MULTISCALE BIOMECH

"Multiscale Micro-to-Macro Material and Structural Models for Aortic Heart Valves: Native, Porcine and Prosthetic Valves"

 Coordinatore TEL AVIV UNIVERSITY 

 Organization address address: RAMAT AVIV
city: TEL AVIV
postcode: 69978

contact info
Titolo: Ms.
Nome: Lea
Cognome: Pais
Email: send email
Telefono: -8445
Fax: -9368

 Nazionalità Coordinatore Israel [IL]
 Totale costo 100˙000 €
 EC contributo 100˙000 €
 Programma FP7-PEOPLE
Specific programme "People" implementing the Seventh Framework Programme of the European Community for research, technological development and demonstration activities (2007 to 2013)
 Code Call FP7-PEOPLE-2007-4-3-IRG
 Funding Scheme MC-IRG
 Anno di inizio 2008
 Periodo (anno-mese-giorno) 2008-07-01   -   2012-06-30

 Partecipanti

# participant  country  role  EC contrib. [€] 
1    TEL AVIV UNIVERSITY

 Organization address address: RAMAT AVIV
city: TEL AVIV
postcode: 69978

contact info
Titolo: Ms.
Nome: Lea
Cognome: Pais
Email: send email
Telefono: -8445
Fax: -9368

IL (TEL AVIV) coordinator 0.00

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multiscale    porcine    simulations    tissue    introduce    predictive    native    modeling    leaflet    av    prosthetic    heterogeneous    nonlinear    structural    diseased    models    imagery    collagen    material    refined    mms    mechanical   

 Obiettivo del progetto (Objective)

'Aortic valve (AV) disease expressed by tissue inflammation and calcification is one of the major causes for cardiac related illness and deaths in the world. Calcific stenosis leads to leaflet stiffening and abnormal AV mechanical-structural performance: larger deformation gradients and stresses. Current AV computational models are somewhat qualitative and do not capture the local complex nonlinear tissue and structural behaviors. Nonlinear multiscale (heterogeneous) material and structural (MMS) models have been developed and used in the analysis of many traditional and advanced engineering materials. These MMS modeling approaches can also be used for the analysis of biomaterials and bio-systems. New refined MMS models for the AV tissue will be developed at the microscale that can be integrated for the mechanical analysis of the AV structure at the macroscale. The overall goal is to introduce refined MMS for predictive simulations of native, porcine and a class of prosthetic AVs under in vitro pulsatile flow conditions. The proposed predictive modeling framework will be verified using sophisticated imagery measurements to examine the kinematics and deformations of both normal and stiffened (diseased) porcine AV systems. A major aspect of this proposal is to introduce new heterogeneous material models for the prosthetic and native leaflet tissue to be used in the AV-MMS simulations. The new modeling approach employs collagen fiber network (CFN) discrete multiscale model depicting the actual bundles of collagen fibers embedded in the leaflet. The in-situ elastin and collagen mechanical properties are explicitly recognized and a unit-cell (UC) micromechanical modeling approach is used to back-calculate (inverse problem) their properties from traditional tissue tensile tests. The proposed MMS is an important research tool towards imagery-based diagnostics of diseased native AV. This paradigm will also allow better design of new prosthetic AV systems.'

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