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294          Shrestha et al          Giant Cavernous Malformation in the child 

 
 
 

Giant Cavernous Malformation in the child. Case presentation   

Rajendra Shrestha1, Reeka Pradhan2, You Chao1 

1Department of neurosurgery, West China Hospital, Sichuan University 
2International Medical School, Tianjin Medical University, China 

 

Abstract 
Cerebral cavernous malformations 

(CCMs) are rare lesions that occurs 5 to 
13% of all intracranial vascular 
malformations, develop in 0.02-0.13% of 
the population. Extra axial cavernous 
Malformations are even more rare and 
estimated to be 0.4 to 2% of all the intra 
cranial cavernous hemangiomas. CCMs 
that are greater than six cm in size have 
been described as “giant” in the literature. 
We report ten year-old male who presented 
with right lower limb weakness and 
recurrent seizure disorder. The computed 
tomography and the magnetic resonance 
imaging scans demonstrated giant vascular 
malformation (10CM x 8CM x 6CM) on 
left parietal lobe. Surgical excision of a giant 
cavernous malformation (GCM) was 
performed with good surgical skills. To the 
best of our knowledge, such large GCMs 
are extremely rare lesion seen in 
neurosurgical practice. 

Key words: cavernous malformation, 
cavernoma, child, surgery 

Introduction 
The cavernous malformation (CM), also 

known as cavernous hemangioma, 
cavernoma, angioma and cavernous 
angioma, a well circumscribed, benign 
vascular hamartoma consisting of irregular 
thick and thin walled sinusoidal vascular 
channels located within the brain but 

lacking intervening neural parenchyma, 
large feeding arteries or large draining 
veins. Even though there are many names 
for this phenomenon in world literature, 
most of these lesion are small and only 
become clinically significant when they 
induce seizures, hemorrhage or 
neurological deficit (2, 7). These lesions 
have been diagnosed more frequently in the 
pediatric population. We report a case of 
giant cavernous malformation (GCMs) 
(10CM x 8CM x 6CM) associated with 
seizure and hemiparesis which, according 
to the best of our knowledge, has not been 
documented previously in the literature. 

Case Report 
A ten year-old-male presented with right 

lower limb weakness for five years. He was 
diagnosed with a case of vascular 
malformation in local hospital a couple of 
years back but was denied surgical 
intervention due to fearfulness. He had 
developed recurrent seizure over the course 
of two months and referred to our hospital 
for further management. On admission, 
patient vitals and parameter were within 
normal. Neurological examination revealed 
that his right lower leg had grade 4 Medical 
Research Council (MRC). His upper limbs 
were normal. Bladder and bowel function 
were not affected. Computed tomography 
(CT) scan revealed mixed density lesion on 
left parietal region (figure 2A).  



 
 
 

Romanian Neurosurgery (2012) XIX 4: 294 – 298          295 

 
 
 

 
A 

 
B 

Figure 1 Axial image T1 (A) and T2 (B) - weighted 
MRI showing GCMs a mixed signal mass with areas 

of T2 hypo-intensities suggestive of haemosidren 
and/or calcification 

The magnetic resonance imaging (MRI) 
scans demonstrated vascular malformation 
on left parietal lobe (figure 1A, B). DSA did 
not illustrate any lesion (figure 2B). After 
admission, left temporo-parietal craniotomy 
was done and it was found that the dura 
was not tense, with no signs of a high 
intracranial pressure as there was no 
outward brain swelling.  

 
A 

 
B 

Figure 2 (A) Computed tomography (CT) scanning 
showing a mixed density lesion in the left parieto-

temporal region (B) Cerebral Angiogram of the left 
carotid artery, no evidence of lesion 

After opening dura, 10cm x 8cm x cm 
blue-purple colored mulberry-like lesion 
tumor down to reach the lateral ventricle 
was revealed (Figure 4A). Tumors and 
brain tissue along the border excised and 
maintained hemostasis carefully. A 
complete resection tumor was performed 
without complication and sent for 
histopathological examination. Post 



 
 
 
296          Shrestha et al          Giant Cavernous Malformation in the child 

 
 
 

operative event was uneventful and HPE 
revealed Cavernous malformation (figure 
4B). And patient transferred to 
rehabilitation centre. Patient did not notice 
seizure and also good recover in his right 
lower limb after one month of follow up 
CT scan (figure 3). 

 

 
Figure 3 After one month of follow-up, plain CT 
scan showing complete excision of the giant CCM 

 

 
A 

 
B 

Figure 4 (A) Per-operative picture showing GCMs 
(10cm x 8cm x 6cm (B) Histopathological examination 
of the GCMs (H&E stain) showing thin walled vascular 

channels  and various  organizing thrombi within the 
cavernous vascular spaces (H&E, ×50) 

Discussion 
The first comprehensives studies of 

CMs were by Cushing and Bailey (1928) 
and Dandy (1928) who described a few 
cases of epilepsy in which large cavernoma 
were found during exploratory operation, 
usually for suspected tumour. These lesion 
natural history and management are being 
discussed since 1980 in the English 
literature 8. To date, only a small number 
of cases have been reported. CMs comprise 
5-13% of CNS vascular malformation; 
develop in 0.02-0.13% of the population. 
CMs are found throughout the central 
nervous system in which 48-86% are 
supratentorial, 4-35% brainstem, 5-10% 
basal ganglia. They can occur in two types: 
a sporadic and hereditary. The latter may be 
transmitted as an autosomal dominant trait 
which is characterized by multiple lesions. 
However, the former one, sporadic, is more 



 
 
 

Romanian Neurosurgery (2012) XIX 4: 294 – 298          297 

 
 
 

common as single lesion (7). CMs vary in 
size from a few millimeters to a few 
centimeters. According to the Lawton et al. 
CMs can be defined as giant CMs when 
cavernoma with diameter greater than six 
cm (5). They are rare in the literatures as 
we couldn’t found such a big size in 
literature till date. 

Differential diagnoses include 
meningioma, arteriovenous malformation, 
metastasis, infection, and other tumors. 
The presence of large amounts of 
hemoglobin degradation products such as 
methemoglobin, hemosiderin and ferritin 
around the malformation, seen both 
pathologically and radiologically with MRI, 
provides evidence of multiple previous 
episodes of microscopic hemorrhage (3). 
CT often reveals a hyperdense lesion that 
enhances little or not at all with contrast 
administration. These lesions are not visible 
on angiography and represent the largest 
percentage of angiographically occult 
vascular malformations. They usually have 
little to none of either surrounding edema 
or mass effect.  MRI is the diagnostic tool 
of choice owing to its sensitivity and 
specificity for these lesions. (1, 9, 10, 13) 

The clinical presentations of these 
lesions are variable ranging from headaches 
to fatal hemorrhage. Usual size lesions are 
usually revealed as incidental findings 
during investigations for unrelated 
symptoms. The usual symptoms of a 
cavernoma are seizure, acute onset of a 
severe headache, progressive neurologic 
deficit, hemorrhage and hydrocephalus (7, 
9, 12). Our case is more interesting as such 
giant CMs not yet present in literature. In 
our best knowledge, the growth mechanism 
for these lesions acute or chronic massive 
hemorrhage, intraluminal thrombosis with 
recanalization and organization, 
angiogenesis proliferation with new 

capillaries, immunohistochemical 
demonstrated proliferation, nidus growth 
by new caverns formation, vascular smooth 
muscle proliferation (3, 4, 8). 

The treatment of CM still represents a 
challenge which lesions and in what 
patients an operation is indicated, because 
the natural history of these lesions is 
relatively poorly understood. Surgical 
extirpation of such a lesion is relatively 
straightforward because there is usually a 
gliotic plane with evidence of hemosiderin 
from old hemorrhage around it. Bleeding is 
much less of a problem with cavernous 
malformations than with arteriovenous 
malformations even GCMs, because there 
are never large feeding vessels or draining 
veins. Gamma knife surgery shows some 
promise role by reducing the size of the 
lesion especially in locations like deep in the 
brain, brainstem and basal ganglia6. 
Microsurgical resection is the state of the 
art treatment in all patients whose CM is 
symptomatic, isolated, and localised in non-
eloquent regions of the brain (3, 4, 11, 12). 
Our rare case of GCM was also completely 
removed by microsurgical treatment with 
rewarding outcome. 

Conclusion 
Microsurgical resection is ideal 

treatment since the cavernoma is well 
circumscribed and lacks attachment to the 
surrounding brain. However, prompt 
diagnosis and treatment of large intracranial 
tumors require sound knowledge of 
neuroanatomy, neuroradiology and good 
surgical skills. 

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