TY - JOUR
T1 - Computational flow analysis with boundary layer and contact representation
T2 - II. Heart valve flow with leaflet contact
AU - Terahara, Takuya
AU - Kuraishi, Takashi
AU - Takizawa, Kenji
AU - Tezduyar, Tayfun E.
N1 - Funding Information:
This work was also supported in part by Grant-in-Aid for Research Activity Start-up 16K13779 from Japan Society for the Promotion of Science ( first author ) . The mathematical model and computational method parts of the work were also supported in part by ARO Grant W911NF-17-1-0046 and Con-tract W911NF-21-C-0030 ( second and fourth authors ) and Top Global University Project of Waseda University ( fourth author ) .
Publisher Copyright:
© 2022 The Author(s).
PY - 2022
Y1 - 2022
N2 - In this second part of a two-part article, we provide an overview of the heart valve flow analyses conducted with boundary layer and contact representation, made possible with the space-time (ST) computational methods described in the first part. With these ST methods, we are able to represent the boundary layers near moving solid surfaces, including the valve leaflet surfaces, with the accuracy one gets from moving-mesh methods and without the need for leaving a mesh protection gap between the surfaces coming into contact. The challenge of representing the contact between the leaflets without giving up on high-resolution flow representation near the leaflet surfaces has been overcome. The other challenges that have been overcome include the complexities of a near-actual valve geometry, having in the computational model a left ventricle with an anatomically realistic motion and an aorta from CT scans and maintaining the flow stability at the inflow of the ventricle-valve-aorta sequence, where we have a traction boundary condition during part of the cardiac cycle.
AB - In this second part of a two-part article, we provide an overview of the heart valve flow analyses conducted with boundary layer and contact representation, made possible with the space-time (ST) computational methods described in the first part. With these ST methods, we are able to represent the boundary layers near moving solid surfaces, including the valve leaflet surfaces, with the accuracy one gets from moving-mesh methods and without the need for leaving a mesh protection gap between the surfaces coming into contact. The challenge of representing the contact between the leaflets without giving up on high-resolution flow representation near the leaflet surfaces has been overcome. The other challenges that have been overcome include the complexities of a near-actual valve geometry, having in the computational model a left ventricle with an anatomically realistic motion and an aorta from CT scans and maintaining the flow stability at the inflow of the ventricle-valve-aorta sequence, where we have a traction boundary condition during part of the cardiac cycle.
KW - heart valve
KW - inflow stabilization
KW - ST isogeometric analysis (ST-IGA)
KW - ventricle
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U2 - 10.1093/jom/ufac013
DO - 10.1093/jom/ufac013
M3 - Review article
AN - SCOPUS:85132693373
SN - 1727-7191
VL - 38
SP - 185
EP - 194
JO - Journal of Mechanics
JF - Journal of Mechanics
ER -