the embryonic cerebral ventricles is a graphic reminder of
the intricacy of brain development. Although ultrasound is deemed safe, also in the
fi rst trimester, the recent fi nding that exposure to ultrasound for more than 30 minutes
can impair neuronal migration in mice fetuses, was another prompt to reconsider
unbridled use of ultrasound. In this regard, contrary to previous comments that three
dimensional ultrasound adds to scan time when evaluating embryonic development
(7), one can actually decrease the scan time by obtaining a three dimensional volume.
From this volume, the required images (such as that needed for measuring the crown
rump length or evaluating the ventricular system) can then be reconstructed. The
(short) extra time spent in analysis is more than compensated for by the decrease in
actual scan time.
In conclusion, in this small pilot study it was easy to obtain very satisfactory images of
the embryonic ventricular system at eight weeks of gestational age with commercially
available equipment. In addition, a single three-dimensional sweep could also minimize
the exposure of the rapidly developing embryo to ultrasound energy.
POSTSCRIPT
Subsequent to this report, a report on the use of inverse mode rendering of the fetal
cerebral ventricles has appeared with similar results to those obtained with automatic
volume calculation (8).
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REFERENCES
(1) de Vries JI, Visser GH, Prechtl HF. The emergence of fetal behaviour. I. Qualitative aspects. Early Hum Dev 1982;
7(4):301-322.
(2) Timor-Tritsch IE, Farine D, Rosen MG. A close look at early embryonic development with the high-frequency
transvaginal transducer. Am J Obstet Gynecol 1988; 159(3):676-681.
(3) Blaas HG, Eik-Nes SH, Berg S, Torp H. In-vivo three-dimensional ultrasound reconstructions of embryos and
early fetuses. Lancet 1998; 352(9135):1182-1186.
(4) Tanaka H, Senoh D, Yanagihara T, Hata T. Intrauterine sonographic measurement of embryonic brain vesicle.
Hum Reprod 2000; 15(6):1407-1412.
(5) Raine-Fenning N, Jayaprakasan K., Clewes J. Automated follicle tracking facilitates standardization and may
improve work fl ow. Ultrasound Obstet Gynecol 2008; 30:1015-1018.
(6) Merz E, Benoit B, Blaas HG, Baba K, Kratochwil A, Nelson T et al. Standardization of three-dimensional images
in obstetrics and gynecology: consensus statement. Ultrasound Obstet Gynecol 2007; 29(6):697-703.
(7) Centini G, Rosignoli L., Faldini E, Tonni G, Azzoni D, LaSala GB. Correlation between transvaginal 2D and 3D fi rst
trimester neuroimaging and embryonic development according to Carnagie stadiation. Ultrasound Obstet
Gynecol 2004;371.
(8) Kim MS, Jeanty P, Turner C, Benoit B. Three-dimensional sonographic evaluations of embryonic brain
development. J Ultrasound Med 2008; 27(1):119-124.
Chapter 4GRADE AND SYMMETRY OF NORMAL FETAL
CORTICAL DEVELOPMENT: A LONGITUDINAL TWO
AND THREE DIMENSIONAL ULTRASOUND STUDY
L.R. Pistorius1, Ph. Stoutenbeek1, F. Groenendaal2, L.S. de Vries2, G.T.R. Manten1, E.J.H. Mulder1, G.H.A. Visser1
1Department Obstetrics, Division Perinatology and Gynaecology, University Medical Centre Utrecht, Utrecht, The Netherlands
2Department Neonatology, Division Perinatology and Gynaecology, University Medical Centre Utrecht, Utrecht, The Netherlands
Ultrasound Obstet Gynecol (provisionally accepted)
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ABSTRACT
Introduction
Recent studies have shown the capability of ultrasound to demonstrate when fetal
cortical sulci appear, but information is lacking on the grade of development and left-
right differences at different gestational ages.
Objectives
A longitudinal study was undertaken to evaluate the reproducibility of a simple scoring
method to grade fetal cortical development and to study physiological asymmetry.
Methods
A cohort of 28 patients was examined by 2D and 3D ultrasound from 20 until 40
weeks. Cortical development was graded from 0 (no development) to 5 (maximum
development). One examination per week of gestation was randomly selected for
evaluation of intra- and interobserver variation.
Results
215 ultrasound examinations were performed in 28 patients. The intra-observer
variation showed a correlation (Spearman’s rho) of 0,933 (2D) and 0,927 (3D) and a
Kappa of 0.6 (2D) and 0.63 (3D). The inter-observer variation showed a correlation
(Spearman’s rho) of 0,904 (2D) and 0,921 (3D) and a Kappa of 0.56 (2D) and 0.57 (3D).
Asymmetry was seen in the parieto-occipital, calcarine and cingulate sulci and
occipital area, especially between 24 and 28 weeks, and especially in female fetuses.
The right parieto-occipital sulcus tended to be more advanced and the left calcarine
and cingulate sulci tended to be more advanced.
Conclusions
Evaluation of cortical development by means of a simple grading score is feasible and
reproducible. Asymmetrical development of sulci, previously only described in vitro,
has now also been demonstrated in vivo. 3D ultrasound was equally accurate and
repeatable as 2D ultrasound.
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INTRODUCTION
The gestational age at which different sulci and gyri develop has been well described
anatomically (1-3) as well as with antenatal MRI examination (4-8) and antenatal
transabdominal (9;10) and transvaginal ultrasound (10-12) Indeed, neurosonography
has been shown to be as useful as MRI in diagnosing malformations of cortical
development (13). Although the appearance of cortical development has been
described, quantifi cation of the development of sulci and gyri is still lacking. Also,
asymmetrical cortical development has been demonstrated anatomically (1;3), but this
has not been documented nor systematically studied antenatally (2;4-7;9;10;12;14;15)
As malformation of cortical development might be localized, and might present with
advanced or delayed gyral formation(16;17), it is important to determine the degree of
asymmetry which might represent normal individual physiological variation.
As ultrasound lends itself eminently to the visualization of structural cortical
development, a study was undertaken to describe the progression and symmetry of
fetal cortical development. It was also evaluated whether 2D or 3D ultrasound would
be more suitable for assessing fetal cortical development.
METHODS
Twenty eight healthy pregnant women were included after a screening ultrasound
examination at 20 weeks had demonstrated a singleton pregnancy with no abnormal
fi ndings. Other inclusion criteria were confi rmation of pregnancy duration by
ultrasound during the fi rst trimester, and absence of risk factors which might infl uence
fetal growth or development, such as maternal disease or previous intra-uterine
growth restriction. The study was approved by the local Medical Ethics Committee of
the University Medical Centre Utrecht.
Ultrasound examinations were carried out at two weekly intervals with a General
Electric Voluson 730 Expert (General Electric Healthcare, London). Biometry (including
fetal head circumference, abdominal circumference and femur length) was performed,
followed by neurosonography if the biometry conformed to the gestational age.
Transabdominal neurosonography was performed with the GE M7C-H H40412LS 2.6-
7.7MHz 2D ultrasound probe and the GE RAB4-8L H48621Z 4.0 -8.5MHz 3D abdominal
probe. Prior to the fi rst examination, it was randomly assigned (by means of an internet
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based random number generator www.random.org/integers) to start with either
two or three dimensional ultrasound examination. Subsequently, the examination
was started alternatively with two or three dimensional ultrasound. All ultrasound
examinations were done by one observer (LP). On 2D ultrasound, it was attempted
to obtain the standard axial planes (18), the coronal and sagittal neurosonographic
planes (19) and a plane cephalad to the transventricular plane to demonstrate the
parieto-occipital fi ssure (10). Three images of each plane were stored digitally for
subsequent evaluation. The position of the fetus (right side or left side anterior) was
noted. On 3D ultrasound, three static volumes were obtained with high to maximum
quality (depending on the amount of fetal movement): the fi rst starting with the
axial transventricular plane (20), the second starting with the axial transcerebellar
plane, and the third starting with the midcoronal plane. If a midsagittal plane could
be obtained, a fourth volume was obtained starting with this plane. The angle was
chosen to include the maximum amount of fetal brain that could be visualized, but
kept as narrow as possible to shorten scanning time. If fetal movement was observed
during the volume acquisition, the volume was acquired again. The times used for two
dimensional and three dimensional ultrasound examinations were recorded.
A subjective score ranging from 0 (no development) to 5 (maximum development)
(Figure 1) was modifi ed from scores used for MRI (8) and ultrasound analysis (21) of
cortical development and used to assess the development of the Sylvian, parieto-
occipital, calcarine, superior temporal, central and cingulate sulci, and the frontal,
parietal, temporal, occipital and mesial cortical areas. The development of the parieto-
occipital and central sulci and frontal and parietal areas were evaluated in the axial
plane cephalad to the transventricular plane, the Sylvian and superior temporal sulci,
frontal and temporal areas in the transthalamic axial plane, the cingulate sulcus and
mesial area in the midcoronal planes, the calcarine sulcus and occipital areas in the
coronal transcerebellar plane, and the central sulcus, frontal and parietal areas in
the parasagittal oblique plane (Figure 2) on the recorded 2D images and 3D volumes
separately. Evaluation of stored images and volumes was done using 4DView version
7.0 (General Electric Healthcare, London). 3D images were reoriented to facilitate
identifi cation of the right and left hand sides (Figure 3) (22).
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1.1 Sulcus: Parieto-occipital, calcarine, cingular, superior temporal and centralGrade Definition & diagram Example
0 None visible
1 Earliest changes (shallow indentation or echogenic dot)
2 Broad V (width > depth)
3 Y or narrow V (depth = or > width
4 I-or J-haped
5 Branched
< 60o
Figure 1. Cortical grading (continued)
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1.2 Sylvian fissure
Grade Definition & diagram Example
0 Not visible
1 Shallow indentation
2 Obtuse angular shape
3 Acute angles, < 50% operculisation
4 ≥50% operculisation
5 Complete operculisation
x
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1.3 Gyration: Frontal, parietal, temporal, occipital and mesial
Grade Definition & diagram Example0 None visible
1 Shallow undulation
2 Gyral width > depth
3 Gyral width = depth
4 Gyral depth > width
5 Branched gyri / sulci
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Axial plane cephalad to transventricular plane Parieto-occipital fissure Central sulcus Frontal area Parietal area
Axial transthalamic plane Sylvian fissure Superior temporal fissure Frontal area Temporal area
Coronal transcaudate and transthalamic plane Cingulate sulcus Mesial area
Coronal transcerebellar plane Calcarine sulcus Occipital area
Parasagittal oblique plane Central sulcus Frontal area Parietal area
Frontal Parietal
Central
Parieto-occipital
Frontal Temporal
SylvianSuperiortemporal
CingulateMesial
CalcarineOccipital
Frontal
Parietal
Central
Figure 2. Axial, coronal and sagittal planes
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Prim
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imag
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Reor
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imag
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Prim
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imag
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Reor
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imag
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Fig
ure
3. O
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An attempt was made to grade both left and right hand side at each examination.
The quality of the images was graded subjectively (0=not performed or impossible
to evaluate, 1=barely acceptable, 2=suboptimal, 3=average, 4=better than average,
5=excellent), and the time spent on the analyses was also recorded. Where both (left
and right) sulci and cortical areas could be seen in at least 70% of examinations per
fetus, the difference in grade between the two sides was noted. Where one or the other
side predominated, it was noted as asymmetry. If both left and right sulci and cortical
areas could not be seen in at least 70% of examinations per fetus, asymmetry would
be defi ned as a signifi cant difference (by the Mann-Whitney u test) in gestational age
at which each grade of cortical development was fi rst seen provided that the specifi c
grade was seen in at least 70% of fetuses on each side.
One examination per week was randomly selected for analysis of intra- and
interobserver variation. The analysis was done by a second observer (GM) and redone
by the fi rst observer, without being aware of the fi rst grades.
Data management and statistical analysis (including multilevel analysis mixed model
option to identify variables with an independent effect on the time course of cortical
development) were performed with SPSS version 16.0 for Windows (SPSS Inc. Chicago,
Illinois). Mixor version 2 (Donald Hedeker, Chicago, Illinois) was used for analysis of
categorical variables. The proportion of “missing values” or structures not visualized
well enough to be graded reliably on 2D and 3D ultrasound examination respectively
was compared with Fisher’s exact test. The Kappa statistic and Spearman’s rho were
calculated for the intra- and interobserver variation. The study would be also able
to detect an 8% difference in the proportion of structures visualized reliably with
2D or 3D ultrasound examination with a power of 80% and α 0.05 (two tailed). The
distribution of different grades of cortical development seen at different gestational
ages and gestational age at the fi rst appearance of each grade were calculated. The
time spent on 2D and 3D ultrasound examination and analysis was compared with a
paired t test. The study would be able to detect a 5 minute difference in duration of
2D or 3D ultrasound examination with a power of 90% and α 0.05 (two tailed) (Instat,
Graphpad Software 1993).
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RESULTS
215 ultrasound examinations were performed in 28 patients at a gestational age from
a median of 22 (range: 20 – 25) to a median of 37 (range: 33 – 40) weeks. Two patients
were excluded from the study and replaced with other patients: the fi rst when multiple
choroid plexus cysts were found at the fi rst examination, and the second because of
hospitalization in a different hospital due to symptomatic placenta previa. Delivery of
infants in the study occurred at a median of 39 weeks 6 days (range 37w 0 days – 42
weeks 0 days). The median birth weight was 3563g (range 2360 – 4100g). There were
12 male and 16 female infants, one of whom developed MEN IIb syndrome, and the
other of whom are all alive and well.
68% of structures could be seen with 2D and 70% with 3D (Fisher’s exact test p=0.1).
The quality of the 2D and 3D scans both had a mean score of 3 (standard deviation 1),
and were signifi cantly correlated (Spearman rho 0.528, p<0.01). The means were not
signifi cantly different (paired t test p=0.89). The examinations randomly selected for
the interobserver variation also had a mean quality score of 3 for both 2D and 3D.
Grading by 2D and 3D ultrasound were highly correlated (Spearman’s rho 0.92 – 0.97 for
the different sulci and 0.95 – 0.97 for the different cortical areas for the fi rst observer,
n=215, and 0.92 – 1.0 and 0.98 – 1.0 respectively for the second observer, n=19). The
gestational age at the fi rst appearance of different grades is presented in Figure 4.
With multilevel analysis, neither fetal gender nor laterality was found to have an
independent effect on cortical development. The only combination that nearly
reached signifi cance (p= 0.06) was the combination of female gender and laterality in
the development of the calcarine sulcus. Predictive curves are shown in Figure 5.
Intra- and inter-observer variation
The intra-observer variation showed a correlation (Spearman’s rho) of 0,933 (2D) and
0,927 (3D) and a Kappa of 0.6 (2D) and 0.63 (3D). The inter-observer variation showed
a correlation (Spearman’s rho) of 0,904 (2D) and 0,921 (3D) and a Kappa of 0.56 (2D)
and 0.57 (3D).
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Sulcus Sylvian
Parieto-occipital
Calcarine
Superiortemporal
Central
Cingulate
Figure 4. First appearance of different grades of cortical development (continued)
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Cortical area Frontal
Parietal
Temporal
Occipital
Mesial
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5.1 Sulci
Sylvian Superior temporal
Parieto-occipital Central
Calcarine Cingulate
Figure 5. Prediction of cortical grade by multilevel analysis (continued)
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5.2 Cortical areas
Frontal Occipital
Parietal Mesial
Temporal
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Asymmetry
It was possible to visualize the parieto-occipital, calcarine and cingulate sulci and
occipital and mesial cortical areas on both sides in more than 90% of examinations. An
example of asymmetrical sulci is shown in Figure 6.
Symmetrical parieto-occipital fissure (27w)
Asymmetrical parieto-occipital fissure (33w)
Symmetrical calcarine sulcus (27w) Asymmetrical calcarine sulcus (28w)
Figure 6. Symmetrical and asymmetrical sulci
In total, 12% of examinations (64/514) were asymmetrical. In 8 fetuses all examinations
were symmetrical at all times, in 7 fetuses there was asymmetry once, in 6 fetuses
twice, and in 7 fetuses three of four times. The parieto-occipital sulcus was always
symmetrical in 15 fetuses, more advanced by one grade in 10 fetuses on the right hand
side and in 2 fetuses on the left hand side, and by two grades in 1 fetus on the right
hand side. The calcarine sulcus was always symmetrical in 13 fetuses, more advanced
by one grade in 4 fetuses on the right hand side and in 7 fetuses on the left hand side,
and by two grades in 1 fetus on the right hand side and in 3 fetuses on the left hand
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side. The cingulate sulcus was always symmetrical in 21 fetuses, more advanced by
one grade in 3 fetus on the right hand side and in 6 fetuses on the left hand side. The
occipital area was always symmetrical in 18 fetuses, more advanced by one grade in
2 fetuses on the right hand side and in 7 fetuses on the left hand side, and by two
grades in 1 fetus on the right hand side. There was a signifi cant correlation between
asymmetry in the calcarine sulcus and occipital area (Spearman’s rho = 0.84, p<0.001).
There was a signifi cant association between female gender and asymmetry of the
calcarine sulcus (Fisher’s exact test p=0.02), and a signifi cant association between
asymmetry of the parieto-occipital and calcarine sulci (Fisher’s exact test p=0.003),
although opposite sides tended to be more advanced. There was a signifi cant (p<0.01)
negative correlation between gestational age and degree of asymmetry in the parieto-
occipital fi ssure (Spearman’s rho=-0.35), the calcarine sulcus (Spearman’s rho=-0.48)
and the occipital area (Spearman’s rho=-0.46). Most instances of asymmetry occurred
before 28, and it was rare after 32 gestational weeks (Figure 7).
Figure 7. Asymmetry at different gestational ages
Most instances of asymmetry occurred at a maximal cortical grade of 3, with 53% of
examinations being asymmetrical. No asymmetry was seen with a maximal cortical
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grade of 1, 10% of examinations with a maximal cortical grade of 2 was asymmetrical,
23% of grade 4, and 1% of grade 5.
The time spent with 2D and 3D respectively is depicted in Table 1.
Table 1. Scanning, analysis and total time with two dimensional (2D) and three dimensional (3D) ultrasound.
2D 3D Paired t test
Observer 1 Observer 2 Observer 1 Observer 2 Observer 1 Observer 2
Scanning time 5.2 (2.3) - 1.7 (0.9) - p<0.01 -
Analysis time 2.3 (1.0) 9.3 (2.9) 4.3 (1.4) 12.7 (2.8) p<0.01 <0.001
Total time 7.4 (2.6) 15.9 (8.1) 5.9 (1.9) 14.9 (3.9) p<0.01 0.5
Values in minutes (standard deviation)
DISCUSSION
Cortical development could be graded with excellent intra- and interobserver variability
during the latter half of pregnancy. Although 30-32% of sulci or cortical areas were
not visualized, this should represent the “worst-case” scenario, as the images were
evaluated after the scanning procedure and care was taken to limit the amount of
examination time in healthy volunteers. With more time and especially the use of
transvaginal ultrasound, it should be possible to visualize a greater percentage of sulci,
and visualize these with greater resolution.
Another disadvantage of transabdominal ultrasound is that the proximal hemisphere
of the fetal brain is partially obscured by reverberation artifacts (23;24). Due to this, it
has not been possible to determine the degree of asymmetry in many sulci and cortical
areas in this study. The reverberation artifacts have fortunately to a large degree been
solved by newer generation apparatus, but too late for this study (Figure 8) .
It is reassuring and not unexpected that there is a high degree of correlation between
grading with 2D and 3D ultrasound. With 3D ultrasound, asymmetry could be
confi rmed with greater confi dence, as it is possible to ensure a perfectly aligned plane
with an orthogonal display.
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Reverberation obscuring Sylvian fissure and lateral ventricle in proximal hemisphere(GE Voluson 730 Expert, 2005)
Good visualization of Sylvian fissure and lateral ventricle in proximal hemisphere (GE Voluson E8, 2008)
Figure 8. Visualization of proximal hemisphere
The shorter scanning decreases the time that the fetus is exposed to ultrasound, and
the total time (scanning and analysis time) was not increased with 3D ultrasound in
this study. Although the amount of ultrasound exposure during normal clinical use is a
small fraction of the amount found to disturb cortical migration in the mouse embryo
(25), it still makes sense to limit the amount of exposure (26). It is also reassuring that
3D ultrasound does indeed shorten the total scanning and analysis time, irrespective
of the amount of experience of the ultrasonographer.
In comparing the gestational age at which the different sulci become visible with
the results of other studies (Table 2), the fi rst appearance of sulci such as the Sylvian,
parieto-occipital and calcarine sulci in this study seemed to lag behind the results of
other ultrasound, MRI and anatomical studies. This is most likely a result of the later
gestational age at which this study started, where the Sylvian fi ssure was seen in all
patients in comparison with other studies, that started earlier in gestation.
The fi rst appearance of sulci developing later, such as the central or superior temporal
sulci, was seen in this study at a gestational age comparable with other antenatal
imaging studies. It is also noteworthy how different the gestational ages in two
different anatomical studies were. This might be partially explained that the study
reporting later development also examined brains from fetuses after 22 weeks, and
there might be some inaccuracy in the determination of the gestational ages (1;3).
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Tab
le 2
. Ges
tati
onal
age
at
det
ecti
on o
f su
lci
2a. C
omp
aris
ion
wit
h a
nat
omic
al a
nd
MRI
stu
die
s: g
esta
tion
al a
ge (w
eeks
)
Stru
ctu
reA
nat
omic
al
app
eara
nce
(G
ovae
rt)
An
atom
ical
ap
pea
ran
ce
(Ch
i)
An
atom
ical
ap
pea
ran
ce
(Dor
ovin
i)
MR
I: D
etec
tab
le
in >
75%
of
bra
ins
(Lev
ine)
MR
I: A
pp
eara
nce
(L
an)
MR
I: D
etec
tab
le in
25
-75%
/ >
75%
of
bra
ins
(Gar
el)
Ult
raso
un
d:
Det
ecta
ble
in
25-7
5% /
>75%
of
bra
ins
(th
is s
tud
y)
Sylv
ian
fi ss
ure
1214
14-1
524
-25
/ 29
22 /
22
Pari
eto-
occi
pit
al fi
ssu
re16
1622
18-1
922
/ 2
3
Cal
cari
ne fi
ssu
re16
1622
18-1
922
-23
/ 24
-25
22 /
23
Cin
gula
te s
ulc
us
1618
2426
-27
3022
-23
/ 24
-25
23 /
26
Cen
tral
su
lcu
s20
2024
26-2
824
-26
24-2
5 /
2726
/ 2
6
Sup
erio
r te
mp
oral
su
lcu
s28
2328
28-2
924
-26
26 /
27
25 /
26
2b. C
omp
aris
ion
wit
h o
ther
ult
raso
un
d s
tud
ies:
ges
tati
onal
age
(wee
ks)
Sulc
us
Firs
t ap
pea
ran
ceFi
rst
app
eara
nce
/ d
etec
ted
in a
llD
etec
ted
in 2
5-75
% /
>75
%
Ber
nar
dM
onte
agu
do
Toi
This
stu
dy
Coh
en-S
ach
erTh
is s
tud
y
Sylv
ian
1918
22 /
23
22 /
22
Pari
eto-
occi
pit
al23
1818
/ 2
021
/ 2
418
/ 2
022
/ 2
3
Cal
cari
ne fi
ssu
re23
1818
/22
21 /
26
20 /
22
22 /
23
Cin
gula
te s
ulc
us
22-2
426
23/2
422
/ 2
720
/ 2
423
/ 2
6
Cen
tral
su
lcu
s23
/ 2
726
/ 2
726
/28
26 /
27
Sup
erio
r te
mp
oral
su
lcu
s26
- 28
24 /
29
28 /
3025
/ 2
6
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In the sulci and cortical areas where it was possible to determine asymmetry, this was
seen most clearly in the calcarine sulcus and occipital areas, and to a lesser extent in
the parieto-occipital and cingulate sulcus. This was seen more commonly in female
fetuses, but not related to the position of the fetus, and disappeared after 32 weeks.
Part of the decrease in the degree of asymmetry with advancing gestational age might
be related to the grading, which reached a plateau from around 34 weeks, but the
maximum asymmetry was seen well before this, namely before 28 weeks. Previously,
asymmetry in the hemisphere diameter was found at 20 – 22 weeks in both female
and male fetuses (27). Asymmetry in the development of the temporal lobe has
been demonstrated anatomically (28;29) and with MRI (unpublished data, D. Prayer
and G. Kasprian) with the right hand side developing earlier than the left. No other
antenatal imaging studies could be found which systematically evaluated symmetry
of cortical development. When the results of this study is compared with those of
anatomical studies (1;3), it is interesting that asymmetry was found in sulci where it
has not previously been described anatomically, and the calcarine sulcus which tended
to be more advanced on the right hand side in an anatomical study (1) was tended to
be more advanced on the left hand side in our study. The transience of asymmetry,
and the relationship with female gender in this study might explain some of these
differences. Multilevel analysis with Mixor (considering the grades as categorical
variables) and SPSS (considering the grades as continuous variables) yielded similar
results, and the predictive curves are shown as continuous lines generated from the
SPSS analyses. Advantages of multilevel analysis include that it takes dependence of
measurements in hierarchically structured data into account, and that it allows for
missing values and variation in frequency of measurements. Only the strongest effect
of laterality and gender, namely on the development of the calcarine sulcus, was born
out by multilevel analysis, demonstrating that asymmetry is an individual rather than
a systematic effect.
This study has also shown that it is feasible and not time-consuming to grade cortical
development accurately on transabdominal 2D and 3D ultrasound, and that a degree of
asymmetry can occur physiologically. It should be expanded to increase the number of
evaluations earlier in gestation, and done with apparatus where it is mostly possible to
visualize both hemispheres. Clinically, this technique could be applied as part of a fetal
neurosonographical examination to assist the assesment of cortical development.
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REFERENCES
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(2) Govaert P, de Vries L. Sulci and gyri. An atlas of neonatal brain sonography.London: Cambridge University Press;
2005. p. 1-6.
(3) Dorovini-Zis K, Dolman CL. Gestational development of brain. Arch Pathol Lab Med 1977 Apr;101(4):192-5.
(4) Garel C. The role of MRI in the evaluation of the fetal brain with an emphasis on biometry, gyration and
parenchyma. Pediatr Radiol 2004 Sep;34(9):694-9.
(5) Girard N, Raybaud C, Gambarelli D, Figarella-Branger D. Fetal brain MR imaging. Magn Reson Imaging Clin N Am
2001 Feb;9(1):19-56, vii.
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with a half-Fourier rapid acquisition with relaxation enhancement sequence. Radiology 2000 Apr;215(1):205-
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(7) Levine D, Barnes PD. Cortical maturation in normal and abnormal fetuses as assessed with prenatal MR imaging.
Radiology 1999 Mar;210(3):751-8.
(8) Van der Knaap MS, Wezel-Meijler G, Barth PG, Barkhof F, Ader HJ, Valk J. Normal gyration and sulcation in
preterm and term neonates: appearance on MR images. Radiology 1996 Aug;200(2):389-96.
(9) Bernard C, Droulle P, Didier F, Gerard H, Larroche JC, Plenat F, et al. [Echographic aspects of cerebral sulci in the
ante- and perinatal period]. J Radiol 1988 Aug;69(8-9):521-32.
(10) Toi A, Lister WS, Fong KW. How early are fetal cerebral sulci visible at prenatal ultrasound and what is the normal
pattern of early fetal sulcal development? Ultrasound Obstet Gynecol 2004 Dec;24(7):706-15.
(11) Cohen-Sacher B, Lerman-Sagie T, Lev D, Malinger G. Sonographic developmental milestones of the fetal cerebral
cortex: a longitudinal study. Ultrasound Obstet Gynecol 2006 May;27(5):494-502.
(12) Monteagudo A, Timor-Tritsch IE. Development of fetal gyri, sulci and fi ssures: a transvaginal sonographic study.
Ultrasound Obstet Gynecol 1997 Apr;9(4):222-8.
(13) Malinger G, Kidron D, Schreiber L, Ben Sira L, Hoffmann C, Lev D, et al. Prenatal diagnosis of malformations of
cortical development by dedicated neurosonography. Ultrasound Obstet Gynecol 2007 Feb;29(2):178-91.
(14) Cohen-Sacher B, Sagie-Lerman T, Lev D, Malinger G. Sonographic characterization of the fetal cortex: a
longitudinal study(Abstracts of the 15th World Congress on Ultrasound in Obstetrics and Gynecology).
Ultrasound Obstet Gynecol 2005 Sep;26(4):309-471.
(15) Huisman TA, Martin E, Kubik-Huch R, Marincek B. Fetal magnetic resonance imaging of the brain: technical
considerations and normal brain development. Eur Radiol 2002 Aug;12(8):1941-51.
(16) Malinger G, Lerman-Sagie T, Watemberg N, Rotmensch S, Lev D, Glezerman M. A normal second-trimester
ultrasound does not exclude intracranial structural pathology. Ultrasound Obstet Gynecol 2002 Jul;20(1):51-6.
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(17) Malinger G, Lev D, Lerman-Sagie T. Abnormal sulcation as an early sign for migration disorders. Ultrasound
Obstet Gynecol 2004 Dec;24(7):704-5.
(18) Malinger G, Monteagudo A, Pilu G, Timor-Tritsch IE, Toi A. Sonographic examination of the fetal central nervous
system: guidelines for performing the ‘basic examination’ and the ‘fetal neurosonogram’. Ultrasound Obstet
Gynecol 2007 Jan;29(1):109-16.
(19) Timor-Tritsch IE, Monteagudo A. Transvaginal fetal neurosonography: standardization of the planes and sections
by anatomic landmarks. Ultrasound Obstet Gynecol 1996 Jul;8(1):42-7.
(20) Pilu G, Ghi T, Carletti A, Segata M, Perolo A, Rizzo N. Three-dimensional ultrasound examination of the fetal
central nervous system. Ultrasound Obstet Gynecol 2007 Aug;30(2):233-45.
(21) Quarello E., Stirnemann J., Guibaud L., Ville Y. Assessment of the Sylvia fi ssure operculization (SFO) at between
22 and 32 weeks of gestation: a subjective approach (part I). Ultrasound Obstet Gynecol 2007;30:418.
(22) Merz E, Benoit B, Blaas HG, Baba K, Kratochwil A, Nelson T, et al. Standardization of three-dimensional images in
obstetrics and gynecology: consensus statement. Ultrasound Obstet Gynecol 2007 Jun;29(6):697-703.
(23) Pilu G, Nicolaides K. Central nervous system. Diagnosis of fetal abnormalities: The 18 - 23 week scan.London:
Parthenon; 1999. p. 5-18.
(24) Monteagudo A. Fetal neurosonography: should it be routine? Should it be detailed? Ultrasound Obstet Gynecol
1998 Jul;12(1):1-5.
(25) Ang ES, Jr., Gluncic V, Duque A, Schafer ME, Rakic P. Prenatal exposure to ultrasound waves impacts neuronal
migration in mice. Proc Natl Acad Sci U S A 2006 Aug 22;103(34):12903-10.
(26) Abramowicz JS. Prenatal exposure to ultrasound waves: is there a risk? Ultrasound Obstet Gynecol 2007
Apr;29(4):363-7.
(27) Hering-Hanit R, Achiron R, Lipitz S, Achiron A. Asymmetry of fetal cerebral hemispheres: in utero ultrasound
study. Arch Dis Child Fetal Neonatal Ed 2001 Nov;85(3):F194-F196.
(28) Bossy J, Godlewski G, Maurel JC. [Study of right-left asymmetry of the temporal planum in the fetus]. Bull Assoc
Anat (Nancy ) 1976 Jun;60(169):253-8.
(29) Teszner D, Tzavaras A, Gruner J, Hecaen H. [Right-left asymmetry of the planum temporale; apropos of the
anatomical study of 100 brains]. Rev Neurol (Paris) 1972 Jun;126(6):444-9.
Chapter 5A LONGITUDINAL ULTRASOUND STUDY OF THE
SIZE AND SYMMETRY OF THE FETAL LATERAL
CEREBRAL VENTRICLES
L. Pistorius1, E.J.H. Mulder1, M. Rutten1, S. Kuc1, M. Benders2, G.H.A. Visser1
1Department Obstetrics, Division Perinatology and Gynaecology, University Medical Centre Utrecht, Utrecht, The Netherlands
2Department Neonatology, Division Perinatology and Gynaecology, University Medical Centre Utrecht, Utrecht, The Netherlands
Submitted
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ABSTRACT
Introduction
On the standard transventricular view, usually only one cerebral ventricle can
be visualized. We undertook a study to see whether it is possible to visualize both
ventricles on the standard view and in the midcoronal plane with three dimensional
(3D) ultrasound and with static volume contrast imaging (VCI), to generate longitudinal
growth curves and to determine the prevalence of ventricular asymmetry.
Methods
A cohort of 28 patients was examined every two weeks from 20 until 40 weeks by 2D
and 3D ultrasound. The ventricular atrium, index (VI) and frontal horn width (FHW)
were measured by two observers. Interobserver variation was calculated. Multilevel
analysis was used to evaluate the effect of gestational age and gender on ventricular
measurements.
Results
Both ventricles could be evaluated in the axial plane signifi cantly more often using
3D (42%) and VCI (55%) than with 2D (5%). Both frontal horns could be evaluated
in more than 60% of examinations with 2D, 3D and VCI. Spearman’s rho calculated
for the correlation between measurements with 2D, 3D and VCI ranged from 0.31-
0.67 (p<0.001) and Spearman’s rho calculated for inter-observer correlation ranged
from 0.36-0.80. Asymmetry of the ventricles was seen in 0-4% of measurements.
Longitudinal growth curves based on individual developmental trajectories were
generated.
Conclusion
The midcoronal view and the axial view with VCI proved useful to evaluate both left
and right lateral cerebral ventricles. There was a good interobserver correlation, and
the differences between 2D, 3D and VCI measurements were all small. Asymmetry
was uncommon, but more common than previously reported.
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INTRODUCTION
Evaluation of the lateral cerebral ventricles by assessment of the atrium width on the
transventricular axial plane is a routine part of structural fetal ultrasound examination
(1) (and has been for decades (2)). This evaluation has the advantage that the upper
limit of the atrial measurement (four standard deviations above the mean) remains
around 10mm throughout gestation, but it is not without its drawbacks. Reverberation
artefacts may cause a fuzzy view of the hemisphere closest to the transducer on
transabdominal examination (3). Although it has improved with top-end ultrasound
machines, it is often diffi cult to diagnose asymmetrical ventriculomegaly on this view,
especially if the ventricle distal to the transducer is of normal diameter. The fact that
asymmetrical ventriculomegaly is a very rare fi nding antenatally with a prevalence of
less than 1% (4) as compared to postnatal asymmetry in excess of 40% (5), might at
least in part be due to this ascertainment bias.
There are at least two possible solutions for this problem. The fi rst is to assess the frontal
horns of the lateral ventricles on a midcoronal plane (6), which is the view commonly
used by neonatologists (7;8) and usually allows visualization of both ventricles. A
possible disadvantage of this approach is that mild ventriculomegaly affecting only the
posterior horns might be missed on this view, although the frontal horn confi guration
should also be abnormal in true colpocephaly (9). Another approach would be to
reconstruct the axial plane with three dimensional (3D) ultrasound from different
acquisition planes which might be less prone to obscuring of one lateral ventricle. A
possible disadvantage to this approach is that the resolution of a reconstructed plane
is always less than that of the acquisition plane, but this may be compensated by using
volume contrast imaging (VCI) (10).
We therefore decided to perform a longitudinal study to assess our ability to visualize
both ventricular atria and frontal horns with antenatal two (2D) and three dimensional
ultrasound, the latter with and without VCI.
METHODS
Twenty eight healthy pregnant women were included after a screening ultrasound
examination at 20 weeks had demonstrated a singleton pregnancy with no abnormal
fi ndings. Other inclusion criteria were confi rmation of pregnancy duration by ultrasound
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during the fi rst trimester, and absence of risk factors which might infl uence fetal
growth or development, such as maternal disease or previous intra-uterine growth
restriction. The study was approved by the Medical Ethics Committee of the University
Medical Centre Utrecht.
Ultrasound examinations were carried out at two weekly intervals with a General
Electric Voluson 730 Expert (General Electric Healthcare, London). Biometry (including
fetal head circumference, abdominal circumference and femur length) was performed,
followed by neurosonography if the biometry conformed to the gestational age.
Transabdominal neurosonography was performed by one of the authors (LP) with a
2.6-7.7MHz 2D ultrasound probe and a 4.0-8.5MHz 3D probe. On 2D ultrasound, it was
attempted to obtain the standard neurosonographic planes (6). Three images of each
plane were stored digitally for subsequent evaluation. The position of the fetus (right
side or left side anterior) was noted. On 3D ultrasound, three static volumes were
obtained with high to maximum quality (depending on the amount of fetal movement):
the fi rst starting with the axial transventricular plane, the second starting with the
axial transcerebellar plane, and the third starting with the midcoronal plane. An angle
of 45°-65° was chosen to include the maximum amount of fetal brain that could be
visualized, but kept as narrow as possible to shorten scanning time. If fetal movement
was observed during the volume acquisition, the volume was acquired again.
Image J version 1.38 (NIH, USA) was used to measure the recorded 2D images. 4DView
version 7.0 (General Electric Healthcare, London) was used to measure the 3D volumes.
Measurement of the ventricles was done by two observers (LP and SK) without being
aware of each others’ measurements. Each measurement was done three times, and
the median used for analysis. 3D images were reoriented to facilitate identifi cation
of the right and left sides (11). Measurements on 3D volumes were done at maximal
magnifi cation with and without static volume contrast imaging (VCI) set at slice
thickness 3mm. An attempt was made to measure both left and right sides at each
examination. The ventricular atria were measured on the transventricular plane in a
standardized fashion. The (inner-inner) width of the frontal horns (frontal horn width;
FHW) and the distance from the inner side of the lateral edge of the frontal horns to
the midline (ventricular index, VI) were measured in a coronal plane at the foramina of
Munro, in front of the choroid plexus in the third ventricle (7;12) (Figure 1).
Data management and statistical analysis (including multilevel analysis mixed
model option to identify variables with an independent effect on the time course of
ventricular growth) were performed with SPSS version 15.0 for Windows (SPSS Inc.
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Chicago, Illinois). The number of structures visualized well enough to be graded reliably
with 2D, 3D and VCI, respectively, was compared with the chi square test.
We calculated Spearman’s rho to determine the correlation between the measurements
of each observer and we performed a Bland-Altman analysis to plot the difference
between the measurements of the two observers against their mean.
To obtain the best-fi t equation for multilevel analysis to compare the ventricular
measurements with gestational age, we used a model with random slope and
random intercept. We used the linear mixed model option with maximum likelihood
procedure. 2D ultrasound: axial transventricular plane 2D ultrasound: midcoronal plane
3D ultrasound: plane of acquisition 3D ultrasound: reoriented view
3D ultrasound: volume contrast imaging (VCI ) Note increased contrast (e.g. vermis)
3D ultrasound: measurement of ventricular atrium
3D ultrasound: measurement of frontal horns
1= left ventricular index (V I) 2= right V I 3=right frontal horn width (FHW) 4=left FHW
Figure 1. Evaluation of ventricles
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Asymmetry was defi ned as a difference of more than two standard deviations
between the measurement on the left and on the right hand side (4). The occurrence
of asymmetry was calculated as percentage of the total number of fetuses in whom
both left and right ventricles could be visualized, with confi dence intervals defi ned by
the modifi ed Wald method (13).
RESULTS
215 ultrasound examinations were performed in 28 patients at a gestational age from
a median of 22 (range: 20 – 25) to a median of 37 (range: 33 – 40) weeks. Delivery of
infants in the study occurred at a median of 39 weeks 6 days (range 37w 0 days – 42
weeks 0 days). The median birth weight was 3563g (range 2360 – 4100g). There were
12 male and 16 female infants, one of whom developed MEN IIb syndrome. All other
infants were alive and well in the neonatal period.
The percentage and number of measurements that was possible with the three
methods is depicted in Figure 2 and Table 1.
Figure 2. Visualization with 2D, 3D and VCI
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f
Table 1. VisualizationNumber of examinations where it was possible to measure neither side / one side only / both sides
2D 3D VCI Total
Atria 10 / 194 / 11 14 / 111 / 90 6 / 90 / 119 301 / 3951 / 2201
VI 50 / 31 / 134 49 / 16 / 150 25 / 43 / 147 124 / 90 / 431
FHW 51 / 32 / 132 41 / 46 / 128 25 / 50 / 140 117 / 128 / 400
Total 111 / 2572 / 2772 104 / 173 / 368 563 / 183 / 4064 271 / 613 / 1051
Chi square:1p<0.0001 (compared to VI and FHW) 2p<0.0001 (compared to 3D and VCI) 3p<0.0001 (compared to 2D and 3D)4p=0.03 (compared to 3D)
Measurements with 2D and 3D ultrasound with and without VCI were signifi cantly
correlated and the 95% confi dence interval was less than 1 mm for all comparisons
(Table 2). The inter-observer variation correlations and differences are shown in Table
3 and Figure 3.
Table 2. Correlations and differences between 2D, 3D and VCI
2D-3D 2D-VCI 3D-VCI
Spearman p Difference (mm)
Spearman p Difference (mm)
Spearman p Difference (mm)
Atria 0.51 <0.001 -0.3(-0.6 - -0.1)
0.67 <0.001 0.0(-0.2 – 0.2)
0.51 <0.001 0.1(-0.5 – 0.7)
VI 0.51 <0.001 -0.4(-0.7 - -0.2)
0.59 <0.001 0.3(0.1 – 0.5)
0.61 <0.001 0.6(0.4 – 0.8)
FHW 0.32 <0.001 0.5(0.3 – 0.6)
0.52 <0.001 0.3(0.2 – 0.4)
0.31 <0.001 0.0(-0.1 – 0.1)
2D=two dimensional ultrasound 3D=three dimensional ultrasoundVCI=volume contrast imaging Atrium=ventricular atrium (axial plane)VI=ventricular index (coronal plane) FHW=frontal horn width (coronal plane)Measurements as mm (95% confi dence intervals)
Table 3. Interobserver correlation: 2D, 3D and VCI
2D 3D VCI
Spearman p Spearman p Spearman p
Atria 0.80 <0.001 0.65 <0.001 0.58 0.001
VI 0.36 0.054 0.52 0.001 0.52 0.001
FHW 0.66 <0.001 0.42 0.01 0.38 0.02
2D=two dimensional ultrasound 3D=three dimensional ultrasoundVCI=volume contrast imaging Atrium=ventricular atrium (axial plane)VI=ventricular index (coronal plane) FHW=frontal horn width (coronal plane)
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VCI measurements were used for further analysis. The atrial diameter was
normally distributed; the VI and FHW were normally distributed after log naturalis
transformation. Using multilevel analysis, neither gestational age (p=0.91) nor fetal
gender (p=0.93) were predictors of atrial diameter. The gestational age (p<0.0001)
and squared gestational age (p<0.0001) had main effects on VI, and there was a fetal
gender by gestational age interaction that attained borderline signifi cance (p=0.058).
For the FHW, we found a main effect of the squared gestational age (p=0.002), but not
gestational age (p=0.46) or gender (p=0.77) and a fetal gender by squared gestational
age interaction effect that showed a trend towards signifi cance (p=0.097). The normal
growth curves and measured values are shown in Figures 4 and 5.
Two dimensional ultrasound
Three dimensional ultrasound
Volume contrast imaging
Atrium
Ventricle index
Frontal horn width
Figure 3. Bland-Altman plotsLines represent mean +/- 2 standard deviationsY axes = difference between two measurementsX axes = mean of two measurements
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Five instances of asymmetry of atrial measurements were noted out of 119
measurements (4%, 95% confi dence intervals (CI)=2-10%), no instances of asymmetry
of VI measurements (95% CI 0-3%) and four instances of asymmetry of FHW
measurements (3%, 95% CI 1-7%). Asymmetry was not related with the measurement
modality (2D, 3D or VCI), gestational age, fetal gender or fetal position.
Figure 4. Atrial diameter Lines represent mean (atrial diameter = 5.87mm), 5th and 95th centiles
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Figure 5. Ventricle index (VI) and frontal horn width (FHW) Lines represent mean, 5th and 95th centilesVI (triangles) = exp(0,46+0,0987*GA-0,001279*GA2)FHW (circles) = exp((0,802-0,000182* GA2)
DISCUSSION
The usefulness of static VCI and C-plane VCI (VCI-C) to visualize cerebral midline
structures has previously been demonstrated (10;14) VCI is a technique which
enhances contrast by fi ltering out “noise” pixels and enhancing informative pixels. It
can either be used live in the A or the C-plane during 3D scanning (VCI-A or VCI-C), or
subsequently on a stored 3D volume (static VCI) (15). Our study has demonstrated that
static VCI is useful to visualize both cerebral ventricles, with signifi cantly fewer cases
where only one or no lateral ventricle could be visualized as compared to 2D or 3D.
Both frontal horns could be visualized in more than 60% of fetuses, whether 2D, 3D
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or VCI was used. However, when analyzing the 3D volumes which were obtained from
a midcoronal plane, it was also obvious that the plane obtained on 2D was often not
truly coronal. A small difference in angulation should not make a big difference in
measurement, though, as the ventricles have a fairly regular shape. Another advantage
of 3D is that it is easy to identify the right and left hand side by reorienting the image
in a standardized fashion (11). The small difference in measurements between 2D and
VCI is reassuring and indicated that VCI can be used to increase the contrast resolution
without changing the measurements. We cannot extrapolate these results, however,
to instances where very small differences in measurement could have a large impact,
such as in nuchal translucency measurement (16). The fact that the inter-observer
agreement with VCI was at least as good as with 2D or 3D, while allowing the greatest
chance of visualizing both ventricles, makes VCI the modality of choice to identify and
measure the cerebral ventricles.
Using VCI to optimize the visualization of both ventricles, the incidence of asymmetry
was still low, although much higher than the 0,29% previously reported (4). However,
that study was performed using 2D ultrasound, and it was not specifi ed in how many
fetuses both ventricles were seen. If this was as low as in our 2D examinations, the
“true” percentage might also have been similar to our fi ndings of symmetry in up to
4% of examinations. The neonatal occurrence is still 5 to 10 times higher (5), which
might be the result of intrapartum events or simply the effect of gravity.
The results of this longitudinal study using individual growth trajectories confi rm
previous cross-sectional studies which showed a stable atrial diameter throughout
gestational age (17;18). If the cut-off of 10mm for the atrial diameter is used, only
three out of 328 measurements would have been classifi ed as abnormal (0.9%; 95%
confi dence interval 0.18-2.8%) (Figure 6). We demonstrated only a small effect of
gestational age on the FHW. If a cut-off is calculated for the FHW in a similar way as for
the atrium (17), 4mm would classify two out of 329 measurements as abnormal (0.6%;
95% confi dence interval 0.02-2.3%) (Figure 7). This latter value would need to be tested
prospectively to determine whether it discriminates equally well between normal and
abnormal ventricle diameters as does an atrial diameter of 10mm. There is unlikely
to be a single measurement which gives an optimal distinction between normality
and pathology, as can be seen from the high percentage of infants with a normal
neurological development after an antenatal diagnosis of mild ventriculomegaly (19).
The differences between male and female fetuses were small: no signifi cant difference
could be found using multilevel analysis. The absolute differences were also small. The
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atrium was on average 0.2mm smaller, the VI 0.4mm larger, and the FHW 0.05mm
larger in male than in female fetuses. Even a statistically signifi cant difference would
therefore have been clinically insignifi cant.
Figure 6. Maximum atrial diameter
It has been shown that it is relatively easy to obtain a midfrontal sagittal view with
2D, and 3D could then be used whenever this is not feasible (14). Our results show
that the midcoronal view can also be obtained in the majority of fetuses with 2D. VCI
or 3D could be used where visualization with 2D is inadequate. When examining the
fetal heart, it would be considered the most basic examination to view only a four-
chamber view. In a similar way, in any but the most basic examination of the fetal
brain, we believe that the midsagittal and midcoronal views which are usually easy to
obtain, offer a wealth of additional information, and should form part of the normal
repertoire of planes in addition to axial views.
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Figure 7. Maximum frontal horn width
The usefulness of the measurements of the frontal horn width to distinguish between
fetuses with intracranial pathology and those with a variation of the normal would
need to be evaluated prospectively. An added bonus of this view is that it corresponds
to neonatal practice, and should facilitate direct comparison between antenatal and
postnatal examinations.
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REFERENCES
(1) Malinger G, Monteagudo A, Pilu G, Timor-Tritsch IE, Toi A. Sonographic examination of the fetal central nervous
system: guidelines for performing the ‘basic examination’ and the ‘fetal neurosonogram’. Ultrasound Obstet
Gynecol 2007; 29(1):109-116.
(2) Filly RA, Goldstein RB, Callen PW. Fetal ventricle: importance in routine obstetric sonography. Radiology 1991;
181(1):1-7.
(3) Monteagudo A. Fetal neurosonography: should it be routine? Should it be detailed? Ultrasound Obstet Gynecol
1998; 12(1):1-5.
(4) Achiron R, Yagel S, Rotstein Z, Inbar O, Mashiach S, Lipitz S. Cerebral lateral ventricular asymmetry: is this a
normal ultrasonographic fi nding in the fetal brain? Obstet Gynecol 1997; 89(2):233-237.
(5) Shen EY, Huang FY. Sonographic fi nding of ventricular asymmetry in neonatal brain. Arch Dis Child 1989;
64(5):730-732.
(6) Timor-Tritsch IE, Monteagudo A. Transvaginal fetal neurosonography: standardization of the planes and sections
by anatomic landmarks. Ultrasound Obstet Gynecol 1996; 8(1):42-47.
(7) Davies MW, Swaminathan M, Chuang SL, Betheras FR. Reference ranges for the linear dimensions of the
intracranial ventricles in preterm neonates. Arch Dis Child Fetal Neonatal Ed 2000; 82(3):F218-F223.
(8) Levene MI. Measurement of the growth of the lateral ventricles in preterm infants with real-time ultrasound.
Arch Dis Child 1981; 56(12):900-904.
(9) Levine D, Trop I, Mehta TS, Barnes PD. MR imaging appearance of fetal cerebral ventricular morphology.
Radiology 2002; 223(3):652-660.
(10) Vinals F, Munoz M, Naveas R, Giuliano A. Transfrontal three-dimensional visualization of midline cerebral
structures. Ultrasound Obstet Gynecol 2007; 30(2):162-168.
(11) Merz E, Benoit B, Blaas HG, Baba K, Kratochwil A, Nelson T et al. Standardization of three-dimensional images in
obstetrics and gynecology: consensus statement. Ultrasound Obstet Gynecol 2007; 29(6):697-703.
(12) Monteagudo A, Timor-Tritsch IE, Moomjy M. Nomograms of the fetal lateral ventricles using transvaginal
sonography. J Ultrasound Med 1993; 12(5):265-269.
(13) Agresti A, Coull BA. Approximate is better than “Exact” for interval estimation of binomial proportions. American
Statistician 1998; 52:119-126.
(14) Pilu G, Segata M, Ghi T, Carletti A, Perolo A, Santini D et al. Diagnosis of midline anomalies of the fetal brain with
the three-dimensional median view. Ultrasound Obstet Gynecol 2006; 27(5):522-529.
(15) Merz E. Current 3D/4D ultrasound technology in prenatal diagnosis. Eur Clinics Obstet Gynaecol 2005; 1(3):184-
193.
(16) Paul C, Krampl E, Skentou C, Jurkovic D, Nicolaides KH. Measurement of fetal nuchal translucency thickness by
three-dimensional ultrasound. Ultrasound Obstet Gynecol 2001; 18(5):481-484.
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(17) Cardoza JD, Goldstein RB, Filly RA. Exclusion of fetal ventriculomegaly with a single measurement: the width of
the lateral ventricular atrium. Radiology 1988; 169(3):711-714.
(18) Hilpert PL, Hall BE, Kurtz AB. The atria of the fetal lateral ventricles: a sonographic study of normal atrial size and
choroid plexus volume. AJR Am J Roentgenol 1995; 164(3):731-734.
(19) Ouahba J, Luton D, Vuillard E, Garel C, Gressens P, Blanc N et al. Prenatal isolated mild ventriculomegaly: outcome
in 167 cases. BJOG 2006; 113(9):1072-1079.
Chapter 6FETAL CEREBELLAR VOLUME AND SYMMETRY ON
THREE-DIMENSIONAL ULTRASOUND:
VOLUME MEASUREMENT WITH MULTIPLANAR
AND VOCAL TECHNIQUES
M.J. Rutten1, L.R. Pistorius1, E.J.H. Mulder1, Ph. Stoutenbeek1, L.S. de Vries2, G.H.A. Visser1
1Department Obstetrics, Division Perinatology and Gynaecology, University Medical Centre Utrecht, Utrecht, The Netherlands
2Department Neonatology, Division Perinatology and Gynaecology, University Medical Centre Utrecht, Utrecht, The Netherlands
Ultrasound Med Biol 2008 (in press)
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ABSTRACT
The purpose of this prospective longitudinal study was to evaluate the growth of the
fetal cerebellar volume by means of three dimensional ultrasound, to evaluate whether
there is a difference between the volumes of the left and right cerebellar hemispheres,
and to evaluate the intra- and inter-observer reliability of two different techniques of
volume measurement.
Three-dimensional ultrasound examinations were performed every two to three
weeks on 27 fetuses between 20 and 40 weeks’ gestation. Measurements of the total
cerebellar volume and of the left and right cerebellar hemispheres were done using
the multiplanar technique. Multilevel analysis was used to determine the growth of
cerebellar volume based on individual developmental trajectories and to compare
the volume of the right and left hemispheres of the cerebellum. The intra- and
interobserver reliability was calculated for the multiplanar and VOCALTM techniques in
a subgroup of ten fetuses. A growth curve of cerebellar volume in normal pregnancy
was generated.
The left cerebellar hemisphere was signifi cantly larger (12.3%, p<0.01) than the right.
The intraclass correlation coeffi cient for the measurements by the two techniques
was 0.99. Intra-observer reliability: the intraclass correlation coeffi cient for the
measurements using the multiplanar technique was 0.96 and 0.97 and for VOCALTM
it was 0.98 and 0.97 for the two observers respectively. Inter-observer reliability:
the intraclass correlation coeffi cient for the measurements using the multiplanar
technique was 0.97 and for VOCALTM 0.98. Longitudinal growth curves based on
individual developmental trajectories were generated for the cerebellar volume.
The left fetal cerebellar hemisphere was found to be signifi cantly larger than the
right. Both multiplanar and VOCALTM techniques had a good intra- and inter-observer
reliability and yielded very similar results.
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INTRODUCTION
Three-dimensional (3D) ultrasound has made it possible to measure volumes of organs
with an irregular shape more accurately. Previous studies have demonstrated that the
cerebellar volume is highly correlated with gestational age (GA) and with the transverse
cerebellar diameter (TCD). However, there were obvious differences in the volumes
obtained in different studies with the cerebellar volume from Oriental studies (1;2) 9
to 15% smaller at 32 weeks than in a Brazilian study (3).
Asymmetry of the cerebral hemispheres has been demonstrated with prenatal
ultrasound (4), but possible asymmetry of the cerebellar volume has not been studied
systematically in the fetus. Postnatal cerebellar asymmetry as a consequence of
atrophy has been described (5), and it would be useful to know whether and to what
extent physiological asymmetry of the fetal cerebellar hemispheres is present.
Two commonly used techniques of volume measurement are the multiplanar method
and the Virtual Organ Computer-Aided-Analysis (VOCALTM). The latter technique
involves rotating the data volume obtained by ultrasound around a fi xed axis in
sequential steps. The multiplanar technique entails scrolling through one plane while
manually measuring parallel slices in an orthogonal plane (Figure 1). The methods
have been validated in experimental and gynecological applications (6-9), but few
data are available on the intra- and inter-observer reliability of both methods in fetal
ultrasound (10).
We therefore decided to develop a growth curve of the total fetal cerebellar volume
and in a Dutch population, to evaluate asymmetry of the cerebellar hemispheres and
to evaluate the intra- and inter-observer reliability of the multiplanar and the VOCALTM
technique in measuring cerebellar volume.
METHODS
Twenty seven healthy pregnant women were included after a screening ultrasound
examination at 20 weeks had demonstrated no abnormal fi ndings in a singleton
pregnancy. Other inclusion criteria were confi rmation of pregnancy duration by
ultrasound during the fi rst trimester and absence of risk factors which might infl uence
fetal growth or development, such as maternal disease or previous intra-uterine growth
restriction. The study was approved by the Medical Ethics Committee of the University
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Medical Hospital Utrecht. Informed consent was obtained from each participant prior
to inclusion.
VOCALTM: rotational measurement of
volume around a fixed axis through a
number of sequential steps.
Multiplanar technique: measurement
of volume per slice along axis
Figure 1. Schematic illustration of measurement techniques
Ultrasound examinations were carried out by the same observer (LP) at an interval
of two to three weeks beginning at a gestational age between 20 and 24 weeks.
Firstly, normal biometry of the head circumference, transverse cerebellar diameter,
abdominal circumference and femur length was confi rmed. 3D ultrasound of the
intracranial contents was then carried out using a GE Voluson 730 Expert (General
Electric Healthcare, London) with a 4.0-8.5MHz abdominal probe (RAB4-8) when the
fetus was at rest. If fetal movement was observed during the volume acquisition
or movement artefacts were visible in the B-plane of the orthogonal display of the
scanned volume, the volume was discarded and replaced with another volume. All 3D
volumes were saved for offl ine examination with 4DView version 5.3 (General Electric
Healthcare, London). Data management and statistical analyses were performed using
SPSS 12.0 (SPSS Inc. Chicago, Illinois).
The display of the orthogonal planes from the 3D volume was standardized to facilitate
identifi cation of the right and left hand sides (11). (Figure 2) When the outlines of the
cerebellum could not be identifi ed accurately the examination was excluded.
For the multiplanar measurements we used the sagittal plane to outline the external
surface of the cerebellum and measured the cerebellar area slice by slice at 1 mm
intervals along the transverse axis. The program then calculated the volume making use
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of the outlined circumferences. All measurements were done three times. The volume
of the hemispheres were recorded separately by using the falx to aid identifi cation of
the midline.
Figure 2. Standardized display of orthogonal planes
To determine the intra-and inter-observer reliability the volumes of the fi rst ten fetuses
were measured by two observers (MR and LP) three times each for the multiplanar
and VOCALTM technique. For the VOCALTM measurements we used the axial plane as
reference plane. After defi ning the lateral poles of the cerebellum with the calipers
we outlined the external surface of the organ manually at rotations of 15° for a
gestational age up to 30 weeks and 9° from 30 weeks onwards. By the end of the
rotational process the program calculated the volume automatically and provided a
3D image of the organ volume.
The intra-observer reliability was evaluated by calculating the intraclass correlation
coeffi cient for the minimum and maximum of the three measurements that were
obtained of each volume with each measurement method. We determined the inter-
observer reliability by calculating the intraclass correlation coeffi cient for the median
of the three measurements of each observer for each measurement method. We
constructed Bland-Altman plots using the median measurement from both observers
to plot the difference between against the mean of the two medians. The intraclass
correlation was also used to compare the median values obtained with the multiplanar
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and VOCALTM techniques.
To develop growth curves the median of the three volume measurements with
the multiplanar technique by one observer (MR) and the median of the volume
measurements with VOCALTM of both observers were used. To obtain the best-fi t
equation for multilevel analysis to compare the cerebellar volume with gestational age,
we used the log naturalis in a model with random slope and random intercept, using
the linear mixed model option with restricted maximum likelihood procedure. We
composed growth lines with a 95% confi dence interval. Possible effects of symmetry,
fetal gender, lie (cephalic, breech or transverse) and position (right or left hand side
towards the observer) were also evaluated with multilevel analysis.
RESULTS
A total of 188 ultrasound examinations were carried out on 27 fetuses between 20
and 39 weeks. Forty three volume blocks (22.9%) were excluded due to insuffi cient
quality for accurate interpretation (13.8% of volume blocks up to 32 weeks and 43%
of the volume blocks after 32 weeks), leaving 145 volume blocks which were suitable
for analysis of the whole cerebellum and the left and right hemispheres, resulting
in a median of 6 (range 2-8) suitable volume blocks per fetus. These blocks were all
measured using the multiplanar technique. The VOCALTM technique was used in 58
volumes in ten fetuses, with a median of 6 (range 3-8) volume blocks per fetus.
With multilevel analysis, the growth curve of the cerebellar volume from our data
obtained with the multiplanar technique was predicted by ln(volume, mm3) =
1.502+0.052(GA)-0.000076(GA)2 (GA=gestational age in days) (Figure 3). For the
measurements obtained with VOCALTM the growth curve was ln(volume, mm3) =
0.047+0.064(GA)-0.0001(GA)2, yielding a very similar curve (Figure 4).
The main right-left effect was described by ß=-0.39(SE 0.13); p=0.003 and right-left by
gestational age interaction effect ß=0.0013 (SE 0.00064) p=0.0047. The left hemisphere
had a signifi cantly larger volume than the right hemisphere (median difference 12.3%,
range -48 – 54%) p< 0.001, paired t-test) which was more pronounced earlier in
pregnancy. (The median percentage difference until 32 weeks was 15.2% (-6% – +38%)
and after 32 weeks was 6.8% (-24% - +39%). After 36 weeks, the median percentage
difference was 5,4% (right-left difference not statistically signifi cant). With multilevel
analysis, the fetal gender, lie and position had no infl uence on the total cerebellar
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volume or asymmetry. The intraclass correlation coeffi cient for the measurements by
the two techniques was 0.99 (95% CI 0.98 – 0.99).
Figure 3. Cerebellar volume by gestational age (median and 95% confi dence intervals)
Figure 4. Comparison between cerebellar volume by multiplanar measurement (grey lines; median and 95% confi dence intervals) and VOCALTM measurements (median; solid black line)
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Intra-observer reliability: the intraclass correlation coeffi cient for the measurements
using the multiplanar technique was 0.96 (95% confi dence intervals CI 0.74 – 0.98) and
0.97 (95% CI 0.67-0.99) and for the measurements using VOCALTM it was 0.98 (95% CI
0.84-0.995) and 0.97 (95% CI 0.63-0.99) for the two observers respectively.
Inter-observer reliability: the intraclass correlation coeffi cient for the measurements
using the multiplanar technique was 0.97 (95% confi dence intervals CI 0.96 – 0.99) and
for the measurements using VOCALTM it was 0.98 (95% CI 0.97-0.99). Figure 5 displays
the Bland- Altman plots for both methods.
Figure 5. Bland-Altman plots
DISCUSSION
Only few studies have been published about the development of fetal cerebellar
volume obtained by 3D ultrasound in normal pregnancy. These include a cross-
sectional study by Chang on 231 fetuses (1), and longitudinal studies by Araujo Junior
(3) with two measurements each of 55 fetuses and by Hata (2) with a mean of 4.2
(±2.2) measurements each of 13 fetuses. All used polynomial regression analysis
rather than multilevel analysis. Multilevel analysis derives curves which are based
on individual developmental trajectories rather than separate data points and is
therefore eminently suited to the analysis of longitudinal data, whereas traditional
regression analysis presupposes the independence of observations. Multilevel analysis
can also compensate for missing observations and variation of the interval between
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observation (12). When comparing the results of the other studies with ours (Figure 6)
there are obvious differences such as the lack of data in the late third trimester in Araujo
Junior’s study (3), and the much smaller cerebellar size in the late third trimester in the
studies from Taiwan (1;2). These differences might be related to different statistical
methods, difference in measurement technique, or, as previously suggested, ethnic
differences (13). A recent Dutch study (14) also found larger measurements of the
transverse cerebellar diameter than previously found in studies performed in Britain
(15) and the United States (16). The similarity we found in the growth curves derived
from our data using two different measurement techniques and in different sample
sizes is a reassurance that the technique itself does not make a difference, but that one
should interpret cerebellar volumes with caution when using normal values derived
from a different population or ethnic group.
Figure 6. Comparison of the Utrecht data (grey lines; median and 95% confi dence intervals) with median values from earlier published studies (Araujo, solid black line; Chang, dot-dash black line; Hata, dashed black line)
We did fi nd an increase in the percentage of volume blocks which were not interpretable
at higher gestational ages. This might raise concerns about the clinical applicability of
cerebellar volume measurement in the late third trimester. On the other hand, while
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we took care to limit the examination time in this group of healthy volunteers, we could
still evaluate more than half of the volume blocks in fetuses older than 32 weeks. In a
patient where it would be important to measure the cerebellum, more volume blocks
could be obtained using different approaches, including transvaginal ultrasonography
(17;18).
Few prenatal studies have compared VOCALTM and multiplanar techniques of volume
assessment. An in vitro study suggested VOCALTM to be more precise than then
multiplanar technique for volume measurement of objects with irregular surfaces
(9). However, in prenatal assessment of lung volume the multiplanar technique was
deemed superior to VOCALTM (10). Satisfactory intra- and inter-observer reliability has
also been demonstrated for measuring fetal cerebellar volume using the multiplanar
technique (1;2). As far as we know the present study is the fi rst one to compare the
multiplanar and VOCALTM technique for fetal cerebellar measurement. Although the
Bland-Altman plots might suggest better reliability of the VOCALTM technique, there
is a high intraclass correlation coeffi cient for different measurements by the same
observer, by different observers and using both techniques. This would lead us to
conclude that either technique could be used to measure fetal cerebellar volume.
Although lateralization of structural (4;19) and functional (20) development of the
fetal brain is undoubtedly interesting, the importance of our fi nding of a degree of
lateral asymmetry in cerebellar volume would be of more importance where there
is concern about unilateral cerebellar atrophy. The latter has been described in the
neonate as the result of extreme prematurity (21;22) and is associated with poor
neurodevelopmental outcome, but has not been described in the fetus.
The next step would be evaluating whether cerebellar volume measurement improves
the accuracy of prenatal ultrasound to diagnose conditions where cerebellar growth
is impaired, such as pontocerebellar dysplasia (23). The advantage of being able to
measure the volume accurately might be offset by the disadvantage that it was not
always possible to measure the volume in late pregnancy. This needs to be evaluated
prospectively.
Our study included only singleton pregnancies. No signifi cant differences in cerebellar
growth between single and multiple pregnancies had been found in a study using two-
dimensional measurements(24), but it would need to be confi rmed that assessment
of growth using volume measurement is also equivalent in single and multiple
pregnancies. We only included patients from 20 weeks’ gestation, but the cerebellum
can be reliably visualized with high-resolution transvaginal ultrasound from the end
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of the fi rst trimester (25).
In conclusion, we generated longitudinal growth curves for cerebellar volume based
on individual developmental trajectories. The left fetal cerebellar hemisphere was
found to be signifi cantly larger than the right, especially before 32 weeks’ gestation.
There was an acceptable intra- and inter-observer reliability with both multiplanar
and VOCALTM techniques. Either technique could be used for measuring the cerebellar
volume, but volume measurements should be interpreted with caution when using
normal values derived from a different population.
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ultrasound fetal lung volume measurement: a systematic study comparing the multiplanar method with the
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(15) Snijders RJ, Nicolaides KH. Fetal biometry at 14-40 weeks’ gestation. Ultrasound Obstet Gynecol 1994; 4(1):34-
48.
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(16) Goldstein I, Reece EA. Cerebellar growth in normal and growth-restricted fetuses of multiple gestations. Am J
Obstet Gynecol 1995; 173(4):1343-1348.
(17) Malinger G, Ginath S, Lerman-Sagie T, Watemberg N, Lev D, Glezerman M. The fetal cerebellar vermis: normal
development as shown by transvaginal ultrasound. Prenat Diagn 2001; 21(8):687-692.
(18) Zalel Y, Seidman DS, Brand N, Lipitz S, Achiron R. The development of the fetal vermis: an in-utero sonographic
evaluation. Ultrasound Obstet Gynecol 2002; 19(2):136-139.
(19) Chi JG, Dooling EC, Gilles FH. Gyral development of the human brain. Ann Neurol 1977; 1(1):86-93.
(20) de Vries JI, Fong BF. Normal fetal motility: an overview. Ultrasound Obstet Gynecol 2006; 27(6):701-711.
(21) Limperopoulos C, Bassan H, Gauvreau K, Robertson RL, Jr., Sullivan NR, Benson CB et al. Does cerebellar injury in
premature infants contribute to the high prevalence of long-term cognitive, learning, and behavioral disability
in survivors? Pediatrics 2007; 120(3):584-593.
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in preterm infants is associated with impaired neurodevelopmental outcome. Eur J Pediatr 2008.
(23) McCann E, Pilling D, Hesseling M, Roberts D, Subhedar N, Sweeney E. Pontomedullary disconnection: fetal and
neonatal considerations. Pediatr Radiol 2005; 35(8):812-814.
(24) Goldstein I, Reece EA, Tamir A. Cerebellar growth in normal fetuses of multiple gestations. J Matern Fetal
Neonatal Med 2002; 11(3):188-191.
(25) Blaas HG, Eik-Nes SH, Kiserud T, Hellevik LR. Early development of the hindbrain: a longitudinal ultrasound study
from 7 to 12 weeks of gestation. Ultrasound Obstet Gynecol 1995; 5(3):151-160.
PATHOLOGY
Chapter 7THE ROLE OF PRENATAL ULTRASOUND IN
PREDICTING SURVIVAL AND MENTAL AND MOTOR
FUNCTIONING IN CHILDREN WITH SPINA BIFIDA
S. van der Vossen1, L.R. Pistorius2, E.J.H. Mulder2, M. Platenkamp1, Ph. Stoutenbeek MD2, G.H.A. Visser2, R.H.J.M. Gooskens1
1Department of Neurology and Neurosurgery, Rudolf Magnus Institute of Neuroscience, Utrecht2Department Obstetrics, Division of Perinatology and Gynecology, University Medical Centre Utrecht,
The Netherlands
Ultrasound Obstet Gynecol 2008 (in press)
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ABSTRACT
Background
Spina bifi da is one of the most common malformations and is detected effectively
by antenatal ultrasound screening. Once it is detected, well-founded counselling is
imperative.
Objective
To determine which prenatal ultrasound fi ndings can predict survival and mental and
motor functioning in children with spina bifi da.
Methods
Prenatal ultrasound examinations of all live born children who were prenatally di-
agnosed with spina bifi da from 1997 through 2002 (n=41) were retrospectively re-
viewed for lesion level, head circumference, ventriculomegaly, scoliosis and talipes.
These measures were correlated with postnatal anatomical and functional lesion lev-
els, survival and motor and mental outcome at fi ve years of age. The ability of prenatal
ultrasound to determine lesion level was also assessed in all fetuses diagnosed with
spina bifi da from 2006-2007 (n=18).
Results
Nineteen infants died before the age of fi ve years. Multivariate regression analysis
showed that higher lesion level (p < 0.05) and head circumference ≥ 90th percentile
(p = 0.01) were independent predictors of demise. None of the ultrasound features
were predictors of motor or mental functioning. Ultrasound predicted anatomical le-
sion level within 1 level of the postnatal fi ndings in 50% of the fi rst cohort and 89% of
the second cohort (p < 0.01).
Conclusion
Lesion level and head circumference on prenatal ultrasound are predictive for survival
in children with spina bifi da. No predictors were found for mental or motor function
at the age of fi ve years.
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INTRODUCTION
Spina bifi da is one of the most common and severe structural malformations in hu-
mans. The birth prevalence is between 0.3 and 0.6/1000 in Europe and Northern
America (1) but may be decreasing due to increased use of folic acid (2) or prenatal
diagnosis and termination of affected pregnancies (3).
Routine antenatal ultrasound is an effi cient means of screening for spina bifi da (4)
and a substantial proportion of parents opt for pregnancy termination when faced
with this diagnosis (5;6). Some parents might have chosen this option due to counsel-
ling which places emphasis on severe disability associated with spina bifi da (7). The
ability to reliably predict future functioning of children with spina bifi da, based on
prenatal ultrasound fi ndings, would be valuable to enable parents to make informed
decisions.
Previous studies have explored the role of prenatal imaging in predicting the progno-
sis of children with spina bifi da. These studies showed that lesion level, macrocephaly
and ventriculomegaly were associated with mental and motor outcome in children
with spina bifi da (8-12). However, these studies were based on relatively short follow-
up periods and are of varying methodological quality. We therefore decided to evalu-
ate the ability of prenatal ultrasound fi ndings to predict survival and future mental
and motor functioning in a retrospective cohort of children prenatally diagnosed with
spina bifi da.
METHODS
Patients
The study group consisted of all live born children who were prenatally diagnosed
with spina bifi da from 1997 through 2002 in the University Medical Centre Utrecht, a
tertiary care clinic in the Netherlands (First cohort). Exclusion criteria were insuffi cient
prenatal information, associated autosomal chromosomal disorders or additional
anomalies which could infl uence neurodevelopmental outcome. The gestational age
at diagnosis and the ability of prenatal ultrasound to determine lesion level were also
assessed in all fetuses diagnosed with spina bifi da from 2006-2007 in our institution
(second cohort).
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Ultrasound
Ultrasound examinations were performed by obstetricians with special training in
antenatal ultrasound examination and with state-of-the art equipment. Ultrasound
data were retrieved from text reports, medical notes and if necessary from reviews
of stored still or moving images by one of the authors (LP) while being unaware of
postnatal data. Items to be scored were the lesion level (the lowest intact vertebral
body) (13), head circumference (HC) and HC percentile for gestational age, width of
the atrium of the lateral ventricle (14) and the ventricle-hemisphere ratio (VHR), sco-
liosis and talipes. The lesion level was defi ned as a high lesion when the lowest intact
vertebral body was at L3 or above and a low lesion if the lowest intact vertebral body
was at L4 or below (12;15). Ventriculomegaly was defi ned as atrial width ≥ 15 mm.
Both unilateral and bilateral involvement was considered as presence of talipes.
If multiple ultrasound examinations were available for one fetus, the examination
closest to the term of 20 weeks of gestation was used.
Follow-up
All children were postnatally evaluated and followed by a multi-disciplinary spina bi-
fi da team. The postnatal course and lesion level as recorded in the clinic notes were
noted for all patients. In case of survival, mental and motor functioning were classi-
fi ed according to the fi ndings during follow-up visits at the age of fi ve years.
Motor functioning was dichotomised to discriminate good motor function (commu-
nity or household ambulators) from poor motor function (non-functional ambulators
or non-ambulators) (16).
Good mental outcome was defi ned as following regular education or an IQ score ≥
80. Poor mental functioning was defi ned as a combination of following special educa-
tion and an IQ-score < 80. Mental functioning was also assessed using the Cognitive
Health Score (CHS) of a Dutch version (17) of the Hydrocephalus Outcome Question-
naire (HOQ) (18). The need for shunt placement or revision for hydrocephalus was
noted.
Statistical analysis
We assessed the ability of prenatal ultrasound to predict survival and the height of the
lesion level in the whole study population, and motor and mental functioning in chil-
dren who survived until the age of fi ve years. We also assessed the ability to predict
motor and mental functioning by means of the postnatally determined anatomical
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lesion level.
Descriptive analyses were performed using Fisher’s exact test on dichotomised pa-
rameters. To relate survival, mental and motor prognosis to the different parameters
univariate logistic regression analysis was fi rst performed to identify the most im-
portant predictive factors. Items with a p-value < 0.10 in univariate analysis were in-
cluded in a multivariate logistic regression analysis, in which p < 0.05 was considered
signifi cant. The results are expressed as odds ratios (OR) and 95% confi dence intervals
(95% CI). The appropriateness of the cut-off values for lesion level, ventriculomegaly
and ventricle-hemisphere ratio were further investigated with the use of a receiver
operator characteristic curve (ROC) to determine the cut-off point with optimal sensi-
tivity and specifi city.
To relate mental outcome as assessed by the CHS (a continuous variable) to ultra-
sound items, linear regression was used.
The agreement of prenatal and postnatal lesion level assignation was assessed by
computing the difference in prenatal level assignment by ultrasound and postnatal
level assignment by MRI or X-ray imaging.
Data management and statistical analysis were performed with SPSS version 12.0 for
Windows (SPSS Inc. Chicago, Illinois).
RESULTS
Study population
Seventy fetuses were diagnosed with spina bifi da in the study period at a median
gestational age of 29 weeks (range 13-42 weeks). Twenty two pregnancies were ter-
minated. Six children were excluded because of the following: associated syndromal
or chromosomal disorders (n = 3), additional anomalies which infl uenced neurodevel-
opmental outcome (n = 1), insuffi cient prenatal information (n = 1) and parents de-
clining consent for participation in this project (n = 1). One child was lost to follow-up
before fi ve years of age. This led to the fi nal study population of 41 children. Nineteen
of these children died (46%), eighteen of them during the neonatal period and one
at the age of two years due to a symptomatic Chiari II malformation. Information re-
garding motor functioning and type of education could be retrieved for all 22 children
who survived until fi ve years. In three cases the HOQ could not be completed due to a
language barrier or the parents declining to complete the HOQ.
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Of the fi nal study population 25 were male (61%). The median gestational age at ul-
trasound examination was 35 (range 20-42) weeks in the main cohort, and 20 (range
18–38) weeks in the second cohort. The second cohort comprised 23 children, of
whom the postnatal lesion height was known in 18.
Survival
In univariate analysis a lesion at L3 or higher, a HC ≥ 90th percentile, VHR>0.5 and the
presence of scoliosis were negatively correlated with survival with p<0.10 (Table 1).
In multivariate analysis only HC ≥ 90th percentile (OR 12.6, 95% CI 1.7-91.5, p = 0.01)
and high lesion level (OR 5.8, 95% CI 1.0-32.1, p < 0.05) appeared to be independently
related to demise before 5 years.
Employing a ROC-curve, a cut-off point between T12 and L1 gave the best combina-
tion of sensitivity and specifi city. Using this cut-off point resulted in a stronger rela-
tion between lesion level, HC ≥ 90th percentile and survival. Presence of these two
ultrasound items demonstrated odds ratios of 16.5 (95% CI 2.6-104.0, p = 0.003) and
15.3 (95% CI 1.8-130.8, p = 0.01) for demise for a high lesion level and increased HC
respectively. The chances of survival according to lesion level and HC are depicted in
Table 2.
Motor outcome
Fifteen children (68%) were household or community ambulators and seven were
non-ambulators. Neither the ultrasound markers nor the postnatally determined ana-
tomical lesion level was related to motor outcome at the age of fi ve years in univariate
analysis, regardless of the cut-off point for lesion level (Table 1). As a result multivari-
ate analysis was not performed for motor outcome.
Mental outcome
Thirteen children (59%) were able to follow regular education. Nine children, of whom
six with an IQ score below 80, attended special education. In univariate analysis none
of the ultrasound markers showed a signifi cant relationship with poor mental out-
come (Table 1).
The median CHS in this patient sample was 0.58 (range 0.25-1.00). In univariate analy-
sis only HC ≤ 10th percentile reached a p-value < 0.10 (Table 1). HC ≤ 10th percentile
showed a trend in predicting higher CHS (p = 0.06).
Postnatal anatomical lesion level was not related to mental outcome. However, the
postnatal anatomical lesion level at T12 or higher predicted a lower CHS (p = 0.04). In
fi
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mu
ltiv
aria
te a
nal
ysis
, nei
ther
th
e p
ostn
atal
an
atom
ical
leve
l nor
a H
C ≤
10t
h p
erce
nti
le c
orre
late
d s
ign
ifi ca
ntl
y w
ith
th
e C
HS.
Tab
le 1
. Res
ult
s of
un
ivar
iate
an
alys
is, r
elat
ing
ult
raso
un
d it
ems
to s
urv
ival
, men
tal a
nd
mot
or o
utc
ome
Dem
ise
bef
ore
5 yr
Poor
mot
or f
un
ctio
nin
gM
enta
l ou
tcom
eSp
ecia
l ed
uca
tion
+ IQ
Men
tal o
utc
ome
CH
S
OR
CI
pO
RC
Ip
OR
CI
pB
CI
p
HC
≥ 9
0th p
erce
nti
le8.
01.
4;44
.90.
022.
30.
1;43
.80.
570.
00.
00.
99-0
.11
-0.4
9;0.
270.
55
HC
≤ 1
0th p
erce
nti
le0.
80.
2;3.
30.
720.
30.
03;3
.60.
360.
40.
04;4
.80.
500.
23-0
.01;
0.48
0.06
VM
3.4
0.6;
19.5
0.17
1.0
0.1;
7.5
1.00
2.5
0.23
;27.
60.
450.
04-0
.25;
0.32
0.79
VH
R ≥
0.50
4.6
1.2;
17.5
0.03
0.6
0.1;
4.2
0.61
6.0
0.78
;46.
10.
09-0
.11
-0.3
5;0.
120.
33
Scol
iosi
s8.
30.
8;83
.20.
07-*
--
-*-
--*
--
Talip
es6.
00.
5;68
.70.
150.
00.
01.
000.
00.
01.
00-*
--
US
lesi
on L
3 or
hig
her
3.1
0.8;
11.8
0.09
0.9
0.1;
5.2
0.87
1.3
0.2;
8.4
0.79
0.02
-0.2
2;0.
250.
89
US
lesi
on T
12 o
r h
igh
er9.
02.
1;38
.80.
003
2.6
0.3;
23.8
0.40
3.5
0.37
;33.
30.
280.
18-0
.09;
0.46
0.18
PN le
sion
L3
or h
igh
er-
--
2.9
0.42
;19.
60.
292.
00.
28;1
4.2
0.49
-0.1
5-0
.37;
0.08
0.20
PN le
sion
T12
or
hig
her
--
-3.
70.
56;2
4.1
0.18
6.0
0.78
;46.
10.
090.
230.
01;0
.45
0.04
HC
: Hea
d c
ircu
mfe
ren
ce; V
M: v
entr
icu
lom
egal
y; V
HR:
Ven
tric
le h
emis
ph
ere
rati
o; U
S: u
ltra
sou
nd
; PN
: pos
tnat
al; C
HS:
cog
nit
ive
hea
lth
sco
re; O
R: o
dd
s ra
tio;
CI:
95%
con
fid
ence
inte
rval
; p: p
-val
ue
* Log
isti
c re
gres
sion
an
alys
is c
ould
not
be
calc
ula
ted
du
e to
sm
all s
amp
le s
ize.
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Table 2. Survival according to head circumference and lesion height categories.
Head circumference ≥p90 Head circumference <p90
Lesion ≥L3 1/6 (17%) 9/17 (53%)
Lesion ≤L4 1/4 (25%) 11/12 (92%)
Head circumference ≥p90 Head circumference <p90
Lesion ≥T12 1/6 (17%) 5/12 (42%)
Lesion ≤L1 1/4 (25%) 15/17 (88%)
Survivors / total n (%)
Shunting for hydrocephalus
Twelve patients with good (80%) and six with poor motor function (86%) required
shunting for hydrocephalus. Four with good (33%) and two with poor motor function
(33%) required more than one shunt revision. Thirteen patients with good (85%) and
seven patients with poor mental function (78%) required shunting (p=1.0). Five with
good (39%) and two with poor mental function (28%) required more than one shunt
revision (p= 0.32).
<0: prenatal level assignment lower than postnatal level assignment >0: prenatal level assignment higher than postnatal level assignment
Figure 1. Difference between antenatal and postnatal lesion level assignment.
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Prenatal assignation of lesion level
Both the prenatal and postnatal assessment of lesion level was available in 40 pa-
tients in the main cohort and in 18 patients in the second cohort. The prenatally as-
signed lesion level underestimated the postnatal anatomical lesion level with a mean
of 1.3 (SD 2.4) vertebral levels in the main cohort and with a mean of 0.3 (SD 0.9)
vertebral levels in the second cohort. In 20 patients (50%) of the fi rst cohort and in
in 16 patients (89%) of the second cohort the prenatally assigned level was within 1
level (p<0.01) (Figure 1). Six patients of the second cohort were assessed with three
dimensional (3D) ultrasound, and the prenatally assigned level was within 1 level of
the postnatal anatomical level in all six. Examples of level determination with 2D and
3D equipment is shown in fi gure 2.
Two dimensional ultrasound Three dimensional ultrasound
Figure 2. Ultrasound diagnosis of anatomical level of spina bifi da.
Prenatally assigned lesion level underestimated the postnatal functional lesion level
as assigned by neurological examination with a mean of 0.8 vertebral levels (SD 2.9).
The postnatal anatomical level was a mean of 0.4 levels higher than postnatal func-
tional level (SD 2.3, range four levels lower to six levels higher) (Figure 3).
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<0: anatomical level lower than functional level >0: anatomical level higher than functional level
Figure 3. Difference between anatomical and functional level assignment.
DISCUSSION
Our study group was chosen to allow for fi ve-year follow-up in all infants. The disad-
vantage is that the ultrasound examinations were done with equipment with lower
resolution than nowadays and without a 3D capability, and at a time when screening
for neural tube defects in the Netherlands was offered to high-risk patients rather
than as routine screening (6). Indeed, there was a distinct improvement in our ability
to predict lesion level in the second cohort using modern ultrasound (and sometimes
3D (19)), equipment and the gestational age at diagnosis has decreased dramatically
since the introduction of routine ultrasound screening in pregnancy.
It is interesting that we found a strong correlation between survival and prenatal pa-
rameters such as lesion height and macrocephaly which have been found to correlate
with motor and mental function in other studies (8-12). One reason for this might be
the difference in management in our unit, where all infants born with spina bifi da are
not routinely scheduled for surgery, but are fi rst evaluated by a multidisciplinary team.
If it is the opinion of the multidisciplinary team that a very poor quality of life is antici-
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pated despite surgery, and the parents opt against surgery, only palliative care is given
(28). It is conceivable that an infant who otherwise would have survived with poor
motor and mental function after surgery would not survive, with the consequence
that the predictors of poor function (such as high lesion level, ventriculomegaly or
macrocephaly) found in other studies correlated to (neonatal) demise in our group.
Other possible explanations for the differences between our and other studies may
lie in the longer follow-up period, differences in determining or categorizing motor
and mental outcome and our more rigorous statistical analyses. We categorized com-
munity and household ambulation as good motor outcome, as the possibility to walk
even indoors adds to autonomy and quality of life.
We categorized a combination of inability to attend normal education and IQ below
80 (“mild mental retardation”) as poor mental function, because several parents could
not indicate whether their child was in special education due to the physical handicap
alone or because of an additional developmental delay. Furthermore, the CHS was
chosen to assess mental functioning more reliably. Previous studies have shown that
hydrocephalus is an important determinant of cognitive functioning in children with
spina bifi da (21-28). The Dutch translation of this questionnaire has been shown to
have good applicability for determining outcome in hydrocephalic children (17).
We found a trend between the presence of a HC at or below the 10th percentile and
higher CHS scores. The sample size of this study is too small to conclude that a small
HC shows a protective effect on cognitive function, but that the presence of a small
HC in a fetus with spina bifi da is not necessarily a negative fi nding. Also, postnatally
determined high lesion level (T12 or above) showed a relationship to higher CHS but
not to type of education and IQ. Lesion level might possibly be related to mental func-
tioning, but this relation is not unequivocal and we cannot claim to predict future
mental outcome by means of prenatally determined lesion levels.
Suboptimal determination of the lesion level may also play a part in the differences
between our and other studies. However, anatomical lesion level as determined post-
natally also differs from the functional level with as much as six vertebral levels, and
does not predict motor and mental function, either.
The available literature varies regarding the accuracy of antenatal ultrasound to dem-
onstrate the lesion level varies. Six (8;10;12;29-31) out of eight (8;10;12;29-33) studies
concluded that prenatal ultrasound revealed good agreement with postnatal fi ndings.
However, only three studies correlated prenatal lesion level assignation to postnatal
functional lesion level, also with varying accuracy (10;30;31). Intervening factors such
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as central nervous system infections and shunt complications may also have infl u-
enced neuromotor development (34).
It is also possible that some parameters may indeed be better predictors than shown
by our study. Retrieving ultrasound data from ten-year old video tapes or suboptimal
still images cannot be as accurate as real-time scanning. Lesion level, unless explicitly
stated, as well as the presence or absence of scoliosis or talipes was often diffi cult to
ascertain. Although we tried to minimise the effect of gestational age by using per-
centiles and ratios for analysis, we cannot rule out an effect of gestational age on spe-
cifi c ultrasound parameters (35;36). This may restrict the applicability of the results.
On the other hand, the lesion level would not change during gestation, although it
might be easier to ascertain it at twenty weeks than in the third trimester. To our best
knowledge, this is the fi rst study to investigate the possibility of predicting survival
with prenatal ultrasound fi ndings in children with spina bifi da. We found a lesion level
at L3 or above and the presence of HC ≥ 90th percentile to be independent prognostic
items of demise with high odds ratios, with an even stronger association if a cut-off
level at T12 is used. The wide confi dence intervals might be due to the small sample
size. Since the cut-off point at T12 was determined retrospectively with ROC analysis,
it needs to be evaluated prospectively.
In conclusion, we found prenatal ultrasound predictive of survival, but not of men-
tal or motor function at the age of fi ve years. Prediction of future mental or motor
function from ultrasound parameters during antenatal counselling seems therefore
impossible.
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nervous system. Ultrasound Obstet Gynecol 2007 Aug;30(2):233-45.
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spina bifi da. Dev Med Child Neurol 2003 Dec;45(12):813-20.
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dictors of type of education in young adults with spina bifi da. Int J Rehabil Res 2004 Mar;27(1):45-52.
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(33) Bruner JP, Tulipan N, Dabrowiak ME, Luker KS, Walters K, Burns P, et al. Upper level of the spina bifi da defect: how
good are we? Ultrasound Obstet Gynecol 2004 Nov;24(6):612-7.
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with myelomeningocele: correlation with gestational age and severity of posterior fossa deformity. Radiology
1994 Mar;190(3):703-7.
(36) Biggio JR, Jr., Wenstrom KD, Owen J. Fetal open spina bifi da: a natural history of disease progression in utero. Pre-
nat Diagn 2004 Apr;24(4):287-9.
Chapter 8MIDDLE CEREBRAL ARTERY PULSATILITY INDEX IN
FETAL CENTRAL NERVOUS SYSTEM ABNORMALITIES
L.R. Pistorius1, R.H.J.M. Gooskens2, Ph. Stoutenbeek1, E.J.H. Mulder1, G.H.A. Visser1
1Department Obstetrics, Division of Perinatology and Gynecology, University Medical Centre Utrecht, The Netherlands
2Department of Neurology and Neurosurgery, Rudolf Magnus Institute of Neuroscience, Utrecht, The Netherlands
Ultrasound Obstet Gynecol (under revision)
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ABSTRACT
Objectives
A retrospective cohort study was undertaken to evaluate the prognostic value of the
middle cerebral artery pulsatility index (mca PI) in fetuses with central nervous system
abnormalities.
Methods
Antenatal mca PI and ultrasound fi ndings of fetuses with central nervous system
abnormalities evaluated from 2000 through 2006 in a tertiary unit were related to
subsequent neurodevelopmental outcome.
Results
The mca PI was available for 141 fetuses. Median follow up of 21 months was available
for 135 infants (96%). There was a signifi cantly higher risk of neurodevelopmental delay
in infants with an antenatal fi nding of an increased mca PI. This was true for the whole
group, and especially the subgroup of infants with isolated central nervous system
pathology including aqueductal stenosis, but excluding infants with spina bifi da
or multiple abnormalities. An interesting pattern of initially high and subsequently
decreasing mca PI was seen in infants with malformations of cortical development,
microcephaly, agenesis of the corpus callosum and West’s syndrome. A rapid rise of
mca PI was associated with a high risk of demise.
Conclusions
In fetuses with abnormalities of the central nervous system an antenatal fi nding of
increase in mca PI is associated with a increased risk of adverse neurodevelopmental
outcome. This does not apply to fetuses with spina bifi da or multiple abnormalities.
An increased mca PI which subsequently decreased was seen in fetuses that subsequently
were diagnosed with malformations of cortical development, microcephaly, agenesis
of the corpus callosum and West’s syndrome. A rapid rise in mca was seen in fetuses
with a high risk of demise.
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INTRODUCTION
Doppler indices of cerebral blood fl ow are used postnatally to diagnose raised
intracranial pressure in infants with hydrocephalus (1). The value of these indices is
less certain in the prenatal period (2;3), and standard fetal neurosonography does
not include these measurements (4). This raises the question whether measuring
middle cerebral artery fl ow is of value in a fetus with pathology of the central nervous
system (CNS). We therefore undertook a retrospective cohort study to determine the
prognostic value of the middle cerebral artery pulsatility index (mca PI) in fetuses with
ultrasound evidence of CNS pathology. To test the hypothesis that an enlargement
of cerebral ventricles above a certain critical size might lead to a decrease in cerebral
blood fl ow, the relationship between ventricular atrial diameter, head circumference
and mca PI was also examined.
METHODS
A complete fetal ultrasound examination including measurement of the mca PI was
performed in patients who were referred to a single tertiary unit with an ultrasound
diagnosis of a fetal central nervous system abnormality. Antenatal and intrapartum
management (including repetition of the examination) and postnatal follow-up were
performed as clinically indicated. Examinations from 2000 until 2006 were included in
the analysis. Abnormalities were classifi ed under spina bifi da, multiple abnormalities
and isolated central nervous system abnormalities. For the analysis, a pulsatility
index value more than two standard deviations above the mean for gestational
age was considered abnormal (5). In fetuses with repeated mca PI measurements,
the pattern was analyzed (with the expected fi ndings either a repeatedly normal
mca PI or an increased mca PI developing in a fetus with initially a normal mca PI).
Major neurodevelopmental delay was defi ned as the presence of cerebral palsy, a
Bayley neurodevelopment score less than two standard deviations below the mean,
deafness or blindness (6). Minor neurodevelopmental delay was defi ned as any other
neurological, psychological or behavioral abnormality of suffi cient severity to warrant
repeated medical referral. Statistical analysis was done with SPSS (version 12.0.1, SPSS
Inc, Chicago). Descriptive statistics of continuous data which are normally distributed
are given as mean (standard deviation), and of continuous data which are not normally
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distributed as median (range). Doppler fi ndings were correlated with the presence of
neurodevelopmental delay in live born fetuses in a two by two table, and analyzed with
Fisher’s exact test. Pearson’s R was calculated for the correlation between the multiple
of the median (MoM) of the mca PI and the MoM of the head circumference (HC), and
the MoM of the mca PI and the maximum ventricular atrial width, respectively.
RESULTS
A total of 385 mca PI measurements were obtained from 141 fetuses. The gestational
age at diagnosis and delivery, and interval between the last mca PI measurement
and delivery are given in Table 1. Forty seven infants (33%) had a fi nal diagnosis of
a spina bifi da, in 35 fetuses (25%) the fi nal diagnosis confi rmed CNS fi ndings as part
of a complex with multiple abnormalities (including chromosomal abnormalities), 50
infants (26) had a CNS abnormality not related to a spina bifi da or other abnormalities,
and in 9 infants (26) no CNS abnormality or physiological variations of the normal could
be confi rmed postnatally and these were excluded from further analysis. Follow-up
was available in 126 infants (95%). Of these, sixty eight infants survived the neonatal
period and were followed up for a median of 21 months (range 1-84 months).
a.”Increasing” pattern b. “Decreasing” pattern
Figure 1. Repeated mca PI measurements
ff
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Tab
le 1
. Ges
tati
onal
age
at
dia
gnos
is, t
ime
inte
rval
fro
m la
st D
opp
ler
mea
sure
men
t u
nti
l del
iver
y, m
ode
of d
eliv
ery
and
su
rviv
al
Tota
l:n
Ges
tati
onal
age
at
dia
gnos
is:
Med
ian
wee
ks(r
ange
)
Ges
tati
onal
age
at
del
iver
y:
Med
ian
wee
ks(r
ange
)
Tim
e fr
om
last
Dop
ple
r m
easu
rem
ent
un
til
del
iver
y:M
edia
n d
ays
(ran
ge)
Mod
e of
del
iver
y:ca
esar
ean
sec
tion
/
vagi
nal
del
iver
yn
Surv
ival
aft
er
neo
nat
al p
erio
d
(los
t to
fol
low
-u
p):
n
Spin
a b
ifi d
a47
32(1
6-40
)39
(21-
42)
10(0
-48)
18 /
29
28
Mu
ltip
le a
bn
orm
alit
ies
3529
(17-
37)
35(1
5-42
)21
(0-1
23)
5 /
307
CN
S ab
nor
mal
itie
s w
ith
out
spin
a b
ifi d
a or
oth
er a
bn
orm
alit
ies
5028
(14-
40)
38(2
1-41
)13
(0-1
16)
18 /
32
27 (3
)
C
orp
us
callo
sum
age
nes
is6
2 /
46
(1)
A
qu
edu
ct s
ten
osis
2812
/ 1
612
M
icro
cep
hal
y3
1 /
23
(2)
M
alf
of c
orti
cal d
evel
opm
ent
31
/ 2
2
H
olop
rose
nce
ph
aly
21
/ 1
2
C
ereb
ellu
m a
nd
pos
t fo
ssa
20
/ 2
0
O
ther
61
/ 5
5
Un
confi
rmed
927
(21-
33)
39(3
6-40
)53
(12-
110)
1 /
89
(3)
Tota
l14
129
(14-
40)
38(1
5-42
)14
(0-1
23)
42 /
99
74 (6
)
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The median gestational age at diagnosis decreased from a median of 31 weeks (range
16-40) in 2000-2003 to 27 weeks (14-40) in 2005-2006 (Mann-Whitney U test 2-tailed
p=0.011).
A single mca PI measurement was available in 62 fetuses, two measurements were
done in 26 fetuses, and three or more measurements were done in 44 fetuses. The
time interval between the last mca PI measurement and delivery was a median of 14
days (range 0 to 123 days).
In 105 fetuses the mca PI was (and remained) normal, and in 27 the mca PI was
increased to more than 2SD above the mean (Table 2).
Table 2. Middle cerebral artery Doppler measurements and fi ndings
Middle cerebral artery pulsatility index
Normal once
Normal by repetition
Increasing pattern
Decreasing pattern
High once
Total
Spina bifi da 15 30 0 2 0 47
Multiple abnormalities 19 9 1 1 5 35
Isolated CNS abnormalities 18 14 4 9 5 50
Cca 4 1 0 1 0 6
Aqueduct stenosis 11 7 4 3 4 29
Microcephaly 0 1 0 2 0 3
Mcd 1 0 0 1 1 3
Holoprosencephaly 2 0 0 0 0 2
Cerebellum 0 2 0 0 0 2
Other 0 3 0 2 0 5
Total 52 53 5 12 10 132
Percentage of total 39% 40% 4% 9% 8% 100%
CNS = central nervous system; cca=corpus callosum agenesis; mcd = malformation of cortical development
In case of an increased mca PI , two main patterns could be distinguished: a pattern
of increasing PI, and a pattern of decreasing PI. The “increasing” pattern (Figure 1 a.)
was seen in 5 patients (5/70 or 7% of fetuses with repeated Doppler measurements),
and occurred signifi cantly more frequently in fetuses with aqueduct stenosis (4/14 of
repeated Doppler measurements in fetuses with aqueduct stenosis; 1/56 of all other
fetuses; p=0.0048). The median gestational age at delivery in infants with repeatedly
normal Doppler measurements was 38 weeks (21-42 weeks) and in infants with an
“increasing” pattern was 36 weeks 35-40 weeks) (difference not signifi cant; Mann-
Whitney U test p=0.32). The time until delivery in patients with aqueduct stenosis and
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f
an “increasing” pattern was a median of 9.5 days (range 4-16 days); and in the other
patients with repeated Doppler measurements it was 14.5 (1-52) days (Mann-Whitney
U test p=0.24). Three out of fi ve infants with an “increasing” pattern died intrapartum
or postnatally (Table 3).
Table 3. Abnormalities and outcome of foetuses with abnormal mca PI
Pattern Patient Findings and outcome
Increasing pattern (Figure 1a)
1 Microcephaly, akinesia, early neonatal death
2 Severe hydrocephalus, intrapartum demise after cephalocentesis
3 Severe progressive hydrocephalus, early neonatal death after abstaining from treatment
4 Hydrocephalus, delayed speech and motoric development at 18 months
5 Hydrocephalus, hemiplegia, syndrome of West at 18 months
Decreasing pattern (Figure 1b)
1 Lumbosacral spina bifi da, hydrocephalus, motoric impairment lower limbs at 12 months
2 Lumbosacral spina bifi da, motoric impairment lower limbs at 30 months
3 Congenital CMV infection, moderate neurodevelopmental impairment at 13 months
4 Corpus callosum agenesis; delayed motoric development at 15 months
5 Unilateral ventriculomegaly; normal development at 14 months
6 Ventriculomegaly, syndrome of West at 30 months
7 Hydrocephalus, lissencephaly, probably Walker-Warburg syndrome, intrapartum demise
8 Microcephaly, lost to follow-up after age 4 months
9 Microcephaly chorioretinal dysplasia at 16 months
10 Lissencephaly and corpus callosum agenesis, global neurological delay at 13 months
11 Encephalocoele, corpus callosum atrophy, nodular heterotopia, epilepsy at 12 months
12 Arachnoid cyst, syndrome of West at 6 months
The “decreasing” pattern (Figure 1 b.) of the PI mca was seen in twelve infants, eight
of whom subsequently manifested abnormalities related to malformations of cortical
development, microcephaly, corpus callosum agenesis or syndrome of West (Table 3).
No signifi cant correlation was found between the MoM mca PI and maximum
ventricular atrial diameter (Pearson R=0.011, P=0.92, n=76). A weak positive correlation
was found between the MoM mca PI and MoM head circumference (Pearson R=0.22,
P=0.010, n=134).
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The distribution of Doppler fi ndings associated with different neurological diagnoses
is displayed in Table 2. The relationship between Doppler fi ndings and outcome is
displayed in Table 4.
Table 4. Pattern of middle cerebral artery Doppler abnormalities and outcome at follow-up
Outcome Middle cerebral artery pulsatility index
Normal once
Normal by repetition
Increasing pattern
Decreasing pattern
High once
Total Percentage of total
Unknown 3 2 0 1 0 6 5%
TOP / IUD 22 9 0 0 6 37 28%
Neonatal / infant death 12 10 3 1 1 27 20%
Alive & well 5 5 0 1 0 11 8%
Mild neuro 5 17 0 2 1 25 19%
Severe neuro 5 10 2 7 2 26 20%
Middle cerebral artery pulsatility index
Always normal Ever abnormal Total Percentage of total
Unknown 5 1 6 5%
TOP / IUD 31 6 37 28%
Neonatal / infant death 22 5 27 20%
Alive & well 10 1 11 8%
Mild neuro 22 3 25 19%
Severe neuro 15 11 26 20%
TOP=termination of pregnancy; IUD=intra-uterine or intrapartum demise; neuro=neurodevelopmental delay
In the whole group there was a signifi cant association between adverse mca PI fi ndings
antenatally and subsequent adverse neurodevelopmental outcome (p<0.05). In fetuses
with a spina bifi da or multiple anomalies, there was no association between the PI mca
and outcome. In fetuses with CNS abnormalities not associated with a spina bifi da or
other abnormalities, there was also a signifi cantly higher risk of adverse outcome if
an increased mca PI was found (p<0.05). In fetuses with a fi nal diagnosis of aqueduct
stenosis, the increase in adverse outcome in case of Doppler abnormalities was on the
borderline of statistical signifi cance (Fisher’s exact p=0.072) (Table 5).
No correlation could be found between head circumference (expressed as multiples
of the median) and outcome in the study group or any subgroup. No signifi cant
association could be detected between the maximum diameter of the ventricular
atrium and outcome either.
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Table 5. Correlation between middle cerebral artery pulsatility index and neurodevelopmental outcome
Doppler always normal Doppler ever highA B
Outcome normal moderate severe normal moderate severe
Study 11 20 16 1 3 11 0.26 0.007**
Spina 2 19 5 0 2 0 1.0 1.0
Multiple 0 0 5 0 0 2 # #
Isolated 9 1 6 1 1 9 0.04* 0.047*
Aqueduct 5 0 3 0 1 3 0.26 0.6
Study=study group (all known follow-up, confi rmed central nervous system abnormalities, n=62)Spina = spina bifi daMultiple = multiple abnormalitiesIsolated = isolated CNS abnormalitiesAqueduct = aqueduct stenosisNormal = normal outcomeModerate = moderate neurological delaySevere = Severe neurodevelopmental delayA=Fisher’s exact test (normal versus moderate or severe)B= Fisher’s exact test (normal or moderate versus severe) * = signifi cant (p<0.05)** = signifi cant (p<0.01)# = impossible to calculate
DISCUSSION
The results from this study demonstrate an association between increased pulsatility
index of the middle cerebral artery and neurodevelopmental outcome in fetuses with
central nervous system abnormalities. Our fi ndings are consistent with neonatal
fi ndings (1;7), as well as previous fi ndings of a progressive increase in pulsatility index of
the internal carotid artery in four fetuses with increasing hydrocephalus (8). However,
these studies did not try to determine an association between Doppler fi ndings and
neurodevelopmental outcome.
The increase in mca PI might refl ect an increase in intracranial pressure, with a resulting
decrease in cerebral perfusion pressure and decrease in diastolic fl ow (9). This was,
indeed, the working hypothesis, and an increase in mca PI acted as an indication for
earlier delivery. This was confi rmed by the shorter (although not statistically signifi cant)
interval from the last Doppler measurement until delivery in these patients. Despite
the earlier delivery, the outcome was still worse than in the group of patients with
normal mca PI measurements. It might be that the interval to delivery was still too long,
exposing the fetal cortex to increased pressure for too long. The increase in pulsatility
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index might also be too late a fi nding, and another index such as the transsystolic
time (9), or maximum systolic fl ow velocity (vmax) might be more sensitive to detect
impaired cerebral fl ow. It might be also be more appropriate to assess cerebral venous
fl ow patterns (10).
Previously, no correlation between the middle cerebral artery resistance index and the
lateral ventricular width could be demonstrated in 430 normal fetuses, three fetuses
with ventriculomegaly and three with hydrocephalus (11). In our large group of fetuses
with central nervous system pathology, there was also no correlation between mca
PI and ventricular diameter. Only a very weak correlation between mca PI and head
circumference could be found in cases with progressive hydrocephalus. This absence
of a strong correlation might be related to the capability of the fetal skull to expand
with increasing ventricular diameter without an increase in intracranial pressure great
enough to infl uence cerebral blood fl ow, or be related to the development of ex vacuo
hydrocephalus where the intraventricular and intracranial pressure would be expected
to be normal.
The fact that no association could be demonstrated between antenatal mca PI
measurements and outcome in fetuses with spina bifi da might be related to the
fact that the ventricular diameter is of less importance to the neurodevelopmental
development than the spinal abnormality. It might also be that increased intracranial
pressure would not develop to the same extent, as cerebrospinal fl uid could fl ow into
a meningocoele in case of increased intracranial pressure.
An unexpected fi nding was the “decreasing” pattern. The initially increased mca PI
in the fetus with asymmetrical ventriculomegaly and normal neurodevelopmental
outcome at 14 months might refl ect a false positive fi nding, or it might be too early
to detect more subtle neurodevelopmental delay. It could also have been related to
an intraventricular bleeding, as this can be diffi cult to detect on ultrasound (12). An
increase of the mca PI has previously been described in fetuses with intraventricular
hemorrhage (13;14). It is also interesting that the highest mca PI values were seen in
the fetus with congenital CMV infection, as cerebral vasculitis has been associated
with congenital CMV infection (15). The other eight cases with a “decreasing” pattern
were associated with malformations of cortical development (n=4 , two of which were
also associated with corpus callosum agenesis), microcephaly (n=2), West syndrome
(n=2) or corpus callosum agenesis with impaired neurological development (n=1).
Conversely, all infants with syndrome of West or malformations of cortical development
demonstrated an increased mca PI at some time antenatally.
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If the pressure hypothesis holds true for the patients with a normalizing pattern,
the law of Laplace (with a pronounced decrease in pressure associated with a small
increase in diameter) might play a part to allow a decrease in intracranial pressure
with an increase in head circumference. Another explanation would be a postulated
transient phenomenon which might lead to subsequent structural and functional
neurological abnormalities. If brain development is faulty, it is also conceivable that
the development of small vasculature is slower, with a cerebral vascular resistance
that is still high at relatively early gestational age, which would be associated with a
raised mca PI. Delayed development of the medullar venous system has been noted
in infants with malformations of cortical development (16), and it is conceivable that
this can be associated with a delayed development on the arterial side of the cerebral
circulation as well.
The relatively advanced gestational age at diagnosis is one of the limitations of this
study. The age at diagnosis did decrease somewhat during the course of the study,
which is probably related to the introduction of a structural ultrasound examination
at 20 gestational weeks for all pregnant women in the Netherlands.
During future prospective evaluation it would be useful to assess the value of other
indices such as the transsystolic time and maximum fl ow velocity in addition to the
pulsatility index of the middle cerebral artery, starting earlier in pregnancy. The use of
venous Doppler measurements, and the use of MRI, especially to assess the presence
or timing of hemorrhage or ischemia (17) and normality of oxygenation (18) should
also be assessed.
CONCLUSIONS
In fetuses with isolated abnormalities of the central nervous system (including fetuses
with aqueduct stenosis), the antenatal fi nding of increase in mca PI is associated with
a subsequently increased risk of demise or adverse neurodevelopmental outcome.
An increased mca PI which subsequently normalized was seen in fetuses that
subsequently were diagnosed with malformations of cortical development,
microcephaly and syndrome of West.
In fetuses with neural tube defects or multiple abnormalities, an increased mca PI was
not demonstrated with an increased risk of adverse neurodevelopmental outcome.
Future research should focus on elucidating mechanisms which could explain this
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fi nding, and on determining the clinical applicability of measurement of cerebral fl ow
in fetuses with aqueduct stenosis or other central nervous system abnormalities.
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REFERENCES
(1) Hanlo PW, Gooskens RH, Nijhuis IJ, Faber JA, Peters RJ, van Huffelen AC et al. Value of transcranial Doppler
indices in predicting raised ICP in infantile hydrocephalus. A study with review of the literature. Childs Nerv Syst
1995; 11(10):595-603.
(2) Kirkinen P, Muller R, Baumann H, Briner J, Lang W, Huch R et al. Cerebral blood fl ow velocity waveforms in
hydrocephalic fetuses. J Clin Ultrasound 1988; 16(7):493-498.
(3) Mai R, Rempen A, Kristen P. Color fl ow mapping of the middle cerebral artery in 23 hydrocephalic fetuses. Arch
Gynecol Obstet 1995; 256(3):155-158.
(4) Malinger G, Monteagudo A, Pilu G, Timor-Tritsch IE, Toi A. Sonographic examination of the fetal central nervous
system: guidelines for performing the ‚basic examination‘ and the ‚fetal neurosonogram‘. Ultrasound Obstet
Gynecol 2007; 29(1):109-116.
(5) Wladimiroff JW. Fetal cerebral blood fl ow. Clin Obstet Gynecol 1989; 32(4):710-718.
(6) Washburn LK, Dillard RG, Goldstein DJ, Klinepeter KL, deRegnier RA, O‘Shea TM. Survival and major
neurodevelopmental impairment in extremely low gestational age newborns born 1990-2000: a retrospective
cohort study. BMC Pediatr 2007; 7:20.
(7) Hill A, Volpe JJ. Decrease in pulsatile fl ow in the anterior cerebral arteries in infantile hydrocephalus. Pediatrics
1982; 69(1):4-7.
(8) Degani S, Lewinsky R, Shapiro I, Sharf M. Decrease in pulsatile fl ow in the internal carotid artery in fetal
hydrocephalus. Br J Obstet Gynaecol 1988; 95(2):138-141.
(9) Hanlo PW, Peters RJ, Gooskens RH, Heethaar RM, Keunen RW, van Huffelen AC et al. Monitoring intracranial
dynamics by transcranial Doppler--a new Doppler index: trans systolic time. Ultrasound Med Biol 1995;
21(5):613-621.
(10) Pooh RK, Pooh KH, Nakagawa Y, Maeda K, Fukui R, Aono T. Transvaginal Doppler assessment of fetal intracranial
venous fl ow. Obstet Gynecol 1999; 93(5 Pt 1):697-701.
(11) Zalel Y, Almog B, Seidman DS, Achiron R, Lidor A, Gamzu R. The resistance index in the fetal middle cerebral
artery by gestational age and ventricle size in a normal population. Obstet Gynecol 2002; 100(6):1203-1207.
(12) Levine D, Barnes PD, Robertson RR, Wong G, Mehta TS. Fast MR imaging of fetal central nervous system
abnormalities. Radiology 2003; 229(1):51-61.
(13) Achiron R, Pinchas OH, Reichman B, Heyman Z, Schimmel M, Eidelman A et al. Fetal intracranial haemorrhage:
clinical signifi cance of in utero ultrasonographic diagnosis. Br J Obstet Gynaecol 1993; 100(11):995-999.
(14) Hadi HA, Finley J, Mallette JQ, Strickland D. Prenatal diagnosis of cerebellar hemorrhage: medicolegal
implications. Am J Obstet Gynecol 1994; 170(5 Pt 1):1392-1395.
(15) Booss J, Dann PR, Winkler SR, Griffi th BP, Kim JH. Mechanisms of injury to the central nervous system following
experimental cytomegalovirus infection. Am J Otolaryngol 1990; 11(5):313-317.
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(16) Pooh RK, Pooh KH. Medullary venous system of fetal brain; high-frequency transvaginal bidirectional power
Doppler study. Ultrasound Obstet Gynecol 2007; 30(4):416.
(17) Brugger PC, Stuhr F, Lindner C, Prayer D. Methods of fetal MR: beyond T2-weighted imaging. Eur J Radiol 2006;
57(2):172-181.
(18) Levine D. Science to practice: can MR oxygenation imaging be used to assess at-risk pregnancies? Radiology
2006; 238(3):765-766.
Chapter 9DISTURBANCE OF CEREBRAL MIGRATION
FOLLOWING CONGENITAL PARVOVIRUS
B19 INFECTION
L.R. Pistorius1, J. Smal2, T.R. de Haan3, G.C.M.L. Page-Christiaens1, M. Verboon-Maciolek2, D. Oepkes4, L.S. de Vries2
1Department of Obstetrics, University Medical Center, Utrecht, The Netherlands, 2Department of Neonatology, University Medical Center Utrecht, The Netherlands
3Department of Neonatology, Academic Medical Center, Amsterdam, The Netherlands4Department of Obstetrics, Leiden University Medical Center, Leiden, The Netherlands
Fetal Diagn Ther 2008 (in press)
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ABSTRACT
Objective
We describe the clinical course of an infant who presented with severe fetal anemia and
fetal hydrops following congenital Parvovirus B19 infection before sixteen gestational
weeks. The fetus was treated by cordocentesis and intra-uterine transfusion at
eighteen weeks.
Results
The infant demonstrated mild unilateral ventriculomegaly on antenatal magnetic
resonance imaging, and polymicrogyria and heterotopia on postnatal magnetic
resonance imaging.
Conclusion
This adds to the evidence in recent literature of central nervous system damage
associated with congenital Parvovirus B19 infection.
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INTRODUCTION
Intra-uterine infection with Parvovirus B19 can cause severe fetal anemia, fetal hydrops
and intrauterine fetal death. The anemia is secondary to a transient aplastic crisis (1)
and can be effectively treated by intra-uterine transfusion. More than 80% of hydropic
infants survive after intra-uterine transfusion (2-5), whereas untreated fetal hydrops
may lead to fetal death in 30 – 50% (2;3;5;6) of cases or a maternal pre-eclampsia-like
or “mirror syndrome” (7).
Previous studies reported a normal neurodevelopmental prognosis following intra-
uterine Parvovirus B19 infection (8). More recently, mild to severe neurodevelopmental
delay was reported in fi ve out of sixteen Parvovirus B19 hydrops survivors (9).
We describe the course of an infant who developed intrauterine hydrops and severe
anemia due to Parvovirus B19 infection and in whom malformations of cortical
development were seen on cerebral MRI.
CASE REPORT
A genetic amniocentesis was performed for advanced maternal age at a gestational
age of 16 weeks in a 38-year-old G3P2 Caucasian female in the University Medical
Centre Utrecht (UMCU). At that time the patient mentioned to have had a Parvovirus
B19 contact within the family a couple of weeks before. The presence of parvovirus B19
specifi c IgM antibodies suggested recent infection. A Parvovirus B19 PCR performed on
an amniotic fl uid sample proved positive. The infant had a normal female karyotype.
The pregnancy was followed up with weekly ultrasound examinations for hydrops
and middle cerebral artery peak systolic velocity (MCA PSV) measurements were
performed to detect fetal anemia (10). At a gestational age of 17 weeks, the MCA PSV
of the middle cerebral artery was 32cm/s, equivalent to 1.4 multiples of the median
(MoM). Seven days later, fetal ascites was visible on ultrasound, and the MCA PSV
of the middle cerebral artery was 55cm/s, equivalent to 2.3 MoM. Because of the
high probability of fetal anemia, she was referred to the Leiden University Medical
Centre (LUMC) for a diagnostic cordocentesis and intra-uterine transfusion. This
was performed the next day, at a gestational age of eighteen weeks. Cordocentesis
demonstrated a fetal hemoglobin level of 1.4 g/dL (0.9 mmol/L) with a hematocrit of
5%. The platelet count was 39x109/L. Intrauterine erythrocyte and platelet transfusions
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were given intravenously. The post-transfusion fetal hemoglobin levels were 12.3 g/dL
(7.5 mmol/L), the hematocrit 35%, and the platelet count 122 x109/L. Fetal Parvovirus
B19 infection was confi rmed by detection of viral DNA in fetal blood, with a viral
load of log 8.6 (4.0 x 108) copies/mL. The ascites resolved within two weeks after the
transfusion. The MCA PSV remained normal for the duration of the pregnancy. At 22
weeks, ultrasound examination did not demonstrate any intracranial abnormalities,
but an antenatal MRI examination demonstrated mild unilateral dilatation of the
frontal and occipital horn of the left lateral ventricle (Figure 1) with the ventriclular
atrium measuring 10mm (11).
Figure 1. Prenatal MRI at 22 weeks of gestational age demonstrating mild unilateral dilatation of the occipital and frontal horn of the left lateral ventricle (arrows)
A female infant was delivered vaginally after an induction of labor at a gestational age
of 41 weeks. The Apgar scores were 8 and 10 at 1 and 5 minutes respectively and the
physical examination was normal. The birth weight was 3475g (P50). The hemoglobin
level was 20.5g/dL (12.4mmol/L), the hematocrit 63% and the platelet count 190x109/L.
The liver function tests were normal. The Parvovirus B19 DNA load in blood was
negative. Parvovirus B19 specifi c IgG antibodies were detected in serum of the infant
whereas parvovirus B19 specifi c IgM antibodies were negative. Postnatal cranial
ultrasound demonstrated a slight enlargement of the anterior horn of the left lateral
ventricle, and MRI examination demonstrated a mildly enlarged left frontal horn and
marked ipsilateral frontal polymicrogyria and heterotopia. There was loss of volume of
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the left posterior region without evidence of polymicrogyria (Figure 2) .
At the age of twelve months the child showed a normal early development, with
growth and head circumference on the 50th centile.
Figure 2. Postnatal MRI demonstrating mildly enlarged left frontal horn (white line arrow), marked ipsilateral frontal polymicrogyria (solid arrow) and heterotopia (black line arrow) and loss of volume of the left posterior region
DISCUSSION
We describe the outcome of an infant who recovered from non-immune fetal hydrops
due to intrauterine parvovirus B19 infection after an intrauterine transfusion (IUT)
for severe fetal anemia and thrombocytopenia. Neonatal imaging demonstrated
cerebral migratory abnormalities, namely cortical heterotopia and polymicrogyria.
Cortical heterotopia are clusters of neurons in an abnormal position as the result of
arrested migration of neurons which normally occurs from the germinal matrix in the
lateral ventricular walls towards the cortex, and is seen as an abnormally situated T2
hypointese area on MRI. Polymicrogyria is seen as an area of cortex with abnormally
small convolutions (11). Cerebral migratory abnormalities can be associated with
multiple congenital abnormalities, mental retardation syndromes and epilepsy. It has
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been described in association with ischaemia, Cytomegaloviral (CMV) infection and
complications of monochorionic twin pregnancies occuring before 20 gestational
weeks (12).
The primary target of parvovirus B19 infection is the erythroid cell line but
thrombocytopenia is also often observed in infected patients. Furthermore an
association has been reported between human parvovirus B19 infection and
encephalitis or even fetal stroke (13-17). Myocarditis due to human parvovirus B19 has
been described in the human fetus, infants, older children and even adults (18;19).
Until recently, the available published literature of infants treated with IUT for
anemia related to maternal parvovirus B19 infection was reassuring with regards to
neurodevelopmental outcome. Four publications on a total of 24 survivors of IUT for
parvovirus B19 infection reported a normal neurodevelopmental outcome (6;8;20;21).
However, the upper 95% confi dence limit of absence of neurological abnormalities in
a series of 24 is 3/24 = 12.5% (22) and indeed, rare cases of fetal neurological injury
associated with maternal parvovirus B19 infection have been reported. These include
hydrocephalus (16), cortical dysplasia (16), perivascular white matter calcifi cations
(15), fetal stroke (13;14), cerebellar haemorrhage (29) and encephalitis (17). A very
recent report mentioned for the fi rst time neurodevelopmental delay in fi ve out of
sixteen survivors of IUT for Parvovirus B19 induced fetal anemia. Two of these had
severe neurodevelopmental delay. MRI was not performed in any of these children (9).
The infant in our report is still young, and although she is doing well at twelve months,
she is still at risk of later development of epilepsy in view of the cortical dysplasia (24).
It is diffi cult to quantify the risk of adverse neurorological outcome, as most cases of
cortical dysplasia are found in children where brain imaging is performed because of
intractable epilepsy. The outcome does tend to correlate with the location and extent
of the lesions, and possibly with the underlying cause. Most cases of severe epilepsy
tend to start early, and 38% of mild epilepsy also starts before the age of twelve
months (25).
Although the infant presented with a very low hemoglobin level at the time of
intra-uterine transfusion, no relation between the minimum fetal hemoglobin and
subsequent neurodevelopmental status has been demonstrated so far (8;9). This
might refl ect absence of evidence rather than evidence of absence of an effect, as
the number of reported cases is still only a handful. Detailed follow up of transfused
children is paramount to answer this question.
Can we learn something from other intrauterine viral infections? Congenital
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cytomegalovirus infections in the early second trimester can be associated with
cerebral abnormalities such as polymicrogyria in the absence of extreme fetal anemia.
This supports the hypothesis that viral infections as such may have negative effects
on fetal neuronal migration (26-29). The pathogenesis might be related to a disturbed
blood supply during a crucial time of cerebral development (28), through direct
cytotoxic effects of viral infection (15) or by a chronic hypoxic state caused by fetal
vasculitis, severe anemia or myocarditis (30). Parvovirus B19 genome DNA has been
detected in the nuclei of multinucleated giant cells in the white matter of a fetal brain
at post-mortem investigation subsequent to second trimester Parvovirus B19 infection
(15). Neuronal migration has also been shown to be delayed by intermittent or chronic
hypoxic episodes in the infant (30). The previous case of cortical dysplasia associated
with intrauterine Parvovirus B19 infection was also unconfi rmed by histology or PCR
evidence of viral DNA (16) Whether the injury in our patient was caused by a direct
viral effect, by hemodynamic changes caused by fetal myocarditis or anemia, by
the maternal immune response, or by complications of the cordocentesis, remains
uncertain.
If a patient is scheduled for an intrauterine transfusion for Parvovirus B19 induced
fetal anemia, she should be counseled on the risk of a possible association with
neurodevelopmental delay due to the congenital Parvovirus B19 infection despite
successful treatment of fetal anemia and regardless of the severity of the anemia (9).
We therefore propose routine postnatal brain imaging with ultrasound and MRI as
well as subsequent neurodevelopmental follow-up (15) in survivors of parvovirus B19-
associated hydrops, similar to the recommendation in preterm infants (24) and infants
exposed to cytomegalovirus in utero (31;32). This proposal stands regardless of the
initial fetal hemoglobin levels or subsequent duration of hydrops.
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REFERENCES
(1) Anderson MJ, Higgins PG, Davis LR, Willman JS, Jones SE, Kidd IM et al. Experimental parvoviral infection in
humans. J Infect Dis 1985; 152(2):257-265.
(2) Enders M, Weidner A, Zoellner I, Searle K, Enders G. Fetal morbidity and mortality after acute human parvovirus
B19 infection in pregnancy: prospective evaluation of 1018 cases. Prenat Diagn 2004; 24(7):513-518.
(3) Fairley CK, Smoleniec JS, Caul OE, Miller E. Observational study of effect of intrauterine transfusions on outcome
of fetal hydrops after parvovirus B19 infection. Lancet 1995; 346(8986):1335-1337.
(4) Rodis JF, Borgida AF, Wilson M, Egan JF, Leo MV, Odibo AO et al. Management of parvovirus infection in pregnancy
and outcomes of hydrops: a survey of members of the Society of Perinatal Obstetricians. Am J Obstet Gynecol
1998; 179(4):985-988.
(5) Schild RL, Bald R, Plath H, Eis-Hubinger AM, Enders G, Hansmann M. Intrauterine management of fetal parvovirus
B19 infection. Ultrasound Obstet Gynecol 1999; 13(3):161-166.
(6) Rodis JF, Rodner C, Hansen AA, Borgida AF, Deoliveira I, Shulman RS. Long-term outcome of children following
maternal human parvovirus B19 infection. Obstet Gynecol 1998; 91(1):125-128.
(7) de Jong EP, de Haan TR, Kroes AC, Beersma MF, Oepkes D, Walther FJ. Parvovirus B19 infection in pregnancy. J Clin
Virol 2006; 36(1):1-7.
(8) Dembinski J, Haverkamp F, Maara H, Hansmann M, Eis-Hubinger AM, Bartmann P. Neurodevelopmental outcome
after intrauterine red cell transfusion for parvovirus B19-induced fetal hydrops. BJOG 2002; 109(11):1232-
1234.
(9) Nagel HT, de Haan TR, Vandenbussche FP, Oepkes D, Walther FJ. Long-term outcome after fetal transfusion for
hydrops associated with parvovirus B19 infection. Obstet Gynecol 2007; 109(1):42-47.
(10) Mari G, Deter RL, Carpenter RL, Rahman F, Zimmerman R, Moise KJ, Jr. et al. Noninvasive diagnosis by Doppler
ultrasonography of fetal anemia due to maternal red-cell alloimmunization. Collaborative Group for Doppler
Assessment of the Blood Velocity in Anemic Fetuses. N Engl J Med 2000; 342(1):9-14.
(11) Garel C. MRI of the fetal brain. Berlin: Springer, 2004.
(12) Barkovich AJ, Kuzniecky RI, Jackson GD, Guerrini R, Dobyns WB. A developmental and genetic classifi cation for
malformations of cortical development. Neurology 2005; 65(12):1873-1887.
(13) Craze JL, Salisbury AJ, Pike MG. Prenatal stroke associated with maternal parvovirus infection. Dev Med Child
Neurol 1996; 38(1):84-85.
(14) de Haan TR, Wezel-Meijler G, Beersma MF, Von Lindern JS, Van Duinen SG, Walther FJ. Fetal stroke and congenital
parvovirus B19 infection complicated by activated protein C resistance. Acta Paediatr 2006; 95(7):863-867.
(15) Isumi H, Nunoue T, Nishida A, Takashima S. Fetal brain infection with human parvovirus B19. Pediatr Neurol
1999; 21(3):661-663.
(16) Katz VL, McCoy MC, Kuller JA, Hansen WF. An association between fetal parvovirus B19 infection and fetal
anomalies: a report of two cases. Am J Perinatol 1996; 13(1):43-45.
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(17) Kerr JR, Barah F, Chiswick ML, McDonnell GV, Smith J, Chapman MD et al. Evidence for the role of demyelination,
HLA-DR alleles, and cytokines in the pathogenesis of parvovirus B19 meningoencephalitis and its sequelae. J
Neurol Neurosurg Psychiatry 2002; 73(6):739-746.
(18) Ergaz Z, Ornoy A. Parvovirus B19 in pregnancy. Reprod Toxicol 2006; 21(4):421-435.
(19) O’Malley A, Barry-Kinsella C, Hughes C, Kelehan P, Devaney D, Mooney E et al. Parvovirus infects cardiac myocytes
in hydrops fetalis. Pediatr Dev Pathol 2003; 6(5):414-420.
(20) Cameron AD, Swain S, Patrick WJ. Human parvovirus B19 infection associated with hydrops fetalis. Aust N Z J
Obstet Gynaecol 1997; 37(3):316-319.
(21) Miller E, Fairley CK, Cohen BJ, Seng C. Immediate and long term outcome of human parvovirus B19 infection in
pregnancy. Br J Obstet Gynaecol 1998; 105(2):174-178.
(22) Hanley JA, Lippman-Hand A. If nothing goes wrong, is everything all right? Interpreting zero numerators. JAMA
1983; 249(13):1743-1745.
(23) Glenn OA, Bianco K, Barkovich AJ, Callen PW, Parer JT. Fetal cerebellar hemorrhage in parvovirus-associated non-
immune hydrops fetalis. J Matern Fetal Neonatal Med 2007; 20(10):769-772.
(24) Rademaker KJ, Uiterwaal CS, Beek FJ, van Haastert IC, Lieftink AF, Groenendaal F et al. Neonatal cranial
ultrasound versus MRI and neurodevelopmental outcome at school age in children born preterm. Arch Dis Child
Fetal Neonatal Ed 2005; 90(6):F489-F493.
(25) Whiting S, Duchowny M. Clinical spectrum of cortical dysplasia in childhood: diagnosis and treatment issues. J
Child Neurol 1999; 14(12):759-771.
(26) Hayward JC, Titelbaum DS, Clancy RR, Zimmerman RA. Lissencephaly-pachygyria associated with congenital
cytomegalovirus infection. J Child Neurol 1991; 6(2):109-114.
(27) Iannetti P, Nigro G, Spalice A, Faiella A, Boncinelli E. Cytomegalovirus infection and schizencephaly: case reports.
Ann Neurol 1998; 43(1):123-127.
(28) Marques Dias MJ, Harmant-van Rijckevorsel G, Landrieu P, Lyon G. Prenatal cytomegalovirus disease and
cerebral microgyria: evidence for perfusion failure, not disturbance of histogenesis, as the major cause of fetal
cytomegalovirus encephalopathy. Neuropediatrics 1984; 15(1):18-24.
(29) Soussotte C, Maugey-Laulom B, Carles D, Diard F. Contribution of transvaginal ultrasonography and fetal
cerebral MRI in a case of congenital cytomegalovirus infection. Fetal Diagn Ther 2000; 15(4):219-223.
(30) Rees S, Stringer M, Just Y, Hooper SB, Harding R. The vulnerability of the fetal sheep brain to hypoxemia at mid-
gestation. Brain Res Dev Brain Res 1997; 103(2):103-118.
(31) de Vries LS, Gunardi H, Barth PG, Bok LA, Verboon-Maciolek MA, Groenendaal F. The spectrum of cranial ultrasound
and magnetic resonance imaging abnormalities in congenital cytomegalovirus infection. Neuropediatrics 2004;
35(2):113-119.
(32) Barkovich AJ, Lindan CE. Congenital cytomegalovirus infection of the brain: imaging analysis and embryologic
considerations. AJNR Am J Neuroradiol 1994; 15(4):703-715.
Chapter 10FETAL CENTRAL NERVOUS SYSTEM
ABNORMALITIES: ULTRASOUND, MRI OR
MULTIDISCIPLINARY DISCUSSIONS?
L.R. Pistorius1, R.H.J.M. Gooskens2, F. Groenendaal3, L.S. de Vries3, Ph. Stoutenbeek1, G.H.A. Visser1
1Department Obstetrics, Division of Perinatology and Gynecology, University Medical Centre Utrecht, The Netherlands
2Department of Neurology and Neurosurgery, Rudolf Magnus Institute of Neuroscience, Utrecht3Department Neonatology, Division Perinatology and Gynaecology, University Medical Centre Utrecht,
Utrecht, The Netherlands
Submitted
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ABSTRACT
Introduction
There are many articles comparing the ability of ultrasound and MRI to diagnose fetal
central nervous system (CNS) abnormalities. The quality of ultrasound and MRI and
a multidisciplinary discussion might all improve the diagnostic accuracy. We decided
to evaluate our own experience with the diagnostic accuracy of ultrasound, MRI and
multidisciplinary discussions of fetuses with CNS lesions.
Methods
A retrospective cohort of patients referred for MRI of the fetal CNS from 2000 to 2008
was evaluated for the diagnostic accuracy of ultrasound, MRI, and multidisciplinary
discussions before and after MRI as compared to the fi nal postnatal diagnosis. The
primary endpoint was the change in accuracy of the multidisciplinary discussion before
and after the MRI. We also evaluated the accuracy of basic ultrasound examinations
and neurosonograms separately.
Results
Forty six patients were referred for MRI. A postnatal diagnosis could be made in 38,
of whom 28 were discussed in a multidisciplinary team before and after MRI. The
diagnosis made during the multidisciplinary discussion was accurate in 62% (95%CI 22-
77%) before, and 73% (57-85%) of patients after MRI (p=0.17). The diagnosis remained
unchanged in 23/28 patients, changed from inaccurate to accurate in 4, and from
accurate to inaccurate in 1 patient. Basic ultrasounds were accurate in 42% (23-64%)
of patients, and neurosonograms in 63% (41-81%) of patients (p=0.097).
Conclusions
In this cohort, the highest accuracy of prenatal diagnosis of fetal CNS lesions was
obtained with a multidisciplinary discussion after neurosonography and MRI.
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INTRODUCTION
Prenatal ultrasound examination is widely used to screen for fetal abnormalities.
When a suspicion of a fetal abnormality arises, ultrasound, MRI, or both, can be used
as the main imaging modality to arrive at a fi nal diagnosis. At the same time, the value
of a thorough history and additional tests such as infectious serology, karyotyping and
tests for coagulopathy should not be forgotten.
Although there are many articles comparing the diagnostic capabilities of US and MRI,
many are hampered by an obvious bias by comparing a diagnosis made in primary
care on US with a tertiary diagnosis by MRI, with only few trying to compare like
with like (1;2). It is also diffi cult to distinguish between the effect of MRI and that of
a multidisciplinary discussion (3). The latter has also been shown to be important in
improving the accuracy of diagnosis of fetal central nervous system abnormalities (4).
We have previously found MRI to be of additional value in the diagnosis of fetal central
nervous system (CNS) abnormalities where ultrasound examination yielded uncertain
or limited results (5). We therefore decided to analyze our subsequent results to
compare the accuracy of ultrasound, MRI and the additional value of a multidisciplinary
discussion with the postnatal diagnosis.
METHODS
All patients with an ultrasound diagnosis or suspicion of a fetal CNS abnormality and who
were referred for antenatal MRI from 2000-2008, were included in this retrospective
cohort from the University Medical Centre Utrecht, one of the ten tertiary perinatal
centres in the Netherlands. The type of ultrasound was noted as a “basic examination”
if only axial views or mainly axial and limited coronal and sagittal views were recorded,
or as a “neurosonogram” when multiple axial, sagittal and coronal views had been
recorded (6). High resolution equipment was used, such as the Toshiba Aplio or Aplio
XG (Toshiba Medical, Tokyo, Japan) or the General Electric Voluson 730 Expert (General
Electric Healthcare, London, United Kingdom) with as a high resolution as possible;
typically 4-8MHz transabdominally or 5-9MHz transvaginally. The fi nal diagnosis (of
the central nervous and other systems) by the maternal and fetal medicine specialist
who performed the last ultrasound examination prior to MRI was noted, as was the
diagnosis made on MRI by the attending radiologist who was aware of the ultrasound
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fi ndings. MRI was performed on a 1,5T Philips system (Philips Medical Systems,
Best, Netherlands) with T2-weighted, T1-weighted and diffusion-weighted imaging
protocols (7), usually after oral sedation with 10mg diazepam 3 hours prior to the
examination. The settings were adjusted to the gestational age. The T2-weighted
sequence was a single shot turbo-spin echo (SSH-TSE) with fi eld of view (FOV) 170-
300mm, slice thickness 4mm, gap 0-0.4mm, matrix 169-256x256, repetition time (TR)
shortest, echo time (TE) 140-250ms, fl ip angle 90º, 18-25 slices and scan time 15-25
seconds. For the T1-weighted sequence we used two-dimensional gradient echo (2D-
GRE) with FOV 300 – 325 mm, slice thickness 5mm and gap 0.5mm, matrix 166 x 256,
shortest TR, TE 3.8-4.6ms, fl ip angle 21-80º, 14-15 slices and scan time 14-15 seconds,
and for the DWI a FOV 240mm, slice thickness 5mm and gap 0.1mm, matrix 108 x 256,
TR 1,470, TE 125ms, fl ip angle 90º, 16 slices and scan time 19 seconds (5;8;9).
The diagnoses made during a multidisciplinary discussion prior and subsequent to the
MRI were also recorded. The multidisciplinary discussions were regularly attended
by members of the following specialities: maternal and fetal medicine, neonatology,
pediatric neurology, clinical genetics, pathology and pediatric cardiology. The MRI
images were reviewed by a neonatologist / paediatric neurologist (LdV, FG or RG) prior
to the multidisciplinary discussion. The fi nal diagnosis made postnatally by neuro-
imaging or autopsy was used as the gold standard, and the accuracy (true positives
& true negatives divided by the total) was compared with the chi square test. The
diagnoses were classifi ed according to a postnatal neuro-imaging classifi cation of
congenital abnormalities of the CNS (10). The primary outcome measure was the
difference in accuracy of the multidisciplinary meetings’ diagnoses before and after
the MRI examination. Other outcome measures were the difference in accuracy of
basic ultrasound examinations and neurosonograms and the difference in accuracy
between ultrasound and MRI examinations.
Data management and statistical analysis were performed with SPSS version 15.0 for
Windows (SPSS Inc. Chicago, Illinois). Descriptive data are given as mean (standard
deviation) if normally distributed and as median (range) if not normally distributed.
95% confi dence intervals for proportions were calculated with the modifi ed Wald
method (11).
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Table 1. Accuracy of ultrasound, multidisciplinary and MRI diagnoses Table 1.1 According to ultrasound diagnosis
Ultrasound diagnosis
Ultrasound Multidisciplinary before
MRI Multidisciplinary after
n* % n % n % n %
Neural tube defects
4/4 100 4/4 100 4/4 100 4/4 100
Posterior fossa lesions
2/2 100 2/2 100 1/2 50 2/2 100
Ventriculo-megaly
4/14 29 3/10 30 4/13 31 7/13 54
Corpus callosum agenesis
3/4 75 2/2 100 3/4 75 3/4 75
1/1 100 1/1 100 1/1 100 1/1 100
Cysts and tumors
2/4 50 3/3 100 3/4 75 4/4 100
Acquired lesions
0/1 0 1/1 100 1/1 100
Other lesions 3/4 73 2/3 67 2/4 50 6/6 100
Normal fi ndings
1/4 25 1/4 25 1/4 25 1/5 20
Table 1.2 According to fi nal diagnosis
Final diagnosis
Ultrasound Multidisciplinary before
MRI Multidisciplinary after
n % n % n % n %
Neural tube defects
4/4 100 4/4 100 4/4 100 4/4 100
Posterior fossa lesions
2/2 100 2/2 100 1/2 50 2/2 100
Aqueduct stenosis
4/4 100 2/2 100 1/3 33 3/3 100
Corpus callosum agenesis
3/5 60 2/2 100 5/5 100 5/5 100
2/9 22 3/9 33 2/9 22 4/9 44
Cysts and tumors
2/2 100 2/2 100 2/2 100 2/2 100
Acquired lesions
0/3 0 0/1 0 0/3 0 0/3 0
Other lesions 2/4 50 2/4 50 2/4 50 2/4 50
Normal fi ndings
1/5 20 1/3 33 3/5 60 5/5 100
*correct diagnoses / total
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RESULTS
Forty six patients were referred for MRI because of an ultrasound diagnosis or suspicion
of a fetal CNS abnormality during the study period. From 2000 to 2005, the majority of
ultrasound examinations (20/26, or 71%) were basic examinations. From 2006 onwards,
the majority of ultrasound examinations (15/20, or 75%) were neurosonograms. The
median gestational age of the last ultrasound examination before MRI was 31 weeks
(range 20 – 38 weeks) and the median gestational age at MRI was 32 weeks (21 – 38
weeks). The median interval between the ultrasound and MRI examinations was 5 days
(range 0 – 30 days). The MRI examination failed in one patient due to claustrophobia.
In eight patients, a fi nal CNS diagnosis could not be established because no postnatal
imaging or autopsy was performed, or because severe maceration made an accurate
diagnosis impossible. The accuracy of the ultrasound, multidisciplinary meeting before
and after MRI and MRI diagnoses are given in Table 1 according to the main diagnostic
groups.
Table 2. Accuracy of antenatal diagnosis according to type of ultrasound examinationTable 2.1 Basic ultrasound
Ultrasound Multidisciplinary before
MRI Multidisciplinary after
n % n % n % n %
true diagnosis 8 42 7 54 11 58 13 68
false negative 2 11 2 15 2 11 2 11
false positive 1 5 0 0 0 0 0 0
different diagnosis 8 42 4 31 6 32 4 21
total 19 100 13 100 19 100 19 68
Table 2.2 Neurosonogram
Ultrasound Multidisciplinary before
MRI Multidisciplinary after
n % n % n % n %
true diagnosis 12 63 11 69 9 50 14 78
false negative 1 5 1 6 1 6 1 6
false positive 3 16 2 13 2 11 0 0
different diagnosis 3 16 2 13 6 33 3 17
total 19 100 16 100 18 100 18 100
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f
The accuracy of the multidisciplinary meetings before the MRI examinations was
62% (95% confi dence intervals 44-77%) and after the MRI examinations 73% (57-85%)
(Single tailed chi square p=0.17) A multidisciplinary meeting was held before and after
MRI in 28 patients. In 23 (82%) the diagnosis remained unchanged, in 1 (4%) a correct
diagnosis was changed to an incorrect diagnosis after MRI, and in 4 (16%) an incorrect
diagnosis was changed to a correct diagnosis after MRI.
The accuracy of diagnoses according to the type of ultrasound is shown in Table 2. The
lowest accuracy of 42% (23-64%) was seen with basic ultrasound examination and the
highest accuracy of 78% (54-92%) was seen with multidisciplinary meetings after a
neurosonogram (p=0.01). If the patients with neural tube defects where all diagnoses
were 100% accurate are excluded, the accuracy of 61% (39-80%) of neurosonograms
was signifi cantly higher than the accuracy of 31% (14-56%) of basic ultrasound
examinations (p=0.04, single-tailed chi square test).
DISCUSSION
Although the absolute numbers are small, some defi nite trends emerge from this
analysis. Firstly, the spectrum of disorders refl ects the fact that we used MRI in cases
where it would be likely to add to the diagnostic value, rather than as a routine in
patients with (suspicion of) fetal CNS abnormalities on ultrasound. Secondly,
MRI might add to the diagnostic accuracy as can be seen by the (not statistically
signifi cantly) higher accuracy of the diagnoses of the multidisciplinary discussion
after MRI compared to before the MRI. An MRI examination can to some extent
compensate for an insuffi cient ultrasound examination. However, the accuracy of the
specifi c MRI diagnosis as made by the attending radiologist was hardly or no better
than the accuracy of the ultrasound as made by the attending maternal fetal medicine
specialist. The real improvement in diagnostic accuracy was made by discussing the
patient in a multidisciplinary setting. This has been suggested previously (3) and has
also been demonstrated in a study where a panel retrospectively reviewed the image
material and case management of fetuses where ultrasound and brain MRI had been
done (12). Finally, the greatest improvement was achieved by performing a full fetal
neurosonogram, which entails transvaginal ultrasonography if the fetus is in a cephalic
presentation, and manipulating the fetus to visualize the intracranial content in axial,
coronal and sagittal planes (6).
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Many studies have found that MRI changed the diagnosis by ultrasound for the better
in 27-29% of fetuses (14-17). If we compare ultrasound and MRI, we would have
changed the diagnosis for the better in 13% of patients, and for the worse in 11% of
patients. The diagnosis of the multidisciplinary meeting improved from 62% before to
73% after the MRI.
Most of this improvement can probably be ascribed to the MRI, although the
ultrasound was often repeated at the same time. It is possible that the execution and
interpretation of MRI in our study were not as good as in the other studies, but it is
also possible that the shorter interval between ultrasound and MRI in our study, and
the fact that we did not compare referral diagnoses with MRI diagnoses led to these
results. Similar results have been reported in other studies where the initial ultrasound
examination had been more detailed (2;18).
We found little additional value in MRI of fetuses with neural tube defects. Most
infants with corpus callosum agenesis were detected by ultrasound, even though the
examinations had been mostly basic, but with indirect signs such as colpocephaly and
an absent cavum septum pellucidum easily visible. With fetal neurosonography it is
even easier to detect corpus callosum agenesis or hypoplasia, as the corpus callosum
and pericallosal vessels can be visualized easily, either directly, or with the aid of three
dimensional ultrasound (19).
Patients with malformations of cortical development mostly presented with
ventriculomegaly. The fi nal diagnosis was made correctly at the fi nal multidisciplinary
discussion in four of the eight patients: two with schizencephaly, both of whom were
correctly diagnosed on MRI and one of whom was correctly diagnosed on ultrasound,
and two with delayed cortical maturation, which was identifi ed in both on ultrasound
and in neither on MRI on the initial evaluation, although it was confi rmed on
revision of the MRI images. Additional pointers to possible malformations of cortical
development which mostly did not lead to the correct diagnosis in our cases were
associated cerebellar or callosal abnormalities (28).
Although MRI has been found superior to ultrasound in the diagnosis of posterior fossa
lesions in many studies (15;17;21-24), we found ultrasound to be equally accurate in
the diagnosis of posterior fossa lesions, whether vermian abnormalities or cysts.
Several of the false positive diagnoses in our study might in fact have been due to
transient fi ndings, such as mild ventriculomegaly or asymmetrical ventriculomegaly
due to intraventricular haemorrhage. The development of the fetal brain remains
a dynamic process, and this could also explain “false negative”diagnoses such as
malformations of cortical development not yet visible at 22 weeks, or peripartum
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intracranial haemorrhage which was not present at the time of antenatal imaging.
A change in diagnosis leading to a change in policy has been described in as much as
46% of patients (1;15;17;25;26). We did not evaluate the effect of the MRI on the change
of policy, as policy decisions were usually deferred until all results were available.
So what do our data add to the literature? Obviously our small numbers cannot compete
with the excellent work by experts in the fi eld (1;17;23;27;28). reporting series of even
more than 3000 MRI’s (29). On the other hand, that is precisely the point: although
excellent diagnostic accuracy can be obtained with fetal MRI, both obtaining and
interpreting MRI images are operator dependent (8). There are conditions where the
different physical properties of image generation of MRI can lead to greater accuracy,
such as the early detection of ischemia (8) or estimating the age of a haemorrhage (30).
In units with excellent MRI service and evaluation, the MRI diagnosis is also likely to be
superior to the ultrasound diagnosis (1). On the other hand, if a fetal central nervous
system abnormality is found or suspected on ultrasound, in our setting we would
expect greater gain from performing a neurosonogram and discussing the patient in a
multidisciplinary setting, rather than referring the patient for MRI.
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abnormalities. Radiology 2003; 229(1):51-61.
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magnetic resonance imaging and dedicated neurosonography. Ultrasound Obstet Gynecol 2004; 23(4):333-
340.
(3) Malinger G, Lev D, Lerman-Sagie T. Is fetal magnetic resonance imaging superior to neurosonography for
detection of brain anomalies? Ultrasound Obstet Gynecol 2002; 20(4):317-321.
(4) Hagmann CF, Robertson NJ, Leung WC, Chong KW, Chitty LS. Foetal brain imaging: ultrasound or MRI. A
comparison between magnetic resonance imaging and a dedicated multidisciplinary neurosonographic opinion.
Acta Paediatr 2008; 97(4):414-419.
(5) Gerards FA, Stoutenbeek P, Gooskens RH, Beek FJ, Groenendaal F. [Diagnostic value of prenatal MRI in fetus with
intracranial anomalies diagnosed by ultrasonography]. Ned Tijdschr Geneeskd 2001; 145(4):179-184.
(6) Malinger G, Monteagudo A, Pilu G, Timor-Tritsch IE, Toi A. Sonographic examination of the fetal central nervous
system: guidelines for performing the ‘basic examination’ and the ‘fetal neurosonogram’. Ultrasound Obstet
Gynecol 2007; 29(1):109-116.
(7) Prayer D, Brugger PC, Prayer L. Fetal MRI: techniques and protocols. Pediatr Radiol 2004; 34(9):685-693.
(8) Brugger PC, Stuhr F, Lindner C, Prayer D. Methods of fetal MR: beyond T2-weighted imaging. Eur J Radiol 2006;
57(2):172-181.
(9) Prayer D, Brugger PC, Prayer L. Fetal MRI: techniques and protocols. Pediatr Radiol 2004; 34(9):685-693.
(10) van der Knaap MS, Valk J. Classifi cation of congenital abnormalities of the CNS. AJNR Am J Neuroradiol 1988;
9(2):315-326.
(11) Agresti A, Coull BA. Approximate is better than “Exact” for interval estimation of binomial proportions. American
Statistician 1998; 52:119-126.
(12) Hagmann CF, Robertson NJ, Leung WC, Chong KW, Chitty LS. Foetal brain imaging: ultrasound or MRI. A
comparison between magnetic resonance imaging and a dedicated multidisciplinary neurosonographic opinion.
Acta Paediatr 2008; 97(4):414-419.
(13) Hagmann CF, Robertson NJ, Leung WC, Chong KW, Chitty LS. Foetal brain imaging: ultrasound or MRI. A
comparison between magnetic resonance imaging and a dedicated multidisciplinary neurosonographic opinion.
Acta Paediatr 2008; 97(4):414-419.
(14) Ismail KM, Ashworth JR, Martin WL, Chapman S, McHugo J, Whittle MJ et al. Fetal magnetic resonance imaging
in prenatal diagnosis of central nervous system abnormalities: 3-year experience. J Matern Fetal Neonatal Med
2002; 12(3):185-190.
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(15) Twickler DM, Magee KP, Caire J, Zaretsky M, Fleckenstein JL, Ramus RM. Second-opinion magnetic resonance
imaging for suspected fetal central nervous system abnormalities. Am J Obstet Gynecol 2003; 188(2):492-496.
(16) Wang GB, Shan RQ, Ma YX, Shi H, Chen LG, Liu W et al. Fetal central nervous system anomalies: comparison of
magnetic resonance imaging and ultrasonography for diagnosis. Chin Med J (Engl ) 2006; 119(15):1272-1277.
(17) Whitby EH, Paley MN, Sprigg A, Rutter S, Davies NP, Wilkinson ID et al. Comparison of ultrasound and magnetic
resonance imaging in 100 singleton pregnancies with suspected brain abnormalities. BJOG 2004; 111(8):784-
792.
(18) Kubik-Huch RA, Huisman TA, Wisser J, Gottstein-Aalame N, Debatin JF, Seifert B et al. Ultrafast MR imaging of
the fetus. AJR Am J Roentgenol 2000; 174(6):1599-1606.
(19) Pilu G, Segata M, Ghi T, Carletti A, Perolo A, Santini D et al. Diagnosis of midline anomalies of the fetal brain with
the three-dimensional median view. Ultrasound Obstet Gynecol 2006; 27(5):522-529.
(20) Malinger G, Kidron D, Schreiber L, Ben Sira L, Hoffmann C, Lev D et al. Prenatal diagnosis of malformations of
cortical development by dedicated neurosonography. Ultrasound Obstet Gynecol 2007; 29(2):178-191.
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as an adjunct to ultrasound in prenatal diagnosis. Eur Radiol 2003; 13(7):1538-1548.
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Radiol 1998; 28(4):212-222.
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in utero. AJNR Am J Neuroradiol 2000; 21(9):1688-1698.
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(27) Girard N, Raybaud C, Gambarelli D, Figarella-Branger D. Fetal brain MR imaging. Magn Reson Imaging Clin N Am
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(28) Raybaud C, Levrier O, Brunel H, Girard N, Farnarier P. MR imaging of fetal brain malformations. Childs Nerv Syst
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(29) Zimmerman RA, Bilaniuk LT. Magnetic resonance evaluation of fetal ventriculomegaly-associated congenital
malformations and lesions. Semin Fetal Neonatal Med 2005; 10(5):429-443.
(30) Prayer D, Brugger PC, Kasprian G, Witzani L, Helmer H, Dietrich W et al. MRI of fetal acquired brain lesions. Eur J
Radiol 2006; 57(2):233-249.
Chapter 11LACTATE TO CREATININE RATIO IN AMNIOTIC
FLUID: A PILOT STUDY
H.L. Torrance MD1, L. Pistorius MD1, H.A.M. Voorbij MD PhD2, G.H.A. Visser MD PhD1
1 Perinatal Center, Wilhelmina Children’s Hospital, University Medical Center Utrecht, the Netherlands; 2 Department of Clinical Chemistry, University Medical Center Utrecht, the Netherlands
Submitted
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ABSTRACT
Background
Measurement of amniotic fl uid lactate concentration in complicated pregnancies
may provide information on the extent of fetal academia. However, normalization
for amniotic fl uid volume may be necessary by calculating the lactate-creatinine (L:
C) ratio.
Methods and principal fi ndings
Amniotic fl uid lactate and creatinine concentrations were obtained at caesarean
section and were compared to lactate concentration in simultaneously collected
arterial cord blood of 28 term and 10 preterm pregnancies. Cord blood lactate was not
correlated to amniotic fl uid lactate, but was correlated to the L:C ratio in the complete
study population (R=0.54, p=0.001) and the subgroups. Correlation was strongest in a
preterm intrauterine growth restricted subgroup (n=7, R=0.83, p=0.02).
Conclusion
The L:C ratio is more accurate in estimating fetal lacticemia than the amniotic
fl uid lactate concentration. When transabdominal amniocentesis is performed for
determination of fetal lung maturity, the L:C ratio can be determined simultaneously
in merely 2 ml of amniotic fl uid. In future, simultaneous non-invasive assessment of
fetal acidosis and fetal lung maturity may become possible by measurement of the L:
C and L/S ratios via MRS and/or infrared spectroscopy.
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INTRODUCTION
Fetal acidemia may develop in intrauterine growth restricted (IUGR) fetuses as a
result of diminished transport of nutrients and oxygen to the fetus due to placental
insuffi ciency. With increasing placental insuffi ciency, a point may be reached where the
disadvantages of a detrimental intrauterine environment outweigh the disadvantages
of the delivery of an immature infant. In each individual case, clinicians must weigh the
advantages and disadvantages of prolonged intrauterine life and come to a decision
on the optimal time of delivery for the fetus (1).
Determining fetal lung maturity can aid in this decision. This can be assessed in amniotic
fl uid obtained via transabdominal amniocentesis. An earlier study by our group, showed
that the lecithin to sphingomyelin (L/S) ratio is >2 (indicating fetal lung maturity) in
half of the IUGR fetuses between 30 and 32 weeks of gestation (2). Simultaneous
measurement of amniotic fl uid lactate concentration may provide insight into the
extent of fetal lacticaemia. However, this concentration may be infl uenced by changes
in amniotic fl uid volume which is often diminished in IUGR. One approach to ensure
that differences in amniotic fl uid metabolite levels are not due to a different rate of
fetal urine production is to calculate a ratio of the amniotic fl uid metabolite of interest
to creatinine (3). The lactate to creatinine (L:C) ratio may therefore be more accurate
to determine the fetal condition in complicated pregnancies. This ratio has not been
studied before as an indicator of fetal wellbeing in IUGR. However, in postnatal life
the urinary L:C ratio has been shown to be predictive for the development of hypoxic-
ischemic encephalopathy in asphyxiated newborns (4).
The aim of the present study was to measure the L:C ratio and lactate concentration
in amniotic fl uid obtained during caesarean section and to correlate these parameters
with fetal lactate concentrations measured simultaneously in arterial cord blood.
METHODS
In this pilot study, amniotic fl uid samples were collected prospectively from pregnant
women undergoing caesarean section. After obtaining written informed consent,
women with uncomplicated pregnancies undergoing elective caesarean section at
term (for instance for breech presentation or repeat caesarean section) and women
undergoing caesarean section prematurely with an estimated fetal weight <p10 were
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included in the study. Fetuses with chromosomal and syndromal abnormalities were
excluded.
Amniotic fl uid samples (2 ml) were collected during caesarean section. Samples that
were contaminated with blood or meconium were discarded. Arterial umbilical cord
blood samples were collected simultaneously. In all materials, creatinine and lactate
concentrations were measured immediately (SI units).
Metabolite concentrations were analyzed in two gestational age (GA) groups: term
fetuses (GA>37 weeks) (1) and preterm fetuses (GA≤34 weeks) (2). The latter group
was divided into fetuses with intrauterine growth restriction (IUGR) associated with
placental insuffi ciency (if the pulsatility index (PI) of the umbilical artery was repeatedly
more than 2 standard deviations above the median) and fetuses that were small for
gestational age (SGA) and demonstrated normal umbilical artery PI.
Statistical analysis was performed using the Statistical Package for the Social Sciences
(SPSS version 14.0). Pearson’s correlations were determined or non-parametric
Spearman’s correlations where appropriate. Statistical signifi cance was accepted
when p<0.05.
The study was approved by the Medical Ethics Committee of the University Medical
Center Utrecht, the Netherlands.
RESULTS
After obtaining written informed consent, 54 pregnant women were included in the
study and 56 amniotic fl uid samples were collected (two twin pregnancies). In 18 cases,
the arterial cord blood lactate could not be measured (because too little arterial cord
blood was available or due to errors in blood sampling). These cases were therefore
excluded from analysis (including both twin pregnancies).
All 28 infants delivered electively at term were healthy. Median GA at birth in this
group was 274 days (range 272-278) and median birth weight 3480 grams (range 2855-
4630). Term infants from mothers with insulin treatment for diabetes were admitted
to the neonatal medium care unit for monitoring of blood glucose levels (n=3). Group
2 consisted of 10 infants with a median GA of 215 days (range 199-231) and median
birth weight of 1100 grams (range 760-1380). In this group, seven infants were IUGR,
fi ve infants were delivered for nonreassuring fetal monitoring and nine infants were
delivered for maternal reasons (preeclampsia or HELLP syndrome). All IUGR infants
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were admitted to the neonatal intensive care unit.
The L:C ratio decreased with increasing gestational age (correlation coeffi cient:
-0.72, p value 0.000). No correlation was found between arterial cord blood lactate
and amniotic fl uid lactate concentration in the complete study population (R=0.25, p
value 0.13), group 1 (R=0.19, p value 0.34) or group 2 (R=0.46, p value 0.18). In contrast,
arterial cord blood lactate concentration was signifi cantly correlated to the L:C ratio in
the complete study population (R=0.54, p value 0.001), group 1 (R=0.59, p value 0.001)
and group 2 (R=0.72, p value 0.02) (see Figure 1). Correlation was strongest in the IUGR
subgroup (R=0.83, p value 0.02).
Figure 1. Correlation between arterial cord blood lactate concentration and amniotic fl uid lactate-creatinine ratio of preterm fetuses
DISCUSSION
The present study indicates that the amniotic fl uid L:C ratio decreases with increasing
gestational age and that this ratio is signifi cantly correlated with arterial umbilical cord
lacticaemia. In contrast, the amniotic fl uid lactate concentration was not correlated
with fetal lacticaemia.
This fi nding may be explained by the fact that the amniotic fl uid lactate concentration
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is infl uenced by the amniotic fl uid volume, similar to the lecithin concentration (5,6).
Normalization for amniotic fl uid volume was performed by calculating the amniotic
fl uid lactate to creatinine ratio (3).
A good deal of research into normal biochemical composition of amniotic fl uid has been
performed many years ago and it has shown that metabolite concentrations change
during normal pregnancy. With increasing gestational age, lactate concentration falls
whereas creatinine has been shown to increase (7). This means that the L:C ratio can be
expected to fall with increasing gestational age, as was shown in the present study.
To our knowledge, this study is the fi rst to report data on the correlation between
simultaneously measured arterial umbilical cord lactate concentrations and amniotic
fl uid lactate and creatinine concentrations after caesarean section delivery of both term
and SGA preterm infants. The present study shows that the L:C ratio is of signifi cance
in both populations. Unfortunately, this pilot study was not designed to correlate fetal
lacticaemia results with neonatal outcome, which obviously is of great interest. The
urinary L:C ratio, however, has been shown to be predictive for the development of
hypoxic-ischemic encephalopathy in asphyxiated newborns (4). Future studies should
focus on measuring the amniotic fl uid L:C ratio and on correlating this ratio with
neonatal outcome.
From a practical point of view, the L:C ratio may become important in future, as
recent studies have demonstrated the capability to measure various amniotic fl uid
metabolites (including lecithin, lactate and creatinine) non-invasively via magnetic
resonance spectroscopy (MRS) (8-10) or infra red spectroscopy (11). These noninvasive
diagnostic tools could become valuable alternatives to invasive amniocentesis for the
simultaneous assessment of fetal asphyxia and fetal lung maturity.
ACKNOWLEDGMENTS
The authors wish to thank E. van Alderen for her participation in the conception and
design of the study.
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the lecithin/sphingomyelin ratio and lamellar body count: a cross-sectional study. J Matern Fetal Neonatal
Med 2003; 14: 373-382.
(3) di Iorio R, Marinoni E, Coacci F, La Torre R, Cosmi EV. Amniotic fluid nitric oxide and uteroplacental blood flow
in pregnancy complicated by intrauterine growth retardation. Br J Obstet Gynaecol 1997; 104: 1134-1139.
(4) Huang CC, Wang ST, Chang YC, Lin KP, Wu PL. Measurement of the urinary lactate:creatinine ratio for the early
identification of newborn infants at risk for hypoxic-ischemic encephalopathy. N Engl J Med 1999; 341: 328-
335.
(5) Roux JF, Nakamura J, Brown E, Sweet AY, Gluck L. The lecithin-sphingomyelin ratio of amniotic fluid: an index of
fetal lung maturity? Pediatrics 1972; 49: 464-467.
(6) Gluck L, Kulovich MV, Borer RC, Jr., Brenner PH, Anderson GG et al. Diagnosis of the respiratory distress
syndrome by amniocentesis. Am J Obstet Gynecol 1999; 109: 440-445.
(7) Lind T. The biochemistry of amniotic fluid. In: Sandler M editor. Amniotic fluid and its clinical significance. 1st
Edition.New York: Marcel Dekker Inc, 1981.
(8) Bock JL. Metabolic profi ling of amniotic fl uid by proton nuclear magnetic resonance spectroscopy: correlation
with fetal maturation and other clinical variables. Clin Chem 1994; 40: 56-61.
(9) McGowan PE, Reglinski J, Wilson R, Walker JJ, Wisdoms S et al. Quantitative 1H-NMR analysis of amniotic fluid.
J Pharm Biomed Anal 1993; 11: 629-632.
(10) Sims CJ, Fujito DT, Burholt DR, Dadok J, Giles HR et al. Quantification of human amniotic fluid constituents by
high resolution proton nuclear magnetic resonance (NMR) spectroscopy. Prenat Diagn 1993; 13: 473-480.
(11) Liu KZ, Mantsch HH. Simultaneous quantitation from infrared spectra of glucose concentrations, lactate
concentrations, and lecithin/sphingomyelin ratios in amniotic fluid. Am J Obstet Gynecol 1999; 180: 696-702.
SUMMARY
Chapter 12GENERAL DISCUSSION
AND RECOMMENDATIONS
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INTRODUCTION AND LITERATURE REVIEW
The intricacy of the development of the fetal brain is matched by the complexity of
the literature dealing with the respective merits and demerits of ultrasound and MRI
imaging of the fetal central nervous system. Since the 1960’s, ultrasound has been
used for brain imaging: fi rstly, with A-mode ultrasound (1), with which it was possible
to measure the biparietal diameter and visualize the midline. With B-mode ultrasound
it became feasible to visualize fetal structures in two dimensional (2D) cross-sectional
planes. With the arrival of three dimensional (3D) ultrasound, three orthogonal
planes could be displayed simultaneously, planes which might otherwise have been
inaccessible could be visualized, and volumes could be measured more accurately (2).
During the same time, magnetic resonance imaging (MRI) developed from a technique
which could provide “tissue characterization information that complements the
superior anatomic detail of ultrasound” (3) in the mid eighties, to arguably “the
optimal method for depicting the specifi c abnormalities that characterize each type of
malformation of the brain in the fetus” (4). And therein lies the rub: is MRI the optimal
method, or is “dedicated neurosonology … equal to MRI in the diagnosis of fetal brain
abnormalities” (5)?
Theoretically, the two modalities should be synergistic, as the physics behind image
generation is completely different. Ultrasound generates images by means of the
ultrasound waves refl ected at the interface between areas with different ultrasound
conductivity, and MRI contrast depends on the relative fat, water and proton content
of tissues. In practice, it is diffi cult to determine the relative merit of either technique
from the literature which is often clouded by an implicit or explicit bias for either
modality. Also, imaging does not equate diagnosis, and several publications confi rm
the value of a multidisciplinary approach to the diagnosis of fetal central nervous
system abnormalities (5;6). Both techniques are operator-dependent (7), and both
techniques are deemed to be safe in pregnancy (8;9).
Having said this, ultrasound imaging of the central nervous system seems preferable
(Chapter 2) for:
• screening examinations,
• repeated examinations,
• examinations before 20 weeks of gestation,
• the assessment of fetal movements before the third trimester,
• evaluation of cerebral blood fl ow,
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• evaluation of associated (extracranial) abnormalities and
• where MRI is contra-indicated or has failed.
MRI is preferred for:
• diffi cult ultrasound examination (such as oligohydramnios, an engaged fetal
head and ruptured membranes),
• the assessment of:
o posterior fossa abnormalities,
o schizencephaly,
o acute fetal asphyxia or
o severe microcephaly,
• evaluating fetal movements in the late third trimester (albeit at a somewhat
low frame rate),
• detecting and determining the age of intracranial bleeding,
• detecting intracranial tuberous sclerosis and
• postmortem brain imaging.
Both ultrasound and MRI should be combined in:
• cerebellar telangiectasis,
• cytomegaloviral infection,
• intracranial tumors or trauma,
• vein of Galen abnormalities,
• germinal matrix and intraventricular bleeding,
• hemimegalencephaly and
• septo-optic dysplasia.
Either would be suitable after 20 weeks for:
• the assessment of holoprosencephaly
• abnormalities of the corpus callosum,
• evaluation of ventriculomegaly or
• the diagnosis of craniosynostosis.
The literature review in chapter 2 also demonstrated some relatively uncharted
frontiers of the knowledge of the development of normal and abnormal fetal central
nervous system development, which we explored in the sections on physiology and
pathology.
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PHYSIOLOGY
With the high resolution images of commercially available high frequency transvaginal
transducers and software developed to chart ovarian follicle development, we could
obtain 3D images of the embryonic ventricular system at eight weeks of gestational
age that compared very favorably with images which were previously only obtainable
in a research setting (10;11). In addition, the single three-dimensional sweep used to
obtain these images as well as images which could be used for crown rump length
measurement and further anatomical evaluation could also minimize the exposure of
the rapidly developing embryo to ultrasound energy (Chapter 3). The applicability for
screening remains to be evaluated in greater detail.
The feasibility to limit the time of ultrasound exposure by using 3D ultrasound was
further explored in a longitudinal study in which standard neurosonographical planes
(12) were obtained in real time with two dimensional ultrasound and subsequently
from saved volume blocks obtained with 3D ultrasound. This demonstrated that it was
possible to visualize fetal cortical development (Chapter 4) and measure fetal ventricles
(Chapter 5) as well or better with 3D ultrasound as compared with two dimensional
ultrasound, while limiting the time of fetal exposure to ultrasound, and limiting the
total examination time (scanning and evaluation time) (Chapter 4).
Several publications have demonstrated clearly that fetal cortical development can
be demonstrated well with ultrasound (13-16). However, it is still diffi cult to translate
these fi ndings into practice, as the only the fi rst appearance of sulci and gyri were
typically described, rather than the development over time. Another limitation of
the available literature was the lack of a systematical description of physiological
asymmetry, as only the distal hemisphere is typically seen clearly using transabdominal
ultrasound. In our prospective study, a good intra- and inter-observer agreement was
achieved with a simple scoring system to describe cortical development. Using this
scoring system, and systematically endeavoring to visualize both hemispheres, we
demonstrated asymmetrical cortical development in a third of fetuses between 24
and 28 gestational weeks (Chapter 4). Longitudinal growth curves based on individual
developmental trajectories were generated using multilevel analysis. This scoring
system now needs to be evaluated prospectively to determine whether it is useful to
detect fetuses with malformations of cortical development.
Information on the prevalence of physiological asymmetry of the lateral cerebral
ventricles is also lacking, while the normal size of fetal ventricle is well described in the
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literature. A simple cut-off of 10mm for the ventricular atrium as measured on an axial
view has been used as a screening test for ventriculomegaly throughout pregnancy
(12;17). We confi rmed this cut-off value (which had originally been developed from
cross-sectional data) in our longitudinal study. Obtaining the midcoronal view on 2D
ultrasound and using volume contrast imaging (a modality of 3D ultrasound) facilitated
the evaluation of both left and right lateral cerebral ventricles. We demonstrated
asymmetry of the lateral ventricles in 4% of examinations. This is more than the 0.2
– 0.4% that has previously been reported (18). However, it is still much less than the
postnatal incidence of more than 40% (19) (Chapter 5). It would be interesting to
examine this prospectively a group of infants before and after delivery.
Longitudinal growth curves for the cerebellar volume were also generated from
individual developmental trajectories. The left fetal cerebellar hemisphere was found
to be signifi cantly larger than the right, especially before 32 weeks’ gestation. We
tested two ways of measuring the cerebellar volume, namely the multiplanar and
VOCALTM techniques. Both had a good intra- and inter-observer variability, and yielded
similar results. In the late third trimester, our data demonstrated larger fetal cerebellar
volumes than previously reported in Taiwanese (20;21) and Brazilian populations (22).
This might refl ect a difference between the different population groups, or a difference
in technique (Chapter 6). As is the case with the cortical scoring system, it remains
to be evaluated whether measurement of the cerebellar volume, rather than a one-
dimensional measurement such as the transverse cerebellar diameter, is more sensitive
and specifi c to detect syndromic (23) or acquired (24) cerebellar abnormalities.
PATHOLOGY
To determine whether the parameters visible on prenatal imaging could predict future
prognosis, infants who were antenatally diagnosed with spina bifi da were followed up
until demise or fi ve years of age. Multivariate regression analysis showed that a higher
lesion level and head circumference at or above the 90th percentile were independent
predictors of demise. None of the ultrasound features were associated with motor
or mental functioning at fi ve years of age. Prenatal ultrasound performed between
1997 and 2002 predicted the anatomical lesion level within one level of the postnatal
fi ndings in 50%, and in 89% between 2006 and 2007 (p < 0.01). This improvement
in the accuracy of ultrasound is offset by a difference between the functional level
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of neurological defi cit and the anatomical lesion level which still limits the ability of
ultrasound to predict motor function (Chapter 7).
We also investigated the prognostic value of Doppler ultrasound measurement of
the middle cerebral artery pulsatility index (mca PI) in fetuses with central nervous
system abnormalities. In fetuses with abnormalities of the central nervous system
an antenatal fi nding of increase in mca PI was associated with an increased risk of
adverse neurodevelopmental outcome. This was not found in fetuses with spina
bifi da or multiple abnormalities. An unexpected fi nding was than an increased mca
PI which subsequently decreased was seen in fetuses with malformations of cortical
development, microcephaly and West’s syndrome. Whether this refl ects an underlying
etiology (such as hemorrhage, vasculitis or delayed development of the arterial blood
supply) or is an incidental fi nding remains to be seen. A rapid rise in mca PI was seen
in fetuses with a high risk of demise, especially in fetuses with hydrocephalus. The
advice that a rise in mca PI should be an indication for delivery was not born out by our
fi ndings. One possible explanation is that arterial blood fl ow would only be impaired
at relatively high levels of intracranial pressure and thus refl ect a very advanced stage
of disease progression. Another arterial index (such as the trans systolic time) (25) or
venous fl ow characteristics (26) might be more appropriate, but would need to be
tested prospectively (Chapter 8).
As introduction to the evaluation of our own experience with the relative value of
ultrasound and MRI and multidisciplinary discussions, we present a case of a fetus
that developed malformations of cortical development after requiring intra-uterine
transfusion for a severe Parvovirus B19 infection. Antenatal MRI demonstrated mild
unilateral ventriculomegaly. Polymicrogyria and heterotopia were confi rmed on
postnatal MRI (Chapter 9).
For this evaluation we determined the diagnostic accuracy of ultrasound, MRI, and
multidisciplinary discussions before and after MRI. We investigated a retrospective
cohort of patients where an MRI of the fetal central nervous system was performed
between 2000 and 2008. We also compared the accuracy of standard ultrasound
examinations with that of neurosonograms, and found that the diagnosis made during
the multidisciplinary discussion was accurate in 62% before and 73% of patients after
MRI. The diagnosis remained unchanged in 23 out of 28 patients. The accuracy of the
diagnosis improved in four patients and decreased in one patient after MRI. Standard
ultrasound examinations were accurate in 42% of patients, and neurosonograms in
63% of patients. The highest accuracy of prenatal diagnosis of fetal CNS lesions (78%)
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was obtained with a multidisciplinary discussion after neurosonography and MRI
(Chapter 10). No improvement in accuracy after MRI was seen in patients with neural
tube lesions, and the biggest improvement was seen in patients with an ultrasound
diagnosis of ventriculomegaly.
Of interest for future research into using MR spectroscopy to diagnose the degree of
fetal asphyxia non-invasively is the fi nding that the amniotic fl uid lactate-creatinine-
ratio is a good predictor of fetal lacticemia (Chapter 11).
RECOMMENDATIONS AND FUTURE DEVELOPMENTS
• It is possible to obtain clear pictures of the developing cerebral ventricle system
at eight gestational weeks from a single 3D ultrasound volume and automatic
volume calculation software. The value of this technique to diagnose intracranial
and extracranial pathology should be evaluated further.
• It is feasible to grade fetal cortical development using a simple scoring system.
This scoring system should be evaluated for its usefulness to diagnose of fetal
malformations of cortical development.
• It is possible to limit fetal exposure and total examination time by using 3D
ultrasound.
• Both lateral ventricles can usually be visualized with transabdominal ultrasound
by obtaining the mid coronal plane with 2D ultrasound, and by using (3D) volume
contrast imaging.
• Asymmetry is a feature of normal fetal brain development. It is most pronounced
in cortical development and to a lesser extent in ventricle development. A group
of infants should be followed up longitudinally during pre- and postnatally to
fi nd an explanation for the differences in prevalence of asymmetry of the brain
before and after birth.
• Cerebellar volumes can be measured equally well with VOCALTM or the multiplanar
technique. The use of the cerebellar volume to detect abnormalities in cerebellar
growth a should be evaluated prospectively.
• The fetus with a suspected fetal central nervous system lesion should be
discussed in a multidisciplinary meeting. If a fetal neurosonogram does not
provide suffi cient information, an MRI should be performed.
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• In fetuses with spina bifi da, survival can be predicted accurately with antenatal
ultrasound, but future mental or motor function cannot be predicted.
• A raised mca PI in a fetus with a CNS abnormality is associated with an increased
risk of death or adverse neurodevelopmental outcome. The evaluation of the
fetal cerebral circulation deserves more study; both in terms of predicting
malformations of cortical development, and in terms of timing the delivery of the
fetus with hydrocephalus. 3D ultrasound techniques such as the vascularization
and fl ow indices (27) and MRI techniques to identify hypo- or hyperperfused
areas of the fetal brain or to determine oxygen and pH levels (28;29) might be
useful in this regard.
• Fetal lacticemia (as measure of asphyxia) can be predicted by the ratio of lactate
to creatinine in amniotic fl uid. It should be evaluate how best to assess this non-
invasively with MR spectroscopy (30;31).
• The prenatal use of MRI with higher fi eld strengths than the currently accepted
1.5 Tesla equipment needs further evaluation to confi rm its safety before it
should be used in pregnancy.
• It is also conceivable that the evaluation of fetal movements on ultrasound
and MRI will be included in clinical practice to move from an anatomical and
structural diagnosis to a full fetal neurological examination (32).
• There is still a need for a prospective, unbiased evaluation to determine the
relative value of ultrasound and MRI in the diagnosis of fetal central nervous
system abnormalities.
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REFERENCES
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ultrasonographic reslicing of the fetal brain to assist prenatal diagnosis of central nervous system anomalies. J
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(3) McCarthy SM, Filly RA, Stark DD, Hricak H, Brant-Zawadzki MN, Callen PW et al. Obstetrical magnetic resonance
imaging: fetal anatomy. Radiology 1985; 154(2):427-432.
(4) Raybaud C, Levrier O, Brunel H, Girard N, Farnarier P. MR imaging of fetal brain malformations. Childs Nerv Syst
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(5) Malinger G, Ben Sira L, Lev D, Ben Aroya Z, Kidron D, Lerman-Sagie T. Fetal brain imaging: a comparison between
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340.
(6) Brugger PC, Stuhr F, Lindner C, Prayer D. Methods of fetal MR: beyond T2-weighted imaging. Eur J Radiol 2006;
57(2):172-181.
(7) Abramowicz JS. Prenatal exposure to ultrasound waves: is there a risk? Ultrasound Obstet Gynecol 2007;
29(4):363-367.
(8) Kanal E. Pregnancy and the safety of magnetic resonance imaging. Magn Reson Imaging Clin N Am 1994;
2(2):309-317.
(9) Hagmann CF, Robertson NJ, Leung WC, Chong KW, Chitty LS. Foetal brain imaging: ultrasound or MRI. A
comparison between magnetic resonance imaging and a dedicated multidisciplinary neurosonographic opinion.
Acta Paediatr 2008; 97(4):414-419.
(10) Blaas HG, Eik-Nes SH, Berg S, Torp H. In-vivo three-dimensional ultrasound reconstructions of embryos and early
fetuses. Lancet 1998; 352(9135):1182-1186.
(11) Tanaka H, Senoh D, Yanagihara T, Hata T. Intrauterine sonographic measurement of embryonic brain vesicle.
Hum Reprod 2000; 15(6):1407-1412.
(12) Malinger G, Monteagudo A, Pilu G, Timor-Tritsch IE, Toi A. Sonographic examination of the fetal central nervous
system: guidelines for performing the ‘basic examination’ and the ‘fetal neurosonogram’. Ultrasound Obstet
Gynecol 2007; 29(1):109-116.
(13) Bernard C, Droulle P, Didier F, Gerard H, Larroche JC, Plenat F et al. [Echographic aspects of cerebral sulci in the
ante- and perinatal period]. J Radiol 1988; 69(8-9):521-532.
(14) Cohen-Sacher B, Lerman-Sagie T, Lev D, Malinger G. Sonographic developmental milestones of the fetal cerebral
cortex: a longitudinal study. Ultrasound Obstet Gynecol 2006; 27(5):494-502.
(15) Monteagudo A, Timor-Tritsch IE. Development of fetal gyri, sulci and fi ssures: a transvaginal sonographic study.
Ultrasound Obstet Gynecol 1997; 9(4):222-228.
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(16) Toi A, Lister WS, Fong KW. How early are fetal cerebral sulci visible at prenatal ultrasound and what is the normal
pattern of early fetal sulcal development? Ultrasound Obstet Gynecol 2004; 24(7):706-715.
(17) Cardoza JD, Goldstein RB, Filly RA. Exclusion of fetal ventriculomegaly with a single measurement: the width of
the lateral ventricular atrium. Radiology 1988; 169(3):711-714.
(18) Achiron R, Yagel S, Rotstein Z, Inbar O, Mashiach S, Lipitz S. Cerebral lateral ventricular asymmetry: is this a
normal ultrasonographic fi nding in the fetal brain? Obstet Gynecol 1997; 89(2):233-237.
(19) Shen EY, Huang FY. Sonographic fi nding of ventricular asymmetry in neonatal brain. Arch Dis Child 1989;
64(5):730-732.
(20) Chang CH, Chang FM, Yu CH, Ko HC, Chen HY. Assessment of fetal cerebellar volume using three-dimensional
ultrasound. Ultrasound Med Biol 2000; 26(6):981-988.
(21) Hata T, Kuno A, Dai S-Y, Inubashiri E, Hanaoka U, Kanenishi K et al. Three-dimensional sonographic volume
measurement of the fetal cerebellum. J Med Ultrasonics 2007; 34(1):17-21.
(22) Araujo JE, Guimaraes Filho HA, Pires CR, Nardozza LM, Moron AF, Mattar R. Validation of fetal cerebellar volume
by three-dimensional ultrasonography in Brazilian population. Arch Gynecol Obstet 2007; 275(1):5-11.
(23) McCann E, Pilling D, Hesseling M, Roberts D, Subhedar N, Sweeney E. Pontomedullary disconnection: fetal and
neonatal considerations. Pediatr Radiol 2005; 35(8):812-814.
(24) Johnsen SD, Bodensteiner JB, Lotze TE. Frequency and nature of cerebellar injury in the extremely premature
survivor with cerebral palsy. J Child Neurol 2005; 20(1):60-64.
(25) Hanlo PW, Gooskens RH, Nijhuis IJ, Faber JA, Peters RJ, van Huffelen AC et al. Value of transcranial Doppler
indices in predicting raised ICP in infantile hydrocephalus. A study with review of the literature. Childs Nerv Syst
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(26) Pooh RK, Pooh KH, Nakagawa Y, Maeda K, Fukui R, Aono T. Transvaginal Doppler assessment of fetal intracranial
venous fl ow. Obstet Gynecol 1999; 93(5 Pt 1):697-701.
(27) Chang CH, Yu CH, Ko HC, Chen CL, Chang FM. Three-dimensional power Doppler ultrasound for the assessment
of the fetal brain blood fl ow in normal gestation. Ultrasound Med Biol 2003; 29(9):1273-1279.
(28) Levine D. Science to practice: can MR oxygenation imaging be used to assess at-risk pregnancies? Radiology
2006; 238(3):765-766.
(29) Wedegartner U, Tchirikov M, Schafer S, Priest AN, Kooijman H, Adam G et al. Functional MR imaging: comparison
of BOLD signal intensity changes in fetal organs with fetal and maternal oxyhemoglobin saturation during
hypoxia in sheep. Radiology 2006; 238(3):872-880.
(30) Borowska-Matwiejczuk K, Lemancewicz A, Tarasow E, Urban J, Urban R, Walecki J et al. Assessment of fetal
distress based on magnetic resonance examinations: preliminary report. Acad Radiol 2003; 10(11):1274-1282.
(31) Roelants-van Rijn AM, Groenendaal F, Stoutenbeek P, van der GJ. Lactate in the foetal brain: detection and
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(32) de Vries JI, Fong BF. Changes in fetal motility as a result of congenital disorders: an overview. Ultrasound Obstet
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Appendix
NEDERLANDSE SAMENVATTING
AFRIKAANSE OPSOMMING
ACKNOWLEDGMENTS
CURRICULUM VITAE
LIST OF PUBLICATIONS
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NEDERLANDSE SAMENVATTING
Vanaf 1960 kunnen de hersenen van de foetus met echografi e worden afgebeeld.
Met A-mode echografi e (1) kon de bipariëtale diameter gemeten en de falx cerebri
zichtbaar gemaakt worden. B-mode echografi e maakte het mogelijk foetale
structuren in tweedimensionale (2D) snijvlakken zichtbaar te maken. Met de komst
van driedimensionale (3D) echografi e, kunnen drie orthogonale snijvlakken gelijktijdig
worden getoond, en kunnen volumes nauwkeuriger worden gemeten (2). Gelijktijdig
ontwikkelde de Magnetic Resonance Imaging (MRI) zich van een techniek die “informatie
over weefsels kon verstrekken als aanvulling op het superieure anatomische detail van
echografi e” (3), tot een techniek die door sommigen beschouwd wordt als “de optimale
methode om afwijkingen af te beelden die specifi ek zijn voor elke afwijking van de
hersenen van de foetus” (4). Nu rijst dus de vraag of MRI superieur is aan specifi eke
neurosono(=echo)grafi e om foetale hersenenafwijkingen te diagnosticeren (5).
Beide technieken zijn afhankelijk van degene die ze hanteert (6) en beide technieken
worden geacht veilig te zijn in de zwangerschap (7;8). Theoretisch zouden de twee
methoden elkaar kunnen aanvullen, aangezien de fysica achter de beeldvorming
geheel verschillend is. Echografi e produceert een beeld door middel van ultrasone
geluidsgolven die worden teruggekaatst op de overgang van structuren met een
verschillend geluidsgeleidingsvermogen en bij de MRI ontstaat het beeld doordat
weefsels een verschillende samenstelling hebben van onder meer vet en water.
Beeldvorming is geen diagnose. Uit literatuur gegevens is het niet goed mogelijk de
waarde van beide technieken in te schatten. In een aantal publicaties wordt daarom de
nadruk gelegd op een multidisciplinaire benadering om tot een diagnose van foetale
centrale zenuwstelselafwijkingen te komen (5;9).
Uit onderzoek in Hoofdstuk 2 beschrijven blijkt dat echografi e te verkiezen is voor de
volgende onderzoeken:
• screenings onderzoek,
• follow-up onderzoek,
• onderzoek vóór de 20ste zwangerschapsweek,
• beoordeling van foetale bewegingen vóór het derde trimester,
• evaluatie van doorbloeding van de hersenen,
• onderzoek naar afwijkingen anders dan aan het centrale zenuwstelsel en
• indien er een contra-indicatie is voor MRI, of waar MRI geen diagnose
oplevert.
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MRI heeft de voorkeur bij:
• onvoldoende echografi sche beeldvorming,
• beoordeling van foetale hersenen in geval van:
o afwijkingen in de fossa posterior,
o schizencephaly,
o acute foetale asfyxie en
o ernstige microcefalie,
• evaluatie van foetale bewegingen aan het eind van de zwangerschap,
• evaluatie van intracraniële bloedingen,
• onderzoek naar intracraniële tubereuse sclerose en
• postmortaal onderzoek van de hersenen.
Echografi e en MRI vullen elkaar aan bij onderzoek naar:
• cerebellaire telangiëctasie,
• cytomegalovirusinfectie,
• intracraniële tumoren of trauma,
• afwijkingen van de vena van Galen,
• intraventriculaire en germinale matrix bloedingen,
• hemimegalencephaly en
• septo-optische dysplasie.
Beide technieken zijn na 20 weken in gelijke mate geschikt voor:
• beoordeling van holoprosencephalie,
• afwijkingen aan het corpus callosum,
• evaluatie van ventriculomegalie of
• diagnose van craniosynostosis.
Het literatuuroverzicht, beschreven in Hoofdstuk 2, toonde nog een aantal lacunes
met betrekking tot de kennis omtrent normale en afwijkende ontwikkeling van
de foetale centrale zenuwstelsel. Deze hadden vooral betrekking op de eventuele
toegevoegde waarde van de nieuwe generatie 3D echo apparaten, zowel in beperking
van expositietijd, visualisatie van cerebrale structuren vroeg in de zwangerschap
en volumemetingen. Ontwikkeling van gyri en sulci bleek nog onvoldoende
bestudeerd, alsmede het optreden van een asymmetrie eventueel tijdens de cerebrale
ontwikkeling. Deze aspecten vormden het doel van de onderzoeken beschreven in de
sectie “fysiologie”. In de sectie “pathologie” bestuderen wij de voorspellende waarde
van 2D en 3D echografi e (en MRI) om die kans op overleving en het psychische en
motorische vermogen van kinderen met spina bifi da te bepalen. Ook werd de
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prognostische betekenis van cerebrale arteriële bloedstroomprofi elen op de uitkomst
van de zwangerschap bestudeerd, bij een heel scala van foetale cerebrale afwijkingen.
De diagnostische betrouwbaarheid van echografi e en MRI en de betekenis van
multidisciplinaire team besprekingen werk bestudeerd. Ten slotte werd een eerste
onderzoek gedaan naar de mogelijkheid van MR spectroscopie om de graad van foetale
bedreiging (lactaat) vast te stellen.
FYSIOLOGIE
Met behulp van software speciaal ontwikkeld om ovariële follikel groei te
vervolgen, hebben wij 3D beelden van het ventrikelsysteem van het embryo bij een
zwangerschapstermijn van acht weken verkregen. Deze beelden waren uitstekend
vergelijkbaar met beelden die eerder alleen in een specifi eke onderzoekssetting
mogelijk waren (10; 11). Bovendien kon deze techniek ook gebruikt worden om de
kruin-stuit-lengte te meten en de verdere anatomie te evalueren. Met deze techniek
werd het zich ontwikkelende embryo korter blootgesteld aan ultrageluidenergie dan
bij conventionele echografi e (Hoofdstuk 3). Toepassing van deze techniek bij screening
van foetale afwijkingen moet nog nader worden geëvalueerd.
Om te onderzoeken of met 3D echografi e ook in ander onderzoek de
ultrageluidsblootstelling beperkt werd, is een longitudinaal onderzoek verricht
waarbij de neurosonografi sche snijvlakken (12) in real-time met 2D echografi e en
van opgeslagen 3D volumeblokken werden vergeleken. Dit onderzoek toonde aan
dat de beoordeling van de foetale ventrikels (Hoofdstuk 5) en de ontwikkeling van de
cortex (Hoofdstuk 4) met 3D even betrouwbaar was als met 2D echografi e, terwijl de
tijdsduur van blootstelling van de foetus aan ultrageluid en de totale onderzoekstijd
met 3D echografi e korter was (Hoofdstuk 4).
In verschillende publicaties is aangetoond dat de foetale cortikale ontwikkeling goed
met echografi e (13-16) kan worden bekeken. Eerste verschijning van sulci en gyri is
beschreven, maar onderzoek naar de verdere ontwikkeling van de windingen in tijd
is beperkt. Ook is nauwelijks onderzoek gedaan naar het optreden van fysiologische
cortikale asymmetrie, aangezien met transabdominale echografi e slechts de distale
hemisfeer goed zichtbaar kan worden gemaakt. In ons prospectieve onderzoek werd
een eenvoudig scoresysteem ontwikkeld om cortikale ontwikkeling te beschrijven
met een score van 0 tot 5 voor verschillende stadia van ontplooiing. Met dit systeem
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toonden wij een asymmetrische cortikale ontwikkeling aan bij een derde van de
foetus tussen 24 en 28 zwangerschapsweken (Hoofdstuk 4). De intra- en interobserver
overeenkomst van dit telsysteem was goed. Met behulp van multi-level analyse werden
longitudinale groeicurven van de verschillende sulci en gyri samengesteld. Het is de
bedoeling dit systeem prospectief te evalueren om de eventuele waarde aan te tonen
bij de identifi catie van afwijkingen van de ontwikkeling van de cortex van de foetus.
Ook over de prevalentie van fysiologische asymmetrie van de laterale hersenventrikels
zijn weinig gegevens bekend, ondanks het feit dat de normale grootte van de foetale
ventrikels uitvoerig beschreven is. De afkapwaarde van 10mm voor het axiaal
gemeten ventriculaire atrium, is vanuit cross-sectionele gegevens ontwikkeld en wordt
gedurende de gehele zwangerschap gebruikt als grenswaarde voor ventriculomegalie
(12; 17). Wij bevestigden deze afkapwaarde in onze longitudinale studie. Het verkrijgen
van het midcoronale vlak met 2D echografi e en het gebruiken van volume contrast
imaging (een modaliteit van 3D echografi e) vereenvoudigden de evaluatie van zowel
linker als rechter laterale hersenventrikels. Wij vonden asymmetrie van de laterale
ventrikels in 4%. Dit is meer dan de 0.2 - 0.4% die in eerdere publicaties gevonden zijn,
(18) maar aanmerkelijk minder dan de 40% die bij postnataal onderzoek is gevonden
(19) (Hoofdstuk 5). Een verklaring voor de verschillen in asymmetrie pre- en postnataal
is niet eenvoudig te geven. Het is van belang om een groep kinderen vóór en na de
bevalling prospectief te vervolgen.
Longitudinale groeicurven van het volume van het cerebellum zijn ook door ons met
multi-level analyse van individuele groeicurven ontwikkeld. De linker cerebellaire
hemisfeer bleek beduidend groter dan de rechter, vooral vóór 32 zwangerschapsweken.
Wij testten twee manieren om het volume van de kleine hersenen te meten, namelijk
de multiplanaire en de VOCALTM techniek. Beide technieken hadden een goede intra-
en interobserver correlatie en leverden gelijkwaardige resultaten op. Aan het einde
van het derde trimester, vonden wij een groter foetaal volume van het cerebellum dan
eerder gerapporteerd in Taiwanese (20; 21) en Braziliaanse bevolkingsgroepen (22). Dit
kan op een populatieverschil of op een verschil in techniek berusten (Hoofdstuk 6).
Onderzocht moet nog worden of meting van het cerebellaire volume, in plaats van een
unidimensionale meting zoals de transcerebellaire diameter, van grotere waarde is om
syndromale (23) of verworven (24) afwijkingen van het cerebellum te diagnosticeren.
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PATHOLOGIE
Om te onderzoeken of prenatale beeldvorming van een foetus met een spina bifi da
prognostische waarde heeft, werden kinderen met een antenataal vastgestelde spina
bifi da gevolgd tot de leeftijd van vijf jaar of tot hun overlijden. De plaats van de spina
in de wervelkolom en de grootte van het hoofd bleken onafhankelijk gecorreleerd
met de kans op overlijden. De motorische en mentale ontwikkeling op 5-jarige leeftijd
waren niet gerelateerd met echografi sche bevindingen. De echografi sche bepaling
van het anatomische letselniveau bleek accuraat binnen één wervelniveau in 50% van
de onderzoeken die tussen 1997 en 2002 plaatsvonden en in 89% van de onderzoeken
die tussen 2006 en 2007 uitgevoerd werden (p < 0.01). Hoewel de nauwkeurigheid van
antenataal echografi sch onderzoek dus toegenomen is, heeft dit geen voorspellende
waarde voor de uiteindelijke motorische functie. Dit komt omdat het functionele
niveau van neurologische uitval niet correleert met het anatomische letselniveau
(Hoofdstuk 7).
Wij onderzochten ook de voorspellende waarde van Doppler bloedstroomprofi elen in
de middelste cerebrale arterie (pulsatiliteitsindex; mca PI) bij foetus met een centrale
zenuwstelselafwijking (Hoofdstuk 8). Bij foetus met een afwijking van het centrale
zenuwstelsel was de aanwezigheid van een verhoogde mca PI, indicatief voor een
verhoogde foetale vaatweerstand, geassocieerd met een verhoogd risico op een
ongunstige neurologische ontwikkeling. Dit werd niet gevonden bij de foetus met een
spina bifi da of complexe hersenafwijkingen. Een onverwachte bevinding was dat als
een initieel verhoogde mca PI later in de zwangerschap afnam, dit geassocieerd bleek
met cortikale ontwikkelingsstoornissen, microcefalie of het syndroom van West. Of de
onderliggende etiologie hiervan een bloeding, vasculitis of vertraagde ontwikkeling
van de arteriële bloedaanvoer of een toevalsbevinding is, dient nader te worden
onderzocht.
Een snelle stijging van de mca PI werd gezien bij de foetus met een hoog risico op
overlijden, vooral bij foetus met een hydrocefalus. Het advies om de zwangerschap
bij een snelle stijging van de mca PI voortijdig te beëindigen wordt daarom niet
door ons bevestigd omdat men dan eigenlijk al te laat is. Een mogelijke verklaring is
dat de arteriële fl ow pas bij een vrij hoge intracraniële druk afneemt en dus op een
vergevorderd stadium van ziekte zou kunnen wijzen. Andere arteriële indices zoals
transsystolische tijd (25) of karakteristieken van de veneuze fl ow (26) zouden mogelijk
een betere voorspellende waarde hebben, maar ook dit moet prospectief worden
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geëvalueerd.
De aanleiding om onze bevindingen bij echografi e, MRI en multidisciplinaire
besprekingen te evalueren was een casus van een foetus met malformaties van
cortikale ontwikkeling na een intra-uterine transfusie voor een ernstige anemie na
een Parvovirus B19 besmetting (Hoofdstuk 9). Voor deze evaluatie bepaalden wij de
diagnostische nauwkeurigheid van echografi e, MRI en multidisciplinaire besprekingen
voor en na MRI. Wij onderzochten een retrospectief cohort van patiënten bij wie
tussen 2000 tot 2008 een MRI van het foetale centrale zenuwstelsel was verricht. Wij
vergeleken ook de nauwkeurigheid van het standaard echografi sch onderzoek met
dat van neurosonografi e. De diagnose die tijdens de multidisciplinaire bespreking
werd gesteld was accuraat bij 62% vóór en bij 73% van de patiënten na de MRI.
Neurosonografi e was aanmerkelijk beter dan standaard echografi e (juiste diagnose
in respectievelijk 63% en 42% van die gevallen). De hoogste nauwkeurige prenatale
diagnose van foetale centrale zenuwstelselletsels (78%) werd verkregen door een
multidisciplinaire bespreking na neurosonografi e en MRI (Hoofdstuk 10). Bij patiënten
met een echografi sche diagnose van ventriculomegalie gaf MRI de grootste verbetering
in nauwkeurigheid van de diagnose. Bij patiënten met neuraalbuisafwijkingen was
MRI niet van aanvullende betekenis.
Van belang voor toekomstig onderzoek naar de mogelijkheid van MR spectroscopie
om de graad van foetale bedreiging vast te stellen is de bevinding dat het vruchtwater
lactate-creatinine ratio een goede voorspeller is voor foetale lacticemie.
CONCLUSIES EN AANBEVELINGEN
• Het is mogelijk om bij acht weken zwangerschap duidelijke beelden van het
ontwikkelende hersenventrikelsysteem uit één enkel 3D echografi sch volume
te verkregen met behulp van automatische volumen calculatie software. De
waarde van deze techniek voor zowel intracraniële als extracraniële pathologie
dient nader bepaald te worden.
• Een eenvoudig scoringsysteem blijkt goed te functioneren om de foetale
cortikale ontwikkeling te graderen. De waarde hiervan om malformaties van
cortikale ontwikkeling te bepalen dient nader bestudeerd te worden.
• 3D echografi e verkort de tijd noodzaaklijk voor echo onderzoek; dit betreft
zowel de foetale blootstellingtijd als de totale onderzoekstijd.
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• Verkrijging van het midcoronale vlak met 2D echografi e en het gebruik van (3D)
volume contrast imaging bij transabdominale echografi e faciliteert in de meeste
gevallen beoordeling van beide laterale ventrikels.
• Asymmetrie is een kenmerk van normale foetale hersenontwikkeling; dat is
het meest uitgesproken bij de cortikale ontwikkeling en in mindere mate bij
de ventrikelontwikkeling. Het is van belang om een groep kinderen vóór en
na de bevalling prospectief te vervolgen om een verklaring te vinden voor de
verschillen in prevalentie van asymmetrie van de hersenventrikels voor en na
geboorte.
• Cerebellaire volumina kunnen even goed met VOCALTM als met een multiplanaire
techniek gemeten worden. De waarde van volumemetingen om afwijkingen
van cerebellaire ontwikkeling te ontdekken dient prospectief te worden
geëvalueerd.
• Foetus met een mogelijk centraal zenuwstelselletsel moeten multidisciplinair
worden besproken. Indien een foetaal neurosonogram onvoldoende informatie
geeft, dan dient het onderzoek uitgebreid te worden met een MRI.
• Bij de foetus met een spina bifi da kan de overleving met prenatale echografi e
worden voorspeld, maar het latere motorisch en mentaal functioneren van het
kind kan niet worden voorspeld.
• Een verhoogde mca PI bij foetus met een centrale zenuwstelselafwijking duidt
op een groter risico op overlijden of abnormale neurologische ontwikkeling.
Verder onderzoek dient zicht te richten op een eventueel verband met cortikale
ontwikkelingstoornissen en op de waarde ten aanzien van het vaststellen
van het optimale moment van geboorte van een kind met hydrocephalus. 3D
echografi sche technieken zoals vascularisatie en fl ow- Dopplerindexen (27) en
MRI technieken om hypo- of hypergeperfundeerde gebieden van de foetale
hersenen te identifi ceren en daarin hypoxie en pH te bepalen (28;29) zouden
hierbij nuttig kunnen zijn.
• Foetale lacticemie (als marker van asfyxie) kan door de ratio van lactaat tot
creatinine in vruchtwater voorspeld worden. Het dient onderzocht te worden
hoe dit het beste non-invasief met MR spectroscopie bepaald kan worden
(30;31).
• De veiligheid in de zwangerschap van MRI-apparaten met een hogere veldsterkte
dan de momenteel toegelaten 1.5 Tesla apparaten vergt nadere evaluatie,
alvorens dit prenataal gebruikt kan worden.
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• Mogelijk zal evaluatie van foetale bewegingen met echografi e en MRI een
plaats krijgen in de klinische praktijk niet alleen om een anatomische diagnose
te stellen, maar ook om de neurologische status van de foetus te bepalen (32).
• Er blijft behoefte aan verder prospectief, goed opgezet onderzoek om de
waarde te bepalen van echografi e en MRI bij diagnostiek van foetale centrale
zenuwstelselafwijkingen.
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AFRIKAANSE OPSOMMING
Inleiding en literatuuroorsig
Sedert die 1960’s is dit al moontlik om die fetale brein met sonar te ondersoek. Met A-
mode sonar was dit moontlik om die bipariëtale diameter te meet en die falx af te beeld
(1). Met die koms van B-mode sonar kon fetale strukture in twee-dimensionele (2D)
snitvlakke gesien word. Sedert die beskikbaarheid van drie-dimensionele (3D) sonar
is dit moontlik om drie ortogonale vlakke (vlakke loodreg op mekaar) terselfdertyd te
vertoon, en om vlakke te sien wat andersins nie sigbaar is nie, en om volumes meer
akkuraat te meet (2).
Gedurende dieselfde tyd het MRI ook ontwikkel van ‘n tegniek wat in die mid
tagtigerjare gebruik is vir die “vertoning van weefselkenmerke as aanvulling tot
die beter anatomiese detail van sonar” (3) tot ’n tegniek wat deur sommige beskou
word as “die optimale metode om die spesifi eke abnormaliteite af te beeld wat
elke tipe malformasie van die fetale brein kenmerk” (4). Daar lê die vraag: is MRI die
optimale metode, of is gedetailleerde neurosonografi e net so goed as MRI om fetale
breinabnormaliteite te diagnoseer (5)?
Beide tegnieke is operateur-afhanklik (6), en volgens huidige kennis veilig in swangerskap
(7;8). Teoreties behoort die twee metodes sinergisties te wees, omdat die fi sika agter die
beeldvorming heeltemal verskil. Sonarbeelde word opgewek deur ultraklankgolwe wat
weerkaats word vanaf skeidingsvlakke tussen areas met verskillende klankgeleiding,
terwyl MRI kontras afhanklik is van die relatiewe vet-, water- en protoninhoud van
weefsels. In die praktyk word die literatuur dikwels verduister deur ‘n implisiete of
eksplisiete sydigheid vir een van die twee tegnieke. Beeldvorming is ook nie gelyk
aan diagnose nie, en verskeie publikasies bevestig die waarde van ‘n multidissiplinêre
benadering tot die diagnose van fetale sentrale senustelsel abnormaliteite (5;9).
Dit lyk wel asof sonar verkieslik is vir (Hoofstuk 2):
• siftingsondersoeke,
• herhaalde ondersoeke,
• ondersoeke voor 20 swangerskapsweke,
• die beoordeling van fetale bewegings voor die derde trimester,
• evaluasie van serebrale bloedvloei,
• om vir geassosieerde (ekstrakraniële) afwykings te soek en
• waar daar ‘n kontra-indikasie vir MRI is of die MRI nie geslaag het nie.
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MRI is weer verkieslik in:
• gevalle van moeilike sonarondersoeke (byvoorbeeld by oligohidramnion, ‘n
ingedaalde fetale skedel en gebroke vliese),
• die beoordeling van
o posterior fossa abnormaliteite,
o skisensefalie,
o akute fetale asfi ksie of
o erge mikrosefalie,
• evaluasie van fetale bewegings laat in die derde trimester,
• evaluasie van intrakraniële bloeding,
• opsporing van intrakraniële tubereuse sklerose en
• vir postmortem beeldvorming.
Sonar en MRI behoort in kombinasie gebruik te word by:
• serebellêre telangiëktase,
• sitomegalovirusinfeksie,
• intrakraniële tumore of trouma,
• malformasies van die vena van Galenus,
• germinale matriks en intraventrikulêre bloeding,
• hemimegalensefalie en
• septo-optiese displasie.
Enige van die twee is na 20 weke geskik vir die beoordeling van:
• holoprosensefalie,
• abnormaliteite van die corpus callosum,
• evaluasie van ventrikulomegalie of
• die diagnose van kraniosinostose.
Die literatuuroorsig in hoofstuk 2 het ook ‘n aantal ongekaarte terreine op die gebied
van die normale en abnormale ontwikkeling van fetale sentrale senustelsel aangedui,
wat verder in die afdelings oor fi siologie en patologie verken word.
FISIOLOGIE
Met behulp van sagteware wat ontwikkel is om ovariële follikelontwikkeling te volg,
was dit moontlik om al teen agt weke 3D beelde van die embrionale ventrikelsisteem
te verkry. Die beelde het uitstekend vergelyk met beelde wat vantevore net in ‘n
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navorsingsopset moontlik was (10;11). Uit die enkele 3D-volume blok waaruit hierdie
beelde verkry is, was dit ook moontlik om de standaardsnitte vir anatomiese evaluasie
en meting van die kruin-romp-lengte te verkry, en terselfdertyd die blootstelling van
die snel-ontwikkelende embrio aan ultraklankenergie te beperk (Hoofstuk 3). Die
toepasbaarheid as siftingsondersoek by hierdie vroeë swangerskapsduur moet nog
verder in detail ondersoek word.
Hoe uitvoerbaar dit is om die blootstelling aan ultraklankenergie te beperk deur
middel van 3D sonar is verder verken in ‘n longitudinale studie waarin standaard
neurosonografi ese vlakke (12) tydens die sonarondersoek met 2D, en daarna vanuit
opgebergde 3D sonar volumes verkry is. Hieruit het dit duidelik geword dat dit moontlik
is om fetale ventrikels (Hoofstuk 5) en kortikale ontwikkeling (Hoofstuk 4) met 3D
sonar met dieselfde akkuraatheid as met 2D te beoordeel, terwyl die tyd waarin die
fetus blootgestel word aan ultraklank, asook die totale ondersoektyd, beperk word
(Hoofstuk 4)
Verskeie publikasies het al duidelik aangetoon dat fetale kortikale ontwikkeling duidelik
met sonar afgebeeld kan word (13-16). Dit is egter nog moeilik om in praktyk toe te pas,
omdat die eerste verskyning van sulci and gyri beskryf word, eerder as die ontwikkeling
met die verloop van tyd. Nog ‘n beperking van die beskikbare literatuur is die gebrek
aan ‘n sistematiese beskrywing van fi siologiese asimmetrie, omdat meestal net die
distale hemisfeer goed sigbaar is met transabdominale sonar. ‘n Eenvoudige telsisteem
is in ons longitudinale studie ontwikkel om kortikale ontwikkeling te beskryf. Ons het
ook probeer om beide hemisfere af te beeld, en asimmetriese kortikale ontwikkeling
is in ‘n derde van fetusse tussen 24 en 28 weke aangetoon (Hoofstuk 4). Die intra- en
inter-waarnemer ooreenkoms van die telsisteem was goed. Longitudinale groeikurwes
is met mutivlak-analise vanuit die individuele groeikurwes bereken. Die volgende stap
is om die telsisteem prospektief te toets om te bepaal of dit nuttig is om fetusse met
malformasies van kortikale ontwikkeling te identifi seer.
Daar is ook min inligting oor die prevalensie van fi siologiese asimmetrie van die
laterale ventrikels beskikbaar, ondanks die feit dat die normale grootte van die fetale
ventrikels goed beskryf is. Die afkapwaarde van 10 mm van die atrium van die laterale
ventrikel op ‘n aksiale vlak is aanvanklik uit data van ‘n dwarssnit-studie bepaal en
word gebruik as afsnypunt vir ventrikulomegalie deur die hele swangerskap (12;17).
Ons het hierdie afsnypunt in ons longitudinale studie bevestig. Deur die midkoronale
vlak op 2D sonar te verkry en die gebruik van volume-kontras beeldvorming (‘n 3D
sonar modaliteit) van aksiale vlakke het die evaluasie van beide regter- en linker-
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laterale ventrikels vergemaklik. Ons het asimmetrie van die laterale ventrikels in tot
4% gevind. Dis is enersyds meer as wat vroeër in die literatuur by 0,2 tot 0,4% beskryf
word (18). Andersyds is dit aanmerklik minder as die postnatale insidensie van meer as
40% (19) (Hoofstuk 5). Dit sal interessant wees om ‘n groep kinders prospektief voor
en na geboorte te vervolg .
Longitudinale groeikurwes van die serebellêre volume is ook met mutivlak-analise
vanuit individuele fetale groeikurwes bereken. Die linker serebellêre hemisfeer was
betekenisvol groter as regs, veral voor 32 weke. Ons het twee metodes getoets om die
volume te bereken, naamlik die multiplanêre en VOCALTM tegniek. Albei het ’n goeie
intra- en inter-waarnemer betroubaarheid gehad, en soortgelyke waardes opgelewer.
Veral laat in die derde trimester het ons serebellêre volumes gevind wat groter was
as wat vantevore in Taiwanese (20;21) en Braziliese bevolkings beskryf is (22). Dit
weerspieël miskien ‘n verskil tussen die bevolkingsgroepe, of miskien ook ‘n verskil in
tegniek (Hoofstuk 6). Dit moet ook nog bepaal word of metings van die serebellêre
volume, eerder as ‘n een-dimensionele meting soos die transserebellêre diameter, van
groter waarde is om sindromiese (23) of verworwe (24) afwykings van die serebellum
te diagnoseer.
PATOLOGIE
Om te bepaal of prenatale beeldvorming by fetusse met spina bifi da van prognostiese
waarde is, het ons kinders met ‘n prenatale diagnose van spina bifi da tot vyf jaar
ouderdom (of sterfte) opgevolg. Die hoogte van die letsel en die grootte van die
hoofomtrek was volgens multivariant analise onafhanklik met sterfte geassosieerd.
Motoriese of verstandelike funksionering by vyf jaar leeftyd was nie verwant aan
enige sonografi ese bevinding nie. Die bepaling van die anatomiese letselhoogte was
akkuraat binne een werwelvlak in 50% van sonarondersoeke tussen 1997 en 2002, en
in 89% tussen 2006 en 2007 (p < 0.01). Alhoewel die akkuraatheid van sonarondersoek
dus verbeter het, kan motoriese funksie nie voorspel word nie omdat die funksionele
vlak van neurologiese uitval verskil van die anatomiese vlak (Hoofstuk 7).
Ons het ook die prognostiese waarde van Dopplermetings van die middel serebrale
arterie pulsatiliteits-indeks (mca PI) van fetusse met sentrale senustelselafwykings
ondersoek (Hoofstuk 8). In fetusse met abnormaliteite van die sentrale senustelsel, is
‘n verhoogde mca PI geassosieerd met ‘n verhoogde risiko op ‘n agterstand in neuro-
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ontwikkeling. Dit geld nie vir fetusse met spina bifi da of veelvuldige abnormaliteite
nie. ‘n Onverwagte bevinding was dat ‘n verhoogde mca PI wat later verminder
het, geassosieerd was met malformasies van kortikale ontwikkeling, mikrosefalie
of Westsindroom. Of dit verband hou met ‘n onderliggende oorsaak soos bloeding,
vaskulitis of ‘n vertraagde ontwikkeling van die arteriële bloedtoevoer, of ‘n toevallige
bevinding is, moet nog duidelik word.
‘n Skielike styging van die mca PI is gesien in fetusse met ‘n hoë risiko vir sterfte, veral
in fetusse met hidrosefalus. Dat ‘n styging in mca PI ‘n indikasie vir bevalling is, is dus
nie deur ons bevindings bevestig nie omdat dit dan al te laat is. ‘n Moontlike verklaring
hiervoor is dat die arteriële bloedtoevoer eers by ernstig verhoogde intrakraniële
drukke afneem, wat dui op ‘n ver gevorderde stadium van die siekte. ‘n Ander indeks
van arteriële vloei soos die transsistoliese tyd (25) of kenmerke van veneuse vloei (26)
sou miskien van groter waarde wees, maar sal prospektief getoets moet word.
Die aanleiding om ons ervaring met met sonar, MRI en multidissiplinêre besprekings
te evalueer, was ‘n geval van ‘n fetus met malformasies van kortikale ontwikkeling
na intra-uteriene transfusie vir ernstige anemie as gevolg van Parvovirus B19-infeksie
(Hoofstuk 9). Vir die evaluasie het ons die diagnostiese akkuraatheid van sonar, MRI
en multidissiplinêre besprekings voor en na MRI bepaal. Ons het ‘n retrospektiewe
kohort van pasiënte ondersoek by wie van 2000 tot 2008 ‘n MRI van die fetale sentrale
senustelsel verrig is. Ons het ook die akkuraatheid van standaard sonarondersoeke met
die van neurosonografi e vergelyk. Die diagnose van multidissiplinêre besprekings was
akkuraat in 62% voor en in 73% na MRI. Die diagnose was onveranderd in 23 van die
28 pasiënte. In vier pasiënte was die diagnose na MRI meer akkuraat, en in een minder
akkuraat.. Standaard sonarondersoeke was akkuraat in 42% en neurosonografi e
in 63% van pasiënte. Die hoogste diagnostiese akkuraatheid (78%) is verkry met ‘n
multidissiplinêre bespreking na neursonografi e en MRI (Hoofstuk 10). Die akkuraatheid
na MRI het nie verbeter in pasiënte met ‘n neuraalbuisdefek nie, en die grootste
verbetering is gesien in pasiënte met ‘n sonografi ese diagnose van ventrikulomegalie.
Van belang vir toekomstige navorsing na die nut van MR spektroskopie om die graad
van fetale asfi ksie te bepaal, is die bevinding dat die vrugwater laktaat:kreatinien-
verhouding ‘n goeie voorspeller van fetale laktaatasidemie is (Hoofstuk 11).
A
197
AANBEVELINGS EN TOEKOMSTIGE ONTWIKKELINGS
• Dit is moontlik om duidelike beelde van die ontwikkelende serebrale
ventrikelsisteem by agt weke swangerskap te verkry uit ‘n enkele 3D sonarvolume
met behulp van outomatiese volume-berekeningsagteware. Die waarde van
hierdie tegniek vir die diagnose van intra- en ekstrakraniële afwykings behoort
verder ondersoek te word
• Dit is moontlike om fetale kortikale ontwikkeling met ‘n eenvoudige telsisteem
te gradeer. Die telsisteem behoort verder evalueer te word om te bepaal of dit
nuttig is om fetale malformasies van kortikale ontwikkeling te diagnoseer.
• Dit is moontlik om die fetale blootstelling en totale ondersoekstyd te beperk
deur die gebruik van 3D sonografi e.
• Albei laterale ventrikels kan meestal met transabdominale eggografi e beoordeel
word deur die midkoronale vlak op 2D sonar te verkry en met die hulp van 3D
volumekontras.
• Asimmetrie is ‘n kenmerk van normale fetale breinontwikkeling en is
mees uitgesproke in kortikale ontwikkeling, en tot ‘n mindere mate in
ventrikelontwikkeling. Daar behoort ‘n groep fetusse voor en na geboorte
opgevolg te word om ‘n verklaring te vind vir die verskillende prevalensie van
asimmetrie van die brein gedurende swangerskap en postnataal.
• Die serebellêre volume kan met dieselfde betroubaarheid met beide VOCALTM
en multiplanêre metings bepaal word. Die waarde van die gebruik van
volumemetings om abnormaliteite van serebellêre ontwikkeling te diagnoseer
behoort prospektief bepaal te word.
• Die fetus met ‘n vermoedelike afwyking van die sentrale senustelsel moet
multidissiplinêr bespreek word. As fetale neurosonografi e onvoldoende inligting
verskaf, moet ‘n MRI gedoen word.
• In fetusse met spina bifi da kan die oorlewing akkuraat met sonar voorspel word,
maar toekomstige verstandelike of motoriese funksie nie.
• ‘n Verhoogde mca PI in ‘n fetus met ‘n sentrale senustelselabnormaliteit is
geassosieerd met ‘n verhoogde risiko op sterfte of abnormale neurologiese
ontwikkeling. Die evaluasie van die fetale serebrale sirkulasie verdien verdere
navorsing; enersyds om te bepaal of dit van waarde is om kortikale malformasies
te diagnoseer, en andersyds om te bepaal wat die optimale tyd van verlossing
van ‘n fetus met hidrosefalus is. 3D sonartegnieke soos vaskularisasie en vloei-
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Doppler indekse (27) en MRI-tegnieke om areas van hiper- of onderperfusie in
die fetale brein te visualiseer of suurstof- of pH-vlakke te bepaal (28;29) kan
hierby van waarde wees.
• Fetale laktaatasidemie (as mate van asfi ksie) kan voorspel word deur die laktaat-
kreatinien-verhouding in vrugwater. Dit moet nog bepaal word hoe om dit non-
invasief met MR spektroskopie te meet (30;31).
• Die veiligheid in swangerskap van MRI-toerusting met veldsterktes sterker as
die huidig aanvaarde 1,5 Tesla moet eers bevestig word voordat dit prenataal
gebruik kan word.
• Dit is ook heel moontlik dat evaluasie van fetale bewegings op sonar en MRI
in kliniese praktyk gebruik sal word om nie net ‘n anatomiese en strukturele
diagnose te maak nie, maar ‘n volle fetale neurologiese ondersoek te verrig
(32).
• Daar is nog behoefte aan verdere prospektiewe, goed beplande evaluasie
van die waarde van sonar en MRI in die diagnose van fetale sentrale
senustelselafwykings.
199
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ACKNOWLEDGMENTS
To the fi rst author of my life: thank you, Jesus, for all the challenging chapters, and the
peaceful paragraphs in between;
Aan Ronel, Wilma en Hantie: dankie dat julle nou al meer as helfte, of julle hele lewe,
uithou met my terwyl ek probeer om te “work quietly and humbly to realize my
delusions of grandeur.” Julle het die kosbare vermoë om terselfdertyd my geloof in
waarmee ek besig is in stand, my voete op die aarde, en die koffi ebekers vol te hou.
Spesiaal dankie ook Ronel, vir die voorblad en die afskaal van sosiale aktiwiteite (veral
laasgenoemde was sekerlik nie altyd maklik nie), Wilma, vir die musiek, Hantie, vir die
uitnodigings.
Aan al my leermeesters en mentore vir hulle rol om my professioneel te (probeer)
ontwikkel: van die tyd as student toe Jan van der Merwe en W.B.D.I. Evans letterlik
of fi guurlik kop en skouers bo vele ander uitgestaan het. Frieda Coetzee en Yvette
Mouton, julle het my in my huisdokterjaar nie net verloskunde geleer nie, maar
ook om verloskunde lief te hê. Kobie van der Merwe: my lewe is onmeetbaar ryker
danksy ons families se interaksie deur die generasies heen. Al die ander konsultante
van my Tygerberg-tyd: Thinus Kruger, Bob Pattinson, Pohl de Villiers, Hein Odendaal,
Wilhelm Steyn, Gerhard Theron, Bert Schaetzing, Karin Norman vir julle toewyding en
‘n ongeloofl ike vermoë om eerstewêreldstandaarde in die derde wêreld te handhaaf
en natuurlik Linnie Muller vir die fondasie van my sonarvermoëns. Peter Soothill you
have always been there in the background and far too seldom in the foreground. Jan
Deprest voor onkreukbare integriteit en vriendelijke toegankelijkheid. My ex-Kalafong
kollegas: Bob (weer!), Graham Howarth, Gerald Mantel, Eric de Jonge, Henri de Wet;
duidelik het ons daar ‘n internasionale perspektief ontwikkel. Eddie Mhlanga, thanks
for speaking grace over Kalafong. Ernest & Patricia, you helped us to discover where
friendship really comes from. (That was worth going to Hull for!) Peter Brugger, for
your infectious enthousiasm for digging deeper into fetal diagnosis.
En vooral natuurlijk iedereen die dit proefschrift mogelijk maakte: Gerard, je
enthousiasme, optimisme en ervaring waren de benzine voor de motor; Linda, voor je
bereidheid om altijd weer mee te kijken en mee te denken, Rob, Floris en Philip, voor
jullie pragmatisme, realisme, hulp en nuchterheid (vooral om mij te leren dat tussen de
zwart en wit van echo vele grijze nuances liggen); Edu, je heb echt een leeuwenaandeel
gehad aan alles van statistieken tot punctuatie, met ook nog een hele scheut fi losofi e
ertussen! It all really started with the impossible review: a review with both an MRI
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and ultrasound expert as co-authors: Daniela and Gustavo, thank you for making this
all possible: not only the article, but for the amazing work you both put in to strive for
perfection in fetal imaging. Daniela, thank you also for participating in the assessment
commission, not to mention the symposium. It proves again: if you need someone to
help, fi nd someone who is already too busy. Ook dank aan de andere medeauteurs:
Wendy, Marjet, Sylwia, Manon, Sanne, Marc, Jaime, Timo, Lieve, Malgosia, Dick en Ron:
ieder van jullie heeft geholpen om het bootje in veiligheid te brengen (al voelde het
soms op dekstoelen schikken op de Titanic!) Hein, dank voor je grote hulp met het
Nederlands, het gaat nog om Nederlands op zijn Afrikaans te praten, maar te schrijven
helemaal niet.
Voor Nils en je collegae laboranten, dank voor alle MRI’s, en het helpen uitzoeken wat
kan en wat niet. Ook aan Helen en Jeroen: de spectroscopieën zijn niet gelukt, en wat
twee proefschriften zou moeten zijn, is uiteindelijk een artikel geworden, maar aan
jullie enthousiasme ligt het niet! Dank aan alle echoscopisten voor alle medewerking,
in de bijzonder om proefpersonen te werven. Een heel groot woord van dank aan alle
proefpersonen. Zonder jullie getrouwheid was de hele afdeling over fysiologie niet
mogelijk. Mag alle kleine proefpersoontjes die onwetend meededen, jullie nog veel
vreugde verschaffen! Dank ook aan de andere ouders voor toestemming tot publicatie.
Mag het goed blijven gaan!
En dan mijn collegae in het UMC Utrecht: Gerard, Hein, Martijn, Lieve, Carla, Philip, Jan,
Anneke, Wendy, Michelle, Monique: voor alle samenwerking en collegialiteit, voor tijd
vrij om dit proefschrift mogelijk te maken: de helft van jullie ken ik niet half zo goed
als ik zou willen; en van minder dan de helft van jullie houd ik half zoveel als jullie
verdienen. Bertina, Ans, Lot; jullie altijd vriendelijke en effi ciënte ondersteuning was
op alle verschillende stadia onmisbaar.
Dankie, familie en vriende, wat ons moes mis terwyl ek na Nederland gekom het vir
verskeie redes, waarvan hierdie proefskrif ’n groot deel uitgemaak het. Thank you, all
my friends in Crossroads, especially the life group: Bas, Brigitte, Eric, Gert-Jan, Lillian,
Linda, Marco, Nicole, Petra, Rebecca, Seantel, Sylvie, thanks for all your prayers and
support.
Dan aan de paranimfen Wendy en Corstiaan, voor jullie vermogen om te regelen, te
ondersteunen, noch eens weer een extra mijl te lopen, en niet alleen collegae maar
vrienden te zijn: heel erg bedankt.
To all, aan almal en iedereen: thank you, baie dankie, dank je wel, tov toda, grüß Gott.
203
CURRICULUM VITAE
The author of this thesis was born on the 27th April 1963 in Potchefstroom, South
Africa. He matriculated at the D.F. Malan High School, Bellville in 1980. Medical studies
at the University of Pretoria led to the degree MBChB cum laude in 1986. After an
internship in Boksburg-Benoni Hospital and national service (most of which was
spent as medical offi cer in Tsumeb, Namibia), he moved back to Bellville to study
gynaecology at the Tygerberg Hospital of the University of Stellenbosch. This led to the
degree MMed (O&G) and FCOG (SA) in 1993. After a year as visiting registrar in the Hull
Maternity Hospital in Kingston-upon-Hull in the UK, he took up a post as consultant
gynaecologist at the Kalafong Hospital of the University of Pretoria. From 1998 to 2003
he ran a private maternal and fetal medicine practice in Sandton, Johannesburg, in
the process introducing laser therapy for twin-twin transfusion in South Africa. Since
January 2004 he has been working as obstetrician and latterly perinatologist in the
University Medical Centre Utrecht.
He married Ronel (néé Nel) on the 5th April 1987 and they have two children: Wilma,
born in 1991, and Hantie, born in 1995.
De auteur van dit proefschrift werd geboren op 27 april 1963 in Potchefstroom, Zuid-
Afrika. In 1980 behaalde hij zijn eindexamen gymnasium aan de D. F. Malan middelbare
school in Bellville. Daarna volgde hij zijn geneeskunde studie aan de Universiteit van
Pretoria wat leidde tot een cum laude doctoraal in 1986. Na een periode als AGNIO
(assistent geneeskunde niet in opleiding) gewerkt te hebben in het Boksburg-Benoni
Hospital en het vervullen van de nationale dienstplicht (waarvan de meeste tijd
doorgebracht werd als basisarts in Tsumeb, Namibië), verhuisde hij terug naar Bellville,
waar hij startte met zijn opleiding tot gynaecoloog in het Tygerberg Hospital aan de
universiteit van Stellenbosch. Deze werd in 1993 afgerond. Na een fellowship van
een jaar in het Hull Maternity Hospital in Kingston-upon-Hull te Engeland, was hij
werkzaam als gynaecoloog in het Kalafong Hospital (universiteit van Pretoria). Van
1998 tot 2003 had hij een privépraktijk voor perinatologie in Sandton, Johannesburg. In
deze periode introduceerde hij de lasertherapie voor behandeling van het transfuseur-
transfusée syndroom bij tweelingen in Zuid-Afrika. Sinds januari 2004 versterkt hij
de staf verloskunde (eerst als obstetricus, later als perinatoloog) van het Universitair
Medisch Centrum Utrecht. Hij is getrouwd met Ronel Nel en samen hebben zij twee
kinderen; Wilma, geboren in 1991, en Hantie, geboren in 1995.
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LIST OF PUBLICATIONS
First author
(1) Pistorius LR, Page-Christiaens GC. First-trimester septated cystic hygroma:
prevalence, natural history, and pediatric outcome. Obstet Gynecol 2005
Dec;106(6):1415-6.
(2) Pistorius LR, Hartman CR. Sonographic diagnosis of subacute puerperal uterine
inversion. J Obstet Gynaecol 1998 Sep;18(5):483.
(3) Pistorius L. Appalling ultrasound knowledge? S Afr Med J 2001 Apr;91(4):272-3.
(4) Pistorius LR, Howarth GR. Failure of amniotic septostomy in the management of
3 subsequent cases of severe previable twin-twin transfusion syndrome. Fetal
Diagn Ther 1999 Nov;14(6):337-40.
(5) Pistorius LR. Routine ultrasound dating has not been shown to be more accurate
than the calendar method. Br J Obstet Gynaecol 1998 Sep;105(9):1039-40.
(6) Pistorius LR, Pattinson RC, Howarth GR, Funk M. Cost-effective on-site screening
for anaemia in pregnancy. S Afr Med J 1997 Aug;87(8):1024.
(7) Pistorius LR, Kruger TF, de VA, van der Merwe JP. A comparative study using
prepared and unprepared frozen semen for donor insemination. Arch Androl
1996 Jan;36(1):81-6.
(8) Pistorius LR, Funk M, Pattinson RC, Howarth GR. Screening for anemia in
pregnancy with copper sulfate densitometry. Int J Gynaecol Obstet 1996
Jan;52(1):33-6.
(9) Pistorius LR, Sweidan WH, Purdie DW, Steel SA, Howey S, Bennett JR, et al.
Coeliac disease and bone mineral density in adult female patients. Gut 1995
Nov;37(5):639-42.
(10) Pistorius LR, Christianson AL. Screening for Down syndrome. S Afr Med J 1995
Sep;85(9):934-6.
(11) Pistorius LR, Kruger TF, van der Merwe JP. [Artifi cial insemination with donor
semen]. S Afr Med J 1993 Jun;83(6):381-2.
(12) Pistorius LR, Pattinson RC. Rational antenatal care. S Afr J Epidemiol Infect
1995;10:66-7.
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Co-author
(1) Hack KE, Kaandorp JJ, Derks JB, Elias SG, Pistorius L, Visser GH. The value
of umbilical artery Doppler velocimetry in the antenatal surveillance of
uncomplicated monochorionic twin pregnancies. Ultrasound Obstet Gynecol
2008 Jun;31(6):662-8.
(2) Kuchenbecker WK, Pistorius LR, Pattinson RC. The tap test--an accurate fi rst-line
test for fetal lung maturity testing. S Afr Med J 2002 Sep;92(9):720-3.
(3) Jeffery BS, Tsuari M, Pistorius LR, Makin J, Pattinson RC. The impact of a pregnancy
confi rmation clinic on the commencement of antenatal care. S Afr Med J 2000
Feb;90(2):153-6.
(4) Howarth GR, Pistorius LR, Combrink W, Hartman C. Management of early onset
severe twin-twin transfusion syndrome in the absence of fetoscopic equipment
by exteriorisation, ligation and replacement of the umbilical cord of the sacrifi ced
twin. S Afr Med J 1998 Mar;88(3):286.
(5) Howarth GR, Pistorius L, Mantel G, Funk M, Pattinson RC. Induction of labour at
term--misoprostol, effi cacy, economics and ethics. S Afr Med J 1996 Sep;86(9
Suppl):1174, 1176.
(6) Pattinson RC, de JE, Pistorius LR, Howarth GR, de WH, Bremer P, et al. Practical
application of data obtained from a Perinatal Problem Identifi cation Programme.
S Afr Med J 1995 Mar;85(3):131-2.
(7) Funk M, Pistorius LR, Pattinson RC. Antenatal screening for bacterial vaginosis
using the amine test. S Afr J Epidemiol Infect 1996;11:74-6.
(8) Howarth GR, Funk M, Steytler P, Pistorius LR, Makin J, Pattinson RC. A randomised
controlled trial comparing vaginally administered misoprostol to vaginal
dinoprostone gel in labour induction. J Obstet Gynecol 1996;16(6):474-8.
Chapters in books
(1) Pistorius LR. Late reproductive failure. In: Van der Spuy Z, Anthony J, editors.
Handbook of obstetrics and gynaecology.Cape Town: Oxford University Press;
2002. p. 172-6.
(2) Pistorius LR. Hypertensive conditons. In: de Kock J, van der Walt C, editors.
Maternal and newborn care.Lansdowne: Juta; 2004. p. 20-1-20-11.
(3) Pistorius LR. The compromised fetus. In: de Kock J, van der Walt C, editors.
Maternal & newborn care.Lansdowne: Juta; 2002. p. 24-1-24-20.
207
(4) Pistorius LR. Prenatale screening. In: Bakker J, van den Boogaard MHWA, de
Lange B, Rommes JH, van der Voort PHJ, editors. Intensive care capita selecta
2007.Utrecht: Uitgeverij Venticare; 2007. p. 107-16.
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Wat ek geskrywe het,
het ek geskrywe.
Pontius Pilatus