FETAL MRI.html
Fetal MRI for characterising a variety of posterior fossa anomalies suspected on 3rd trimester ultrasound examination – a short series of 4 cases
Amaresh Indravadan Ranchod, MB BCh, FCRad (D)
Savvas Andronikou, MB BCh, FCRad, FRCR (Lond), PhD
Mala Modi, MB BCh, FCRad (D)
Department of Diagnostic Radiology, University of the Witwatersrand, Johannesburg
Corresponding author: A Ranchod (airanchod@gmail.com)
Abstract
Fetal
MRI is increasingly being used to more accurately assess abnormalities
detected on screening ultrasound. The procedure is more pertinent when
the initial ultrasound is done late in the third trimester and when the
abnormality involves the posterior fossa of the brain. Four cases with
a variety of unusual posterior fossa anomalies are presented.
Introduction
Prenatal ultrasound (US) is the investigation of
choice when screening for fetal abnormalities. When an intracranial
abnormality is detected on US specifically within the posterior fossa,
a fetal MRI is the next investigation of choice, to accurately
characterise and diagnose the abnormality. In the developing world,
patients often present as unbooked pregnancies in the third trimester.
At this late stage of pregnancy, the sensitivity of US decreases owing
to ossification of the cranium and the relative size of the fetus
compared with the volume of liquor, making fetal MRI more valuable.
We present four instances where posterior fossa
abnormalities were suspected on third trimester antenatal US. Fetal MRI
scans diagnosed four specific posterior fossa abnormalities including a
Dandy-Walker malformation, a Joubert syndrome and related disorder, an
occipital encephalocoele, and an occipital bone lesion.
Case reports
Antenatal US was performed for the first time
during the third trimester in all the cases, owing to unbooked
pregnancy, which is common in developing countries with poorly
distributed resources. MRI scans on all patients were performed at a
referral unit on a 1.5 Tesla machine (General Electric Signa Excite,
Michigan, USA). Routine sequences included T2, T2* and T1.
Case 1
A 28-year-old woman, 32 weeks pregnant, presented
to the antenatal clinic and was referred for antenatal US for suspected
polyhydramnios. Antenatal US demonstrated polyhydramnios, an enlarged
cisterna magna (>10 mm), a cavum septum pellucidum, and retarded
long bone growth (at 5th percentile). There was no echogenic vermis
visible but the lateral ventricles (7 mm) and aqueduct were normal.
There were no features of spina bifida.
Fetal MRI (Fig. 1) confirmed the Dandy-Walker
malformation on the basis of an absent vermis, cystic dilatation of the
fourth ventricle, an enlarged posterior fossa, upward displacement of
the torcula and splayed hypoplastic cerebellar hemispheres.1
There was no hydrocephalus, corpus callosum agenesis, a normal pontine
bulge, no intracranial cysts or spinal abnormalities. The patient was
counselled and the child was delivered by caesarian section and found
to be a trisomy 18. The child did not survive.
Case 2
A 30-year-old woman, 39 weeks pregnant, presented
for a late third trimester US with a history of decreased fetal
movements. Antenatal US demonstrated a possible occipital
encephalocoele. The scan was considered suboptimal in view of the
advanced gestational age.
Fetal MRI (Fig. 2) confirmed the encephalocoele by
demonstrating continuity with the intracranial compartment and
demonstrating brain tissue extracranially. The occipital bony defect of
3.6 cm was also demonstrated. There was no associated hydrocephalus,
brain atrophy, spinal abnormality or other anomaly.
The child was delivered by caesarean section a week later and
proved to be
blind and spastic, and the prognosis was poor. Neurosurgical intervention was considered unfeasible.
Case 3
A 31-year-old woman who was 31 weeks pregnant
presented at the antenatal clinic for US; this demonstrated
hydrocephalus and an abnormal posterior fossa but did not provide a
more specific diagnosis. On fetal MRI (Fig. 3), a diagnosis of Joubert
syndrome and related disorders2
was made by the pathognomic finding of a ‘molar tooth’ sign
at the ponto-mesencephalic junction, representing vermian aplasia and
stretched superior cerebellar peduncles with a deep interpeduncular
fossa.
Case 4
A 37-year-old woman presented to the antenatal
clinic at 28 weeks’ gestation. Owing to her advanced maternal
age, she was referred for an antenatal US. This demonstrated a cystic
structure in the posterior fossa and possible dysplasia of the vermis.
A Dandy-Walker complex was considered.
Fetal MRI (Fig. 4) showed a well-defined
extra-axial lesion within the occipital bone. The vermis, cerebellar
hemispheres and fourth ventricle were normal, therefore excluding a
Dandy-Walker complex. The lesion was reported as either a haemangioma
or a cyst of the occipital bone.
Discussion
MRI is increasingly used to evaluate the fetal
brain, particularly when an abnormality has been detected on prenatal
US or when a fetus is at increased risk for neurodevelopmental
anomalies. Fetal MRI has several advantages over US. It has higher
contrast resolution, is not affected by the shadowing from the
calvarium or by low amniotic fluid volume, allows a larger field of
view and can easily be performed using ultrafast T2-W sequences,3
making it more useful than US in late pregnancy. Parents also better
understand the images and therefore counselling is made easier.
Counselling of parents is important for obtaining appropriate knowledge
of the potential outcomes in the neonate and child.4
Disadvantages include limitations owing to fetal motion, poorer spatial
resolution than US, cost, availability and lack of expertise. One of
the primary reasons for performing fetal imaging is to gather accurate
information about fetal structure on which to base reliable counseling.
This parental counseling is important for making informed decisions
regarding future management of the pregnancy, regarding offering
termination, planning delivery, post-natal prognosis and genetic
counseling and testing.4
In terms of the posterior fossa specifically,
fetal US has limited specificity, and false-positive diagnoses are well
described. A recent study showed a 33% false-positive rate for prenatal
US compared with MRI.4
The same study, however, also highlighted the limitations in both
sensitivity and specificity of fetal MRI compared with postnatal MRI.
In cases of posterior fossa anomalies, only 60% of prenatal MRI
diagnoses are confirmed postnatally. One of the main factors
contributing to this low sensitivity and specificity is the poor
spatial resolution for small structures such as the brainstem and
vermis, especially in early gestation.4
This emphasises the need to perform fetal MRI studies after
22weeks’ gestation and the need for postnatal MRI to correlate
fetal MRI findings.
The two cases of Dandy-Walker complex and Joubert
syndrome and related disorders highlight the superiority of MRI in
evaluating for vermian dysplasia or aplasia, the shape of the fourth
ventricle, the insertion of the tentorium cerebelli and the presence of
the pontine bulge. It is also essential to look for associated cerebral
and extra-cerebral abnormalities when a posterior fossa anomaly has
been detected; this additional information is more accurately obtained
with fetal MRI. Associated migrational abnormalities and midline
anomalies specifically, are more thoroughly assessed on MRI.5
A posterior fossa cyst can severely hamper evaluation of the posterior
fossa structures on ultrasound, as demonstrated in the fetus with the
occipital encephalocele.
Conclusion
Our cases have highlighted the superiority of MRI
over antenatal US in diagnosing both common and unusual posterior fossa
abnormalities. The value of MRI is even more pertinent in developing
countries where third trimester unbooked antenatal presentations are
common; one should have a low threshold for performing MRI at referral
institutions in such patients.
1. Klein O, Pierre-Khan A, Boddaert N, Parisot D, Brunelle F. Dandy
Walker malformation: prenatal diagnosis and prognosis. Childs Nerv Syst
2003;19:484-489.
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brain magnetic resonance imaging leading to the prenatal diagnosis of
Joubert syndrome and related disorders. J Child Neurol 2006;21:320-324.
2. Fluss J, Blaser S, Chitayat D, et al. Molar tooth sign in fetal
brain magnetic resonance imaging leading to the prenatal diagnosis of
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3. Glenn OA. MR imaging of the fetal brain. Pediatr Radiol 2010;40:68-81.
4. Limperopoulos C, Robertson RL, Khwaja, et al. How accurately does
current fetal imaging identify posterior fossa anomalies? Am J
Roentgenol 2008;190:1637-1643.
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current fetal imaging identify posterior fossa anomalies? Am J
Roentgenol 2008;190:1637-1643.
5. Pugash D, Brugger PC, Bettelheim D, Prayer D. Prenatal ultrasound
and fetal MRI: The comparative value of each modality in prenatal
diagnosis. Eur J Radiol 2008;68:214-226.
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Fig. 1. Case 1: Axial fetal MRI: Splayed hypoplastic
cerebellar lobes, and an enlarged cisterna magna and vermian agenesis
consistent with a Dandy-Walker complex.
Fig. 2. Case 2: Axial fetal MRI: An occipital
defect(long arrow) with large encephalocoele containing cerebellar
tissue (arrow head) is demonstrated.
Fig. 3. Case 3: Axial fetal MRI: ‘Molar tooth’ sign consistent with Joubert syndrome and related disorders.
Fig. 4. Case 4: Axial fetal MRI: Well-defined
extra-axial lesion situated within the occipital bone. The intracranial
posterior fossa structures are normal.