A computationally efficient framework for the simulation of cardiac perfusion using a multi‐compartment Darcy porous‐media flow model. (18th October 2012)
- Record Type:
- Journal Article
- Title:
- A computationally efficient framework for the simulation of cardiac perfusion using a multi‐compartment Darcy porous‐media flow model. (18th October 2012)
- Main Title:
- A computationally efficient framework for the simulation of cardiac perfusion using a multi‐compartment Darcy porous‐media flow model
- Authors:
- Michler, C.
Cookson, A. N.
Chabiniok, R.
Hyde, E.
Lee, J.
Sinclair, M.
Sochi, T.
Goyal, A.
Vigueras, G.
Nordsletten, D. A.
Smith, N. P
Hoskins, Peter
Doyle, Barry
Pankaj, Pankaj
Nithiarasu, Perumal - Abstract:
- <abstract abstract-type="main" id="cnm2520-abs-0001"> <title>SUMMARY</title> <p id="cnm2520-para-0001">We present a method to efficiently simulate coronary perfusion in subject‐specific models of the heart within clinically relevant time frames. Perfusion is modelled as a Darcy porous‐media flow, where the permeability tensor is derived from homogenization of an explicit anatomical representation of the vasculature. To account for the disparity in length scales present in the vascular network, in this study, this approach is further refined through the implementation of a multi‐compartment medium where each compartment encapsulates the spatial scales in a certain range by using an effective permeability tensor. Neighbouring compartments then communicate through distributed sources and sinks, acting as volume fluxes. Although elegant from a modelling perspective, the full multi‐compartment Darcy system is computationally expensive to solve. We therefore enhance computational efficiency of this model by reducing the <italic>N</italic>‐compartment system of Darcy equations to <italic>N</italic> pressure equations, and <italic>N</italic> subsequent projection problems to recover the Darcy velocity. The resulting 'reduced' Darcy formulation leads to a dramatic reduction in algebraic‐system size and is therefore computationally cheaper to solve than the full multi‐compartment Darcy system. A comparison of the reduced and the full formulation in terms of solution time and memory<abstract abstract-type="main" id="cnm2520-abs-0001"> <title>SUMMARY</title> <p id="cnm2520-para-0001">We present a method to efficiently simulate coronary perfusion in subject‐specific models of the heart within clinically relevant time frames. Perfusion is modelled as a Darcy porous‐media flow, where the permeability tensor is derived from homogenization of an explicit anatomical representation of the vasculature. To account for the disparity in length scales present in the vascular network, in this study, this approach is further refined through the implementation of a multi‐compartment medium where each compartment encapsulates the spatial scales in a certain range by using an effective permeability tensor. Neighbouring compartments then communicate through distributed sources and sinks, acting as volume fluxes. Although elegant from a modelling perspective, the full multi‐compartment Darcy system is computationally expensive to solve. We therefore enhance computational efficiency of this model by reducing the <italic>N</italic>‐compartment system of Darcy equations to <italic>N</italic> pressure equations, and <italic>N</italic> subsequent projection problems to recover the Darcy velocity. The resulting 'reduced' Darcy formulation leads to a dramatic reduction in algebraic‐system size and is therefore computationally cheaper to solve than the full multi‐compartment Darcy system. A comparison of the reduced and the full formulation in terms of solution time and memory usage clearly highlights the superior performance of the reduced formulation. Moreover, the implementation of flux and, specifically, impermeable boundary conditions on arbitrarily curved boundaries such as epicardium and endocardium is straightforward in contrast to the full Darcy formulation. Finally, to demonstrate the applicability of our methodology to a personalized model and its solvability in clinically relevant time frames, we simulate perfusion in a subject‐specific model of the left ventricle. Copyright © 2012 John Wiley &amp; Sons, Ltd.</p> </abstract> … (more)
- Is Part Of:
- International journal for numerical methods in biomedical engineering. Volume 29:Number 2(2013:Feb.)
- Journal:
- International journal for numerical methods in biomedical engineering
- Issue:
- Volume 29:Number 2(2013:Feb.)
- Issue Display:
- Volume 29, Issue 2 (2013)
- Year:
- 2013
- Volume:
- 29
- Issue:
- 2
- Issue Sort Value:
- 2013-0029-0002-0000
- Page Start:
- 217
- Page End:
- 232
- Publication Date:
- 2012-10-18
- Subjects:
- Biomedical engineering -- Periodicals
Imaging systems in medicine -- Periodicals
Numerical analysis -- Periodicals
Engineering mathematics -- Periodicals
610.28 - Journal URLs:
- http://onlinelibrary.wiley.com/journal/10.1002/(ISSN)2040-7947 ↗
http://onlinelibrary.wiley.com/ ↗ - DOI:
- 10.1002/cnm.2520 ↗
- Languages:
- English
- ISSNs:
- 2040-7939
- Deposit Type:
- Legaldeposit
- View Content:
- Available online (eLD content is only available in our Reading Rooms) ↗
- Physical Locations:
- British Library DSC - 4542.403550
British Library DSC - BLDSS-3PM
British Library HMNTS - ELD Digital store - Ingest File:
- 3508.xml