An extended pulse wave propagation model to predict (patho-)physiological coronary pressure and flow patterns

Onderzoeksoutput: Hoofdstuk in Boek/Rapport/CongresprocedureConferentiebijdrageAcademicpeer review

Uittreksel

A patient-specific model describing the primary relations between the cardiac muscle contraction and coronary circulation might be useful for interpreting coronary hemodynamics and deciding on medical treatment in case multiple types of coronary circulatory disease are present. For this purpose we present the use of a microstructure-based heart contraction model and a micro-structure based fiber reinforced arterial wall model as the basis of a 1D wave propagation model to describe coronary pressure and flow waves. We conclude that this extended pulse wave propagation model adequately can predict coronary hemodynamics in both normal and diseased state based on patient-specific clinical data.
Originele taal-2Engels
Titel3rd International Conference on Computational and Mathematical Biomedical Engineering,
RedacteurenP. Nithiarasu, R. Löhner
UitgeverijCMBE
Pagina's261-264
ISBN van geprinte versie978-0-9562914-2-4
StatusGepubliceerd - 2013
Evenement3rd International Conference on Computational & Mathematical Biomedical Engineering (CMBE13) - City University of Hong Kong, Hong Kong, China
Duur: 16 dec 201318 dec 2013
http://www.compbiomed.net/2013/

Congres

Congres3rd International Conference on Computational & Mathematical Biomedical Engineering (CMBE13)
Verkorte titelCMBE13
LandChina
StadHong Kong
Periode16/12/1318/12/13
AnderInternational Conference on Computational and Mathematical Biomedical Engineering
Internet adres

Vingerafdruk

wave propagation
flow distribution
pulses
hemodynamics
coronary circulation
muscular function
microstructure
elastic waves
contraction
fibers

Citeer dit

Vosse, van de, F. N., van der Horst, A., & Rutten, M. C. M. (2013). An extended pulse wave propagation model to predict (patho-)physiological coronary pressure and flow patterns. In P. Nithiarasu, & R. Löhner (editors), 3rd International Conference on Computational and Mathematical Biomedical Engineering, (blz. 261-264). CMBE.
Vosse, van de, F.N. ; van der Horst, A. ; Rutten, M.C.M. / An extended pulse wave propagation model to predict (patho-)physiological coronary pressure and flow patterns. 3rd International Conference on Computational and Mathematical Biomedical Engineering,. redacteur / P. Nithiarasu ; R. Löhner. CMBE, 2013. blz. 261-264
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title = "An extended pulse wave propagation model to predict (patho-)physiological coronary pressure and flow patterns",
abstract = "A patient-specific model describing the primary relations between the cardiac muscle contraction and coronary circulation might be useful for interpreting coronary hemodynamics and deciding on medical treatment in case multiple types of coronary circulatory disease are present. For this purpose we present the use of a microstructure-based heart contraction model and a micro-structure based fiber reinforced arterial wall model as the basis of a 1D wave propagation model to describe coronary pressure and flow waves. We conclude that this extended pulse wave propagation model adequately can predict coronary hemodynamics in both normal and diseased state based on patient-specific clinical data.",
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Vosse, van de, FN, van der Horst, A & Rutten, MCM 2013, An extended pulse wave propagation model to predict (patho-)physiological coronary pressure and flow patterns. in P Nithiarasu & R Löhner (redactie), 3rd International Conference on Computational and Mathematical Biomedical Engineering,. CMBE, blz. 261-264, 3rd International Conference on Computational & Mathematical Biomedical Engineering (CMBE13), Hong Kong, China, 16/12/13.

An extended pulse wave propagation model to predict (patho-)physiological coronary pressure and flow patterns. / Vosse, van de, F.N.; van der Horst, A.; Rutten, M.C.M.

3rd International Conference on Computational and Mathematical Biomedical Engineering,. redactie / P. Nithiarasu; R. Löhner. CMBE, 2013. blz. 261-264.

Onderzoeksoutput: Hoofdstuk in Boek/Rapport/CongresprocedureConferentiebijdrageAcademicpeer review

TY - GEN

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N2 - A patient-specific model describing the primary relations between the cardiac muscle contraction and coronary circulation might be useful for interpreting coronary hemodynamics and deciding on medical treatment in case multiple types of coronary circulatory disease are present. For this purpose we present the use of a microstructure-based heart contraction model and a micro-structure based fiber reinforced arterial wall model as the basis of a 1D wave propagation model to describe coronary pressure and flow waves. We conclude that this extended pulse wave propagation model adequately can predict coronary hemodynamics in both normal and diseased state based on patient-specific clinical data.

AB - A patient-specific model describing the primary relations between the cardiac muscle contraction and coronary circulation might be useful for interpreting coronary hemodynamics and deciding on medical treatment in case multiple types of coronary circulatory disease are present. For this purpose we present the use of a microstructure-based heart contraction model and a micro-structure based fiber reinforced arterial wall model as the basis of a 1D wave propagation model to describe coronary pressure and flow waves. We conclude that this extended pulse wave propagation model adequately can predict coronary hemodynamics in both normal and diseased state based on patient-specific clinical data.

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Vosse, van de FN, van der Horst A, Rutten MCM. An extended pulse wave propagation model to predict (patho-)physiological coronary pressure and flow patterns. In Nithiarasu P, Löhner R, redacteurs, 3rd International Conference on Computational and Mathematical Biomedical Engineering,. CMBE. 2013. blz. 261-264