The anterior communicating artery (ACOM) bifurcation, a common site for aneurysm formation, carries high risk of aneurysm rupture. Due to its anastomotic nature, it exhibits complex hemodynamic and morphological profiles. Previously, ACOM angles were evaluated without accounting for unique characteristics. Evaluate ACOM angular morphology bilaterally, based on A1 trunk dominance (size and angiographic presentation), in aneurysmal and healthy patients. Bilateral catheter 3D rotational angiographic studies were available from 67 patients with ACOM aneurysms and 54 non-aneurysmal controls (242 samples total). A1 segments were classified as dominant, co-dominant, or non-dominant based on relative diameter. AcomA2 and A1A2 angles were measured on 2D cut planes. Matched-pair analysis was performed on aneurysmal and non-aneurysmal patients with dominant/non-dominant segment labels. Aneurysms occurred on dominant (70.1%) or co-dominant A1 segments. A1A2 angles were significantly wider in aneurysmal bifurcations (74.1 ±21.75°) than contralateral (53.88±21.59°, p<0.001) and non-aneurysmal controls (42.44±14.43°, p<0.001), with a threshold of 59.2° (AUC=0.88). AcomA2 angle could not be evaluated in 90 volumes (37.2%) due to poor angiographic visibility of the ACOM. In unilateral and matched-pair analysis, A1A2 was significantly wider in dominant control bifurcations than non-dominant sides (45.85±9.83° vs. 34.47±12.21°, p=0.003). ACOM angular morphology is strongly determined by A1 dominance, independent of aneurysm presence. Unlike the AcomA2 angle, A1A2 was measurable in all samples and reliably captured bifurcation angulation. ACOM bifurcations, unlike other bifurcations, require bilateral morphological and hemodynamic evaluation of the full anterior communicating artery complex. These findings inform future evaluation and modeling of cerebral vascular architecture.
Breton et al. (Fri,) studied this question.