Angled Aortic Cannulation Reduces Cerebral Embolic Transport and Adverse Wall Loading During Cardiopulmonary Bypass: A Patient-Specific Hemodynamic Study

TL;DR

This study demonstrates that angling the aortic cannula during cardiopulmonary bypass significantly reduces cerebral embolic transport and wall stress, with effects varying across patient-specific aortic anatomies and conditions.

Contribution

It provides the first patient-specific computational analysis showing how angled cannulation decreases embolic transport and wall loading during CPB.

Findings

Angled cannulation reduces embolic transport into cerebral arteries by up to 50%.

Perpendicular cannulation causes higher wall pressure and shear stress.

Geriatric anatomy shows the largest benefit from angled cannulation.

Abstract

Embolic stroke during cardiopulmonary bypass (CPB) is strongly influenced by cannula induced flow disturbances that govern emboli transport and aortic wall loading. This study quantifies how aortic cannula orientation affects embolic distribution and atherosclerotic plaque disruption risk across patient specific, age-dependent aortic anatomies under clinical CPB conditions. A validated computational fluid dynamics and Lagrangian particle tracking (CFD-LPT) framework was applied to four patient-specific aortic models representing pediatric, adolescent, adult, and geriatric anatomies. Two clinically relevant cannula orientations: perpendicular (90 deg) and angled (30 deg), were evaluated under varying blood viscosities (1.5 to 3.5 cP) and embolus sizes (0.5 to 2.5 mm). Aortic branch exit percentage, wall pressure, and wall shear stress (WSS) were quantified. The 30 deg angled cannula reduced embolic transport into the aortic branches by 18 to 50 percent compared with perpendicular cannulation, with the largest reduction observed in the geriatric model. Perpendicular cannulation produced concentrated jet impingement, resulting in significantly elevated posterior wall pressure (24 percent) and up to an 8 fold increase in local WSS. The pediatric anatomy exhibited the highest sensitivity, where decreasing viscosity and increasing embolus size increased branch exit by 8.4 percent and 25 to 44 percent, respectively, consistent with higher particle Stokes numbers and inertial decoupling from the core flow. Angled cannulation redistributes jet momentum along the aortic curvature, weakens jet impingement, reduces localized pressure and wall stress, and limits embolic delivery towards the cerebral circulation. These findings provide mechanistic, patient-specific evidence supporting angled cannula orientation to reduce CPB complications.