42     SA JOURNAL OF RADIOLOGY  •  June 2011  

CASE REPORT

Clinical presentation
A 19-year-old woman (para 1, gravida 1) delivered a baby girl at 36 
weeks’ gestational age. Antenatal blood test results showed that the 
mother was Rhesus positive, the rapid plasma reagin (RPR) for syphilis 
was negative, and she was HIV-positive (she was receiving treatment). 
There were no other significant findings in the maternal history. There 
was no record of antenatal ultrasound findings. The baby was delivered 
by normal vaginal delivery, with a birth weight of 2 670 g and Apgar 
scores of 5/10 at 1 minute and 7/10 at 5 minutes. The baby had an initial 
heart rate of 86 beats per minute, was pale and cyanosed (respiratory rate 
of 50 breaths per minute), with oxygen saturation levels of 88 - 92%. The 
baby was resuscitated, after which her pulse and saturation improved.

Examination revealed cardiomegaly with the apex in the sixth 
intercostal space in the anterior axillary line. A pansystolic murmur 
and a palpable second heart sound (P2) was present on auscultation. 
Chest radiographs demonstrated significant cardiac enlargement with 
signs of congestive cardiac failure (Fig. 1). This prompted cardiac 
ultrasound which demonstrated right atrial dilatation, an inter-atrial 
septal aneurysm (Fig. 2) with a right to left shunt. There was pulmonary 
hypertension with a large tricuspid incompetence and a dilated right 
ventricle. A patent ductus arteriosus (PDA) with right to left shunt 
was also visualised. The degree of right to left shunt suggested a 
possible ‘steal phenomenon’ owing to an arterio-venous malformation 
(AVM). In the search for a high-volume extra-cardiac shunt, cerebral 
ultrasound revealed a vein of Galen malformation (VGM) with massive 
hydrocephalus with no normal brain parenchyma (Fig. 3). Contrast-
enhanced computed tomography confirmed the ultrasound findings, 
showing dilated, tortuous contrast enhancing vessels, a dilated VGM 
and massive hydrocephalus with no visualised brain parenchyma (Fig. 4).

The baby died 2 days later and underwent postmortem. The findings 
confirmed the presence of a large VGM, massive hydrocephalus and no 
normal brain tissue identified macroscopically. There was hypertrophy 
of the left atrium (LA) and right myocardium, and right heart failure 

A severe case of astrogliosis and 
encephalomalacia in a neonate with a  
massive vein of Galen malformation (VGM)
F Ismail, FC Rad (D)
N Khan, FC Rad (D)
I van de Werke, FRCR
R Ahmed, MB ChB
Department of Radiology, Kalafong Hospital and University of Pretoria

Corresponding author: F Ismail (drfismail@yahoo.com)

Fig. 1. Frontal radiograph of the patient’s chest shows massive global 
cardiomegaly.

Fig. 2. Four-chamber cardiac ultrasound demonstrates enlargement of the 
RA with aneurysm of the ASD. Doppler studies (not shown) showed right to 
left shunting of blood.

Aneurysm of the ASD

LA
RA

Abstract
Vein of Galen malformations (VGMs) are rare anomalies of 
intracranial circulation that constitute 1% of all intracranial vascular 
malformations. We describe a case of severe encephalomalacia 
associated with a VGM, which has not been previously described. 



SA JOURNAL OF RADIOLOGY  •  June 2011     43

CASE REPORT

owing to the right to left shunt. An atrial septal defect (ASD) and PDA 
were also noted. No other anomalies were found.

Discussion
VGMs are rare anomalies of intracranial circulation that constitute 1% of 
all intracranial vascular malformations.1 They represent 30% of vascular 

malformations in the paediatric age group.1 The first description 
of a possible VGM was reported by Steinhel in 1895.2 Raybaud and 
co-workers were the first to recognise the ectatic venous structure 
that is characteristically seen in these lesions representing the median 
prosencephalic vein (MPV) and not the vein of Galen itself.1 The MPV is 
responsible for drainage of the choroid plexus prior to the development 

Fig. 3. Coronal cranial ultrasound demonstrates enlarged central vein of Galen with increased blood flow on Doppler study (left) and massive hydrocephalus with 
no brain parenchyma.

VGM
Hydrocephalus

Fig. 4. Axial non-enhanced and enhanced computed tomography of the brain demonstrates dilated, tortuous vessels draining into a large vein of Galen with 
secondary hydrocephalus and astrogliosis with no brain parenchyma.



44     SA JOURNAL OF RADIOLOGY  •  June 2011  

CASE REPORT

of the internal cerebral veins, during embryogenesis, prior to the 11th 
week of gestation.1

VGMs form during the late somite stages of the 4th week of embryonic 
life. The malformation consists of persistent primitive connections 
between the arteries and veins that develop from the sinusoidal vascular 
network of the telencephalon.3 Absence of capillaries results in a low-
resistance shunt, which results in rapid arterio-venous shunt within the 
malformation.3 This results in blood flow away from the parenchyma, 
resulting in hypoperfusion, with consequent astrogliosis and atrophy.3 
High pressure and shear stresses from turbulent flow may result in the 
formation of arterial aneurysms, stenosis or occlusion in the draining 
veins, particularly where the vein enters a dural sinus.3

More recently, anatomical and embryological evidence has allowed 
VGMs to be categorised as specific choroidal type or mural type.4,5 

There is a relationship between the choroidal type of malformation 
and heart failure in neonates, and it is more severe in presentation than 
the mural type, as was the case with our patient.4-6 The mural type is 
characterised by fewer (1 - 4) large-calibre connections that drain into 
the wall of the MPV.5,6 There is also a distinction between the VGM 
and the Vein of Galen aneurysmal dilation (VGAD) which are AVMs 
localised in the subpial space, which drain into a tributary of the vein 
of Galen, resulting in overload and dilatation.4,5 The vein of Galen varix 
refers to a varicose dilation of the vein of Galen without an underlying 
arterio-venous shunt.4

Increased venous return to the right heart promotes shunting of 
blood through a patent foramen ovale and ductus venosis. This leads to 
cyanosis and often refractory congestive cardiac failure.1,7

Neurological manifestations occur as a direct result of cerebral 
venous hypertension that prevents drainage of cerebrospinal fluid (CSF) 
via the medullary veins. Transependymal drainage of CSF, followed by 
medullary venous drainage, supervenes as arachnoid granulations are 
not fully matured in the neonate.1,4 This in turn causes chronic hypoxia, 
ischaemia, hydrocephalus and cerebral oedema.1 Chronic hypoxia 
results in progressive cerebral parenchymal damage.1 Cerebral damage 
can be severe, as cases of hydranencephaly with arterial and venous 
malformations have been reported.7 This was the case in our patient, 
who developed severe leucomalacia and astrogliosis owing to chronic 
intra-uterine hypoxia.

Conclusion
VGMs are rare anomalies that may cause secondary neurological 
abnormalities. The degree of hypoxic damage and hydrocephalus, as 
seen in our case, has not been previously documented.

1. Gupta AK, Varma DR. Vein of Galen Malformations: Review. Neurology India 2004;52:43-53.
2.  Lasjaunias PL, Chng SM, Sachet M, Alvarez H, Rodesch G, Garcia-Monaco R. The management of vein 

of Galen aneurysmal malformations. Neurosurgery 2006;59(5):184-194.
3.  Barkovich AJ. Paediatric Neuroimaging. 4th ed. Baltimore, USA: Lippincott Williams and Wilkins, 

2005:873-878.
4.  Alvarez H, Garcia Monaco R, Rodesch G, Sachet M, Krings T, Lasjaunias P. Vein of Galen aneurysmal 

malformations. Neuroimaging Clin N Am 2007;17:189-206.
5.  Du Toit J, Bam JA. Mngomezulu V. Endovascular treatment of vein of Galen aneurysmal malformation. 

South African Journal of Radiology 2009;13:12-17.
6.  Osborn A, Blaser SI, Salzman KL, et al. Diagnostic Imaging: Brain. Salt Lake City, USA: Amirsys, 2007:12-14.
7.  Stevenson DA, Hart BL, Clericuzio CL. Hydranencephaly in an infant with vascular malformations. Am J 

Med Genet 2001;104:295-298.