Romanian Neurosurgery  |  Volume XXXI  |  Number 1 |  2017  |  January - March 

 
Article 

 
Single center experience and technical nuances 

in the treatment of distal anterior cerebral artery 

aneurysms  

 

Dorin Nicolae Gherasim, Gabriel Gyorki, Adrian Balasa 
ROMANIA 

 

 

 

DOI: 10.1515/romneu-2017-0003 
 



 
 
 
 
 

Romanian Neurosurgery (2017) XXXI 1: 17 – 24 | 17 

 

 
 
 
 
 
 

DOI: 10.1515/romneu-2017-0003   

Single center experience and technical nuances in the 
treatment of distal anterior cerebral artery aneurysms 

Dorin Nicolae Gherasim, Gabriel Gyorki, Adrian Balasa 

Department of Neurosurgery, Targu Mures, ROMANIA 

 
Abstract: Objective: This study presents the experience of one neurosurgical center 

in the treatment of 18 consecutive patients with distal anterior cerebral artery (DACA) 
aneurysms during a 10 years period. Our aim was to compare treatment outcomes of 
these lesions with intracranial aneurysms in general, and to present technical nuances 
in surgical treatment. Methods: We analyzed the clinical and radiological data of 18 
patients treated between 2005 and 2015. All patients were treated surgically using the 
microscope. No patients were lost to follow-up. We compared treatment and outcome 
of ruptured DACA aneurysms (n 18) with all consecutive ruptured aneurysms treated 
in our clinic during the same period (n 446). Results: DACA aneurysms accounted for 
4% of all intracranial aneurysms. They were smaller (median, 5,5 versus 9 mm) We 
found only one case with associated aneurysms (5,5%).  DACA aneurysms presented 
more often with intracerebral hematomas (39% versus 26%) than ruptured aneurysms 
in general. Their microsurgical treatment showed the same complication rates 
(treatment morbidity, 15%) as for other ruptured aneurysms in literature. Their 
mortality rate was lower (11% versus 24%). Conclusion: Despite their specific anatomic 
features, and particular surgical technique, with modern treatment methods, ruptured 
DACA aneurysms have the same favorable outcome and lower mortality as ruptured 
aneurysms in general. 
Key words: Cerebral aneurysm, Distal anterior cerebral artery, Pericallosal artery, 
Subarachnoid hemorrhage 

 
Distal anterior cerebral artery aneurysms 

(DACA), frequently referred to as pericallosal 
artery aneurysms, represent aneurysms that 
arise distal tot the anterior communicating 
artery (AComA), most commonly at the 
origin of the callosomarginal artery. They are 
uncommon, comprising only 2.7 to 9.2% 

(mean, 4.4% in 13 large series) of all 
intracranial aneurysms. (14, 23, 10) 

Their location in the interhemispheric 
fissure, the association with intracerebral 
hemorrhage, with multiple aneurysms and 
with vascular anomalies of the anterior 
cerebral artery (ACA) offer the neurosurgeon 



 
 
 
 
 
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a complex pathology and challenging surgical 
technique. The complexity of this pathology 
is completed by the specific anatomic features 
of DACA aneurysms, such as their small size 
and the broad neck with originating branches 
at this level (14, 23).  
 Anatomy  

The AComA is normally divided into five 
segments, A1 through A5 (Fig. 1). Segments 
A2 through A5 form the DACA. The A2 
segment extends from the AComA to the 
junction between the rostrum and genu of the 
corpus callosum. The A3 segment courses 
around the genu of the corpus callosum and 
ends at the point where the vessel takes a 
sharp turn posteriorly. The A4 segment runs 
superior to the corpus callosum, extending to 
a point just behind the coronal suture. The 
A5 segment is the portion of the AComA that 
lies posterior to the coronal suture (10). 

The literature is lacking detailed studies 
on the anatomy of DACA aneurysms, with 
the notable exception of the Finnish group 
coordinated by Hernesniemi et al which 
divided DACA aneurysms in seven groups, 
with the Genu of the Corpus Callosum (GCC) 
as the anatomic landmark for this division 
(aneurysms at each of these locations require 
a modified microsurgical approach).  1) 
Frontobasal aneurysms: located on the A2 
frontobasal branches.  2) A2 trunk 
aneurysms: located directly on the A2 
segment.  3) Inferior A3 aneurysms: located 
on the proximal part of the A3 segment 
inferior to the GCC. 4) Anterior A3 
aneurysms: located on the central part of the 
A3 segment anterior to the GCC.  5) Superior 
A3 aneurysms: located on the distal part of 
the A3 segment superior to the GCC. 6) A4 or 

A5 aneurysms. 7) Distal branch aneurysms: 
located on the distal cortical branches 
originating from the A3 to A5 segments: the 
callosomarginal artery (CMA) (14, 3). 

Objectives 
This study presents the experience of one 

neurosurgical center in the treatment of 18 
consecutive patients with ruptured DACA 
aneurysms during a 10years period. Our aim 
was to compare treatment outcomes of these 
lesions with intracranial aneurysms in 
general, and to present technical nuances in 
surgical treatment. 

Material and methods    
We analyzed the clinical and radiological 

data of 18 patients treated between 2005 and 
2015. All patients were treated surgically by 
clip ligation using the microscope. No 
patients were lost to follow-up. We compared 
treatment and outcome of ruptured DACA 
aneurysms (n 18) with all consecutive 
ruptured aneurysms treated in our clinic 
during the same period (n 446). 

Results 
From the 466 patients treated for ruptured 

cerebral aneurysms in our department, 18 
presented with ruptured DACA aneurysms 
representing 3,8%. Mean age was 53 years, 
and females were twice as frequent than men. 

We used the classification developed by 
the Finnish group (14), in order to classify 
those 18 aneurysms, and as a result we 
observed that the majority of our cases were 
type 4 located aneurysms – anterior A3 
aneurysms (Table 1). 



 
 
 
 
 

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Table I 
Number of patients according to 

Hernesniemi’ classification of DACA 
aneurysms 

DACA aneurysm classification No of cases (%) 
Type 1 1 (5,5) 
Type 2  1 (5,5) 
Type 3 2 (11) 
Type 4 11 (77,5) 
Type 5 3 (16,5) 

 
As seen in Table 2, 50% of patients with 

DACA aneurysms in our clinic were admitted 
in good clinical condition (Hunt-Hess 1and 
2), with only 1 patient being admitted in 
critical condition (Hunt-Hess- 5). 

 
Table II 

Clinical (Hunt-Hess and WFNS scores) and 
imagistic status (Fisher scale) at presentation 

Intracerebral or interhemispheric 
hematoma was seen in 7 patients, 
representing 38,8% of patients with DACA 
aneurysms (Figure 1). 

From the imagistic point of view, as a 
protocol, every patient had native head CT 
scan upon admission. If subarachnoid 
hemorrhage (SAH) or intracerebral 
hematoma (ICH) were present raising the 
suspicion of ruptured aneurysm, the patient 
was sent to angio suite, for a 4 vessel cerebral 
angiography (Figure 2). 

The medium size of DACA aneurysms in 
our series was 6.2 mm (range 4.5-12 mm), 
and 13 patients harboured DACA aneurysms 
smaller than 7 mm (72.2%).   

An interesting finding was the fact that 
from the 18 patients in our series we had only 
one case with associated unruptured cerebral 
aneurysm representing only 5,5%. 

 

  
Figure 1 - Non enhanced CT scan of patient with 

Fisher 3 SAH 
 

  
Figure 2 - Left ACI injection on DS angiography on 

the same patient revealing a type 3 saccular aneurysm 
on the left DACA 

NR Hunt Hess WFNS Fisher scale
1 1 1 2

2 1 1 2
3 3 3 2
4 1 1 3
5 2 2 4
6 3 4 4
7 3 2 3
8 2 1 2
9 1 1 4

10 1 2 2
11 3 2 4
12 3 4 3
13 3 3 4
14 5 5 4
15 3 4 2
16 3 3 4
17 2 3 2
18 1 1 2



 
 
 
 
 
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Surgical technique 
Our service has an “early surgery” policy, 

thus 78% of patients were admitted in our 
service in the first 24h after rupture and 72% 
underwent early surgery. 

As a technique, the goal was to identify the 
parent vessel and to obtain proximal control 
as soon as possible, so interhemispheric 
approach and dissection was carried out 
following interhemispheric cortical arteries 
which took us as close as possible to the 
anterior communicating complex on the 
anterior fossa floor. After identifying the post 
communicating segment of the anterior 
cerebral arteries, dissection along their 
trajectory was realized with the identification 
of the saccular aneurysm and the emerging 
branches.  

There are some particular aspects that 
need to be considered when performing 
surgery for DACA aneurysms. First the 
interhemispheric fissure provides a narrow 
corridor for the approach. There is little CSF 
present in the  

interhemispheric cisterns, so in order to 
simplify the approach on a swallowed brain, 
external ventricular drain (EVD) or lumbar 
drainage can be an option. The arachnoid 
adhesions make the dissection of 
interhemispheric cisterns difficult. 
Additionally, parasagittal veins may represent 
a challenge – but these structures must be 
preserved. And of course, once the 
interhemispheric approach is realized, early 
identification of parent vessel isn’t always 
easy.

 

 
Figure 3 - Intraoperative images of a right frontal interhemispheric approach  

and clipping of type 3 DACA aneurysm 
 



 
 
 
 
 

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Outcomes 
Clinical outcome was assessed using the 

modified Rankin Scale (mRS) both at 
discharge and at six months. We considered 
good outcome an m RS between 0 and 2. 

As seen in Tables 3 and 4 there is a clear 
relation between the neurological status at 
admission and the clinical outcome. In the 
patients group with good neurological status 
at admission (Hunt-Hess 1 and 2), n-10, there 
was only one patient (10%) with poor 
outcome – m RS-5. 

 

Table III 
Clinical outcome of patients with DACA 

aneurysms in our clinic 

 
Table IV 

Relation between the neurological status at 
admission and the clinical outcome 

In the group of patients with poor 
neurological status at admission (n-8), there 
were 6 patients (75%) with poor outcome (m 
RS-3-6). The only patient in this group 
admitted in critical condition (Hunt-Hess-5), 
died one week after surgery.  

Perioperative complications included 
intraoperative rupture of aneurysm (4 cases – 
22,2%), postoperative intracerebral 
hematoma (1 case-5,5%) and meningitis (1 
case – 5,5%). The overall morbidity  was 11% 
(2 cases). 

Discussion 
Clinical outcome 

The outcomes obtained in this small  
series are comparable to those of previous 
reports. We evaluated 18 patients treated for 
ruptured DACA aneurysm. Successful 
clipping was achieved in all of these patients, 
with no recurrence of SAH at 6 months and 
no need for retreatment (2, 28, 25).  

Good clinical outcome, measured using m 
RS (m RS 0 - 2) was achieved in 11 patients 
(60,5%). In our study, the statistically 
significant predictor of outcomes in the 
patients with SAH was the presenting Hunt-
Hess score. Patients in a lower Hunt-Hess 
grade (I and II) had a favorable outcome in 
90% of cases, compared with 25% of patients 
in the Hunt-Hess groups III, IV and V.  These 
results show that, despite the difficulties 
associated with aneurysms in this location, 
good results can be achieved in most patients 
who have a good clinical grade. Poor grade 
patients remain a significant challenge, 
particularly those patients with large 
parenchymal hemorrhages (1, 15, 24, 29).  

Outcome at 6 months  

Favorable (mRS 0-2) 12 cases (67%) 

Unfavourable (mRS 3-6) 6 cases (33%) 

H-H/mRS 0 1 2 3 4 5 6 

I 3 2 1 0 0 0 0 

II 0 1 2 0 0 1 0 

        

III 0 1 1 3 1 1 0 

IV 0 0 0 0 0 0 0 

V 0 0 0 0 0 0 1 



 
 
 
 
 
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 Ohno et al concluded in their analysis 
that DACA aneurysms tend to rupture at a 
smaller size. In their series, 73% of the 
patients harbored aneurysms smaller than 5 
mm. In Pandey et al series, the majority of 
patients harbored aneurysms smaller than 6 
mm. In our series 72% of DACA aneurysms 
treated were smaller than 7 mm with a 
median size of 6.2 mm. Thus, the question of 
whether unruptured DACA aneurysms 
should be treated at a smaller size compared 
to the limit of 7 mm set by the ISUIA trial for 
anterior circulation aneurysms, seems to be a 
valid one, and needs further investigation (16, 
21, 22).  

Symptomatic vasospasm represents the 
most important cause of morbidity in patients 
surviving SAH and affects up to 30% of 
patients presenting with SAH caused by 
ruptured aneurysms in the anterior 
circulation (6, 8, 17). In our series, only two 
patients developed clinically significant 
vasospasm, both with Fisher grade III SAH 
on CT scans. The majority of our patients 
were in Fisher Grade II (50%) and IV (39%) 
and, thus, would not be supposed to develop 
vasospasm. It seems that patients with distal 
aneurysms (DACA/MCA) have a lower 
incidence of spasm because most of these 
patients tend to have localized bleeding 
instead of the diffuse SAH.  
Surgical technique and nuances   

Microsurgical clipping remains the main 
therapeutic tool, the endovascular treatment 
being limited by the distal location and complex 
anatomy of DACA aneurysms. (4, 7, 9) 

Nonetheless, surgical clipping of DACA 
aneurysm presents with specific difficulties 

compared with other locations, as described 
in previous studies (11, 13, 26, 27). 

The particularities of  DACA aneurysms 
are related to the narrow approach and deep 
location making the approach less straight 
forward. As described by the majority of the 
authors, we utilized a right frontal 
interhemispheric approach making sure to 
have proximal control before dissecting and 
clipping the aneurysm. The approach was 
adapted to the type of DACA aneurysm 
ranging from frontobasal approaches for type 
1 and 2 DACA aneurysms to frontoparietal 
craniotomies for the more distally located 
aneurysms. Although rarely used, 
neuronavigation can be an important 
additional tool in the neurosurgeon’s 
armamentarium, making the approach less 
invasive and more straight forward. 

Once the approach realized, early 
identification of parent vessel is of paramount 
importance because of the lack of anatomic 
landmarks which makes safe dissection and 
clipping of DACA aneurysm difficult. These 
factors make these aneurysms more prone to 
early intraoperative rupture, Lehecka et al 
reporting in their large 501 patients study an 
incidence of 22% of intraoperative rupture 
(15). In our study we had similar results, with 
5 patients (27,5%) that had early 
intraoperative rupture. All cases were 
managed without early or late postoperative 
complications. 

The overall rate of complications was 11% 
(1 case of meningitis, and 1 case of 
postoperative intracerebral hematoma), and 
these complication rates are similar to those 
reported in the literature for the treatment of 
DACA aneurysms (9, 13, 14, 19).  



 
 
 
 
 

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Conclusions 
DACA aneurysms are usually small with 

specific anatomic features such as wide neck 
and association with anatomic variations of 
ACA. Surgical clipping is a safe and effective 
method of treatment, but it must be adapted 
to the location of the aneurysm on the ACA, 
and proximal control is of paramount 
importance. 

Following the actual trend for the 
treatment of intracranial aneurysms, most of 
these aneurysms will eventually be treated by 
endovascular means (5, 12, 18, 20). 
Nonetheless, knowledge of the specific 
features regarding the microsurgical approach 
and clipping of these aneurysms and the 
expected outcomes remain an important skill 
in the arsenal of vascular neurosurgeons. 
 
Correspondence 
Dr. Dorin Nicolae Gherasim – MD, neurosurgeon, 
Department of Neurosurgery, Targu Mures  
Tel: +40 726 29 26 27 
Fax:+40 265 210621 
E-mail: dorin.gherasim@gmail.com 

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