A framework for simulating coupling between coronary artery and myocardial perfusion: a preliminary study
A framework for simulating coupling between coronary artery and myocardial perfusion: a preliminary study
The strong association between cardiac perfusion and myocardial electromechanical deformation motivates this study. We present a numerical model of myocardial perfusion using a Darcy porous media flow in an idealized domain. Our model incorporates cardiac electrophysiology, passive and active mechanics of the myocardium, arterial blood hemodynamics, and a single-compartmental Darcy model to represent microcirculation. We consider a contracting slab domain representing a portion of the myocardium and a cylindrical geometry as the coronary artery. The fluid dynamics in the coronary is governed by the 3-D Navier–Stokes equation, and the myocardium is represented by the porous medium. The coupling of these domains takes place at the interface using appropriate boundary conditions based on the conservation of mass and continuity, where the outlet of the artery supplies flow to the myocardial porous medium. We simulated two clinical conditions: normal and myocardial fibrillation. Results indicated a pressure drop from the coronary to the myocardium of about 44% proving the 46.8 percent local myocardial domain displacement in the normal case than in the fibrillation. There is also a dynamic change in myocardial volume of 10% in a cardiac cycle attributed to the coronary flow and myocardial deformation. Blood is perfused into the myocardium largely when the heart relaxes. The uncoordinated electrical sequence imposed by fibrillation produces more irregular flow in the porous myocardium. These findings offer a basis for a computational framework for investigating coronary–myocardium interaction in a realistic electromechanical-perfusion cardiac model.
131-142
Binti Ulta Delestri, Laila Fadhillah
6634334f-4d49-494a-a674-1874f4374d6a
Kok, Foo Ngai
9c965216-c916-493c-9d7d-b58e72ced83a
Mokhtarudin, Mohd Jamil Mohamed
12678547-6af9-4756-bc5e-9c72b2afb927
Bressloff, Neil W.
9d5c6a14-d975-4628-a7bf-bfff188337db
Sengers, Bram G.
d6b771b1-4ede-48c5-9644-fa86503941aa
Ahmed Bakir, Azam
05b4b607-b825-4ab4-b002-0c3aea9ae0b2
Mokhtarudin, M.J. Mohamed
12 October 2024
Binti Ulta Delestri, Laila Fadhillah
6634334f-4d49-494a-a674-1874f4374d6a
Kok, Foo Ngai
9c965216-c916-493c-9d7d-b58e72ced83a
Mokhtarudin, Mohd Jamil Mohamed
12678547-6af9-4756-bc5e-9c72b2afb927
Bressloff, Neil W.
9d5c6a14-d975-4628-a7bf-bfff188337db
Sengers, Bram G.
d6b771b1-4ede-48c5-9644-fa86503941aa
Ahmed Bakir, Azam
05b4b607-b825-4ab4-b002-0c3aea9ae0b2
Mokhtarudin, M.J. Mohamed
Binti Ulta Delestri, Laila Fadhillah, Kok, Foo Ngai, Mokhtarudin, Mohd Jamil Mohamed, Bressloff, Neil W., Sengers, Bram G. and Ahmed Bakir, Azam
(2024)
A framework for simulating coupling between coronary artery and myocardial perfusion: a preliminary study.
Mokhtarudin, M.J. Mohamed, Ahmad Bakir, A., Stephens, A. and Sulaiman, N.
(eds.)
In Proceedings of the Annual Congress of the Asia-Pacific Society for Artificial Organs: APSAO: Making Breakthrough via Multidisciplinary Approach.
Springer Singapore.
.
(doi:10.1007/978-981-97-1920-4_13).
Record type:
Conference or Workshop Item
(Paper)
Abstract
The strong association between cardiac perfusion and myocardial electromechanical deformation motivates this study. We present a numerical model of myocardial perfusion using a Darcy porous media flow in an idealized domain. Our model incorporates cardiac electrophysiology, passive and active mechanics of the myocardium, arterial blood hemodynamics, and a single-compartmental Darcy model to represent microcirculation. We consider a contracting slab domain representing a portion of the myocardium and a cylindrical geometry as the coronary artery. The fluid dynamics in the coronary is governed by the 3-D Navier–Stokes equation, and the myocardium is represented by the porous medium. The coupling of these domains takes place at the interface using appropriate boundary conditions based on the conservation of mass and continuity, where the outlet of the artery supplies flow to the myocardial porous medium. We simulated two clinical conditions: normal and myocardial fibrillation. Results indicated a pressure drop from the coronary to the myocardium of about 44% proving the 46.8 percent local myocardial domain displacement in the normal case than in the fibrillation. There is also a dynamic change in myocardial volume of 10% in a cardiac cycle attributed to the coronary flow and myocardial deformation. Blood is perfused into the myocardium largely when the heart relaxes. The uncoordinated electrical sequence imposed by fibrillation produces more irregular flow in the porous myocardium. These findings offer a basis for a computational framework for investigating coronary–myocardium interaction in a realistic electromechanical-perfusion cardiac model.
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Accepted/In Press date: 31 July 2023
Published date: 12 October 2024
Identifiers
Local EPrints ID: 498150
URI: http://eprints.soton.ac.uk/id/eprint/498150
ISSN: 2195-271X
PURE UUID: 275c3c93-1db4-40fc-b0db-949389783400
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Date deposited: 11 Feb 2025 17:45
Last modified: 12 Feb 2025 02:41
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Contributors
Author:
Laila Fadhillah Binti Ulta Delestri
Author:
Mohd Jamil Mohamed Mokhtarudin
Author:
Neil W. Bressloff
Author:
Azam Ahmed Bakir
Editor:
M.J. Mohamed Mokhtarudin
Editor:
A. Ahmad Bakir
Editor:
A. Stephens
Editor:
N. Sulaiman
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