Blood flow and emboli transport patterns during venoarterial extracorporeal membrane oxygenation: A computational fluid dynamics study

Despite advances in Venoarterial Extracorporeal Membrane Oxygenation (VA-ECMO), a significant mortality rate persists due to complications. The non-physiological blood flow dynamics of VA-ECMO may lead to neurological complications and organ ischemia. Continuous retrograde high-flow oxygenated blood...

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Published in:Computers in biology and medicine 2024-04, Vol.172, p.108263-108263, Article 108263
Main Authors: Khamooshi, Mehrdad, Wickramarachchi, Avishka, Byrne, Tim, Seman, Michael, Fletcher, David F., Burrell, Aidan, Gregory, Shaun D.
Format: Article
Language:English
Subjects:
Aorta
Aortic arch
Blood
Blood flow
Boundary conditions
Cannula
Cannulae
Cardiac output
Clinical medicine
Computational fluid dynamics
Computational neuroscience
Computed tomography
Coronary vessels
Deoxygenation
Emboli transport
Embolization
Extracorporeal membrane oxygenation
Femoral artery
Fluid dynamics
Harlequin syndrome
Heart
Hydrodynamics
Ischemia
Mathematical models
Mechanical circulatory support
Membranes
Mortality
Neurological complications
Oxygen
Oxygen content
Oxygenation
Particle tracking
Patients
Simulation
Stroke
Tomography
Veins & arteries
Velocity
Ventricle
Ventricles (cerebral)
Watershed region
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Summary:Despite advances in Venoarterial Extracorporeal Membrane Oxygenation (VA-ECMO), a significant mortality rate persists due to complications. The non-physiological blood flow dynamics of VA-ECMO may lead to neurological complications and organ ischemia. Continuous retrograde high-flow oxygenated blood enters through a return cannula placed in the femoral artery which opposes the pulsatile deoxygenated blood ejected by the left ventricle (LV), which impacts upper body oxygenation and subsequent hyperoxemia. The complications underscore the critical need to comprehend the impact of VA-ECMO support level and return cannula size, as mortality remains a significant concern. The aim of this study is to predict and provide insights into the complications associated with VA-ECMO using computational fluid dynamics (CFD) simulations. These complications will be assessed by characterising blood flow and emboli transport patterns through a comprehensive analysis of the influence of VA-ECMO support levels and arterial return cannula sizes. Patient-specific 3D aortic and major branch models, derived from a male patient's CT scan during VA-ECMO undergoing respiratory dysfunction, were analyzed using CFD. The investigation employed species transport and discrete particle tracking models to study ECMO blood (oxygenated) mixing with LV blood (deoxygenated) and to trace emboli transport patterns from potential sources (circuit, LV, and aorta wall). Two cannula sizes (15 Fr and 19 Fr) were tested alongside varying ECMO pump flow rates (50%, 70%, and 90% of the total cardiac output). Cannula size did not significantly affect oxygen transport. At 90% VA-ECMO support, all arteries distal to the aortic arch achieved 100% oxygen saturation. As support level decreased, oxygen transport to the upper body also decreased to a minimum saturation of 73%. Emboli transport varied substantially between emboli origin and VAECMO support level, with the highest risk of cerebral emboli coming from the LV with a 15 Fr cannula at 90% support. Arterial return cannula sizing minimally impacted blood oxygen distribution; however, it did influence the distribution of emboli released from the circuit and aortic wall. Notably, it was the support level alone that significantly affected the mixing zone of VA-ECMO and cardiac blood, subsequently influencing the risk of embolization of the cardiogenic source and oxygenation levels across various arterial branches. [Display omitted] •Interaction between nati
ISSN:0010-4825
1879-0534
DOI:10.1016/j.compbiomed.2024.108263