9_IonG_Ruptured fusiform


 
 
 
 
 
286          Ion et al          Ruptured fusiform aneurysm of the proximal anterior cerebral artery 

 

 

 

 

 

 

 

Ruptured fusiform aneurysm of the proximal anterior 
cerebral artery in young patient - case report 

Georgiana Ion*, A. Chiriac, N. Dobrin*, I. Poeata 

“Gr. T. Popa” University of Medicine and Pharmacy, Iasi 
*“Prof. Dr. N. Oblu” Clinic Emergency Hospital, Iasi 

 
Abstract: A 16-year old male presented with a ruptured aneurysm of the proximal 
segment of the anterior cerebral artery, with symptoms like sudden headache. 
Paraclinical explorations revealed a fusiform aneurysm of the right A1 segment.  The 
optimal treatment used was the microsurgical one via right pterional approach. The 
aneurysm was associated with a saccular pseudoneurysm at the proximal part. The 
saccular portion was clipped and the fusiform one was wrapped with muscle. The 
postoperative evolution was favorable, without neurological deficits.  
Key words: fusiform aneurysm, wrapping, dissecting aneurysm, child. 

 
Introduction 

In children, fusiform aneurysms typically 
affect a major intracranial artery and involve a 
segment several centimeters long. Regarding 
the treatment, these aneurysms are difficult to 
manage both endovascular and microsurgical. 
Sometimes a combination of these methods 
may be needed. Trapping by ligation proximal 
and distal to the aneurysm may be an option if 
the perfusion is maintained by a collateral 
blood flow. This technique should lower the 
risk of rebleeding. 

Fusiform aneurysms represents 1% of all 
intracranial aneurysms, the incidence in A1 
segment is about 0,76-3,4%,often associated 
with vascular anomalies. In children are four 
times more common. The most frequent 
location is vetebrobasilar system, then internal 
carotid artery, middle cerebral artery and in 
more rare cases- anterior cerebral artery. These 
aneurysms are characterized by the spindle 
shape dilatation sometimes associated with a 
saccular expansion-beer belly.  Our case is a 
saccular aneurysm developed on the proximal 
A1 fusiform aneurysm. 

Case report 
History and Presentation 

A 16 year old boy suddenly complained of 
severe headache and vomiting followed by 
loss of consciousness. He was brought to our 
hospital with Hunt&Hess score of 2, Fisher 2. 
The neurological and general examinations 
were unaltered. Personal history with no other 
conditions associated or alcohol and cigarettes 
consuming. Is important to note the family 
history of subarachnoid hemorrhage in a 
parental uncle. 

Brain computer tomography revealed 
subarachnoid hemorrhage in bilateral sylvian 
fissure and carotid cistern. 

 



 
 
 
 
 

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Native CT scan at admission 

 

 

 
CT angio reconstructions 

 
CT angio exploration and 3D 

reconstructions demonstrated a fusiform 
aneurysm in the proximal part of the A1 
segment. For a better visualization of the 
configuration of the aneurysm and relationship 
with adjacent vessels, Seldinger angiography 
was necessary. A bilateral internal carotid 
artery catheterization was performed, 
demonstrating the right ACA aneurysm and 
the right A1 dominant. 

 

 

 
Right carotid artery angiography 

 
After review by the multidisciplinary 

neurovascular team, was decided that the best 
treatment option is the microsurgical one. 

Surgery was performed in day 1 after the 
rupture and was used a right pterional 
transsylvian approach. During the Sylvian 
fissure proximal dissection is distinguished 
some arachnoiditis changes fronto-basal, 
around optic nerves and right internal carotid. 
Then is identified the bifurcation, A1 segment 
up to anterior communicating complex. The 
right A1 segment included a saccular 
aneurysm developed on a fusiform dilatation 
that extends approximately 10mm. The 
saccular dilatation was surrounded by a fresh 
clot. One perforator was identified branching 
proximal from the aneurysm. At first the 
saccular aneurysm is closed with a Yasargil 
straight phynox clip, then the fusiform 
dilatation was wrapped with muscle and 
aponeurosis going between the aneurysm and 
supraoptic recess and fixed on the anterior part 



 
 
 
 
 
288          Ion et al          Ruptured fusiform aneurysm of the proximal anterior cerebral artery 

 

 

 

 

 

 

 

with an oblique phynox clip. The rupture point 
was identified on the anterior surface of the 
saccular aneurysm.  After wrapping the blod 
flow through the distal ACA was maintained. 
Aneurysmal wall was not so thin, there were 
no perforators branching from the dilatation, 
therefore wrapping was considered the best 
option to achieve adequate hemostasis. 

 
Intraoperative view –arachnoiditis 

 
a. Intraoperative aspect of the aneurysm 

 b. saccular dilatation clipped 
 

 
c. fusiform dilatation is wrapped with muscle 

 
The postoperative evolution was favorable, 

without vasospasm during the 3 weeks of 
hospitalization. The CT scan 24 hours after 
surgical treatment demonstrated a hypodense 
area located at the level of basal ganglia. 

Pacient was discharged without neurological 
deficits or psychiatric symptoms. 

 

 
Postoperative 48 h CT scan 

 

Discussion 
Natural history of unrupted fusiform 

aneurysms is not very well studied, but in case 
of rupture the rebleeding rate is about 10% per 
year. First it has to be discussed the term of 
fusiform aneurysm and the clear 
differentiation from the dissecting ones, due to 
the difference regarding the natural history and 
optimal therapy. Some consider that fusiform 
aneurysms may be predisposant for a 
dissecting aneurysm. Angiographic 
characteristics of dissecting lesions are 
represented by the double lumen sign, the 
pearl and string sign, retention of contrast 
media in false lumen, intimal flap or vascular 
occlusion. In the case presented was found 
none of these criteria. Based on angiographic 
images and the intraoperative ones the 
morphological diagnosis was fusiform 
aneurysm. They may be caused by collagen 
and elastin affections, infections or neoplastic 
invasion of the arterial wall. In younger 
population, according to a recent study 
comorbid conditions found in the goup were-
trauma, immune dysfunction, cardiovascular 
malformation, dermatologic disorder, 
hormonal abnormality and genetic syndromes 



 
 
 
 
 

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like polycystic kidney disease, tuberous 
sclerosis, Osler-Weber–Rendu disease, 
Klippel-Trenaunay-Weber syndrome, alpha 1-
antitrypsin deficiency. Aterosclerotic origin in 
the development of these lesions is well known 
but not mandatory. Histopathological studies 
revealed a thinning of the media, atrophy of 
the muscle fibers, hyalinization of the 
connective tissue or deficiency of reticular 
fiber. 

These aneurysms located on A1 segment, 
usually are symptomatic by neural 
compression, ischemia and rarely due to 
bleeding. These aneurysms may expand 
gradually transforming into saccular or 
spherical shape. If the aneurysm is rupted, then 
treatment is required. Clipping only the neck 
of the saccular dilatation is not sufficient. 
Regarding the circumferential fusiform 
dilatation, clipping is not an option, but 
trapping or wrapping are. Trapping is 
recommended if there is a confirmation of a 
good collateral blood flow and if the 
preservation of the perforating artery is 
possible. Therefore if these criteria are not 
fulfilled, wrapping may be the next treatment 
option. 

The ideal procedure in the case presented 
was to clip the saccular dilatation and 
wrapping (reinforcement) of the fusiform 
segment especially that intraoperative, the 
aneurysmal wall was not so thin. Incomplete 
wrapping can be the cause of re-rupture and re-
growth. Some studies (Vivek RD, Udaya KK, 
Joseph Robert 2006) shown that half of the 
patients treated by wrapping, the follow-up 
angiography showed no changes regarding the 
configuration and the size of the aneurysm. Is 
safe to mention that, in pediatric population 
development of new and enlarging aneurysms 
(many within 3 years) is hard to quantify, but 
is more common in patients with fusiform 
aneurysms. Should be considered and the risk 
of rebleeding which is between 12-18 %, 
according to many studies. Other 
complications may be obstruction of one of the 

branches that emerge from A1 segment-medial 
lenticulostriate arteries or occurrence of a new 
aneurysm adjacent to the previously treated 
one. These perforantes supply the globus 
pallidus and medial portion of putamen. 
Intraoperative could observe the recurrent 
artery of Heubner and a small branch running 
proximal to the aneurysm. However, 48 hour 
postoperative CT scan revealed an ischemic 
area at the level of basal ganglia, probably 
because of affecting a small medial 
lenticulostriate branch, without clinical 
manifestation. 

Conclusion 
Brain aneurysms in pediatric population 

may be considered as a potentially aggressive 
chronic progressive condition. This impose a 
rigorously follow-up with MRI or CT 
angiography at three year interval, for a long 
period of time considering the long life 
expectancy. However, more data should be 
gathered to reach a consensus about the nature 
of this pathology. 

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