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Multiblock high order Large Eddy Simulation of powered Fontan hemodynamics: Towards computational surgery

•First computational surgical implantation of a novel pump for Fontan circulation.•Multiblock approach improves accuracy / efficiency of IBM for internal flows.•IBM on fixed Cartesian grid allows simulations of flows in complex moving geometry.•LES model allows accurate prediction of pathological lo...

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Bibliographic Details
Published in:Computers & fluids 2017-01, Vol.143, p.16-31
Main Authors: Delorme, Yann T., Rodefeld, Mark D., Frankel, Steven H.
Format: Article
Language:English
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Summary:•First computational surgical implantation of a novel pump for Fontan circulation.•Multiblock approach improves accuracy / efficiency of IBM for internal flows.•IBM on fixed Cartesian grid allows simulations of flows in complex moving geometry.•LES model allows accurate prediction of pathological low Re transitional flows.•Pump provides desired pressure rise while keeping blood damage low. Children born with only one functional ventricle must typically undergo a series of three surgeries to obtain the so-called Fontan circulation in which the blood coming from the body passively flows from the Vena Cavae (VCs) to the Pulmonary Arteries (PAs) through the Total Cavopulmonary Connection (TCPC). The circulation is inherently inefficient due to the lack of a subpulmonary ventricle. Survivors face the risk of circulatory sequelae and eventual failure for the duration of their lives. Current efforts are focused on improving the outcomes of Fontan palliation, either passively by optimizing the TCPC, or actively by using mechanical support. We are working on a chronic implant that would be placed at the junction of the TCPC, and would provide the necessary pressure augmentation to re-establish a circulation that recapitulates a normal two-ventricle circulation. This implant is based on the Von Karman viscous pump and consists of a vaned impeller that rotates inside the TCPC. To evaluate the performance of such a device, and to study the flow features induced by the presence of the pump, Computational Fluid Dynamics (CFD) is used. CFD has become an important tool to understand hemodynamics owing to the possibility of simulating quickly a large number of designs and flow conditions without any harm for patients. The transitional and unsteady nature of the flow can make accurate simulations challenging. We developed and in-house high order Large Eddy Simulation (LES) solver coupled to a recent Immersed Boundary Method (IBM) to handle complex geometries. Multiblock capability is added to the solver to allow for efficient simulations of complex patient specific geometries. Blood simulations are performed in a complex patient specific TCPC geometry. In this study, simulations without mechanical assist are performed, as well as after virtual implantation of the temporary and chronic implants being developed. Instantaneous flow structures, hepatic factor distribution, and statistical data are presented for all three cases.
ISSN:0045-7930
1879-0747
DOI:10.1016/j.compfluid.2016.10.032