Title :
Estimation of in vivo human myocardial fibre strain by integrating diffusion tensor and tagged MRI using FE modelling
Author :
Wang, V.Y. ; Casta, C. ; Croisille, P. ; Clarysse, P. ; Zhu, Y.-M. ; Cowan, B.R. ; Young, A.A. ; Nash, M.P.
Author_Institution :
Auckland Bioeng. Inst., Univ. of Auckland, Auckland, New Zealand
Abstract :
In this study, we propose a methodology to estimate 3D+time maps of left ventricular fibre strain from human structural and dynamic MRI data. A finite element model integrates fibre principal direction throughout the left ventricle from an ex vivo human diffusion tensor MRI acquisition and motion from tagged MRI. This combination enables the estimation of fibre strain and its variation throughout the cardiac cycle. The long-term goal of this study is to apply this technique to an atlas of human fibre orientations and to investigate the importance of having subject-specific fibre orientation for fibre strain analysis.
Keywords :
biodiffusion; biomedical MRI; cardiology; finite element analysis; medical image processing; physiological models; 3D-time maps; FE modelling; cardiac cycle; dynamic MRI data; ex vivo human diffusion tensor MRI acquisition; ex vivo human diffusion tensor MRI motion; fibre principal direction; fibre strain analysis; finite element model; human fibre orientations; human structural data; in vivo human myocardial fibre strain estimation; left ventricular fibre strain; subject-specific fibre orientation; tagged MRI; Data models; Humans; In vivo; Iron; Magnetic resonance imaging; Myocardium; Strain; Diffusion Tensor MRI; FE modelling; Human cardiac fibre strain; tagged MRI;
Conference_Titel :
Biomedical Imaging (ISBI), 2012 9th IEEE International Symposium on
Conference_Location :
Barcelona
Print_ISBN :
978-1-4577-1857-1
DOI :
10.1109/ISBI.2012.6235480
