Please use this identifier to cite or link to this item: http://hdl.handle.net/2445/121862
Title: A two dimensional electromechanical model of a cardiomyocyte to assess intra-cellular regional mechanical heterogeneities.
Author: Garcia-Canadilla, Patricia
Rodriguez, Jose F.
Palazzi, Maria J.
González Tendero, Anna
Schönleitner, Patrick
Balicevic, Vedrana
Loncaric, Sven
Luiken, Joost J. F. P.
Ceresa, Mario
Camara, Oscar
Antoons, Gudrun
Crispi Brillas, Fàtima
Gratacós Solsona, Eduard
Bijnens, Bart
Keywords: Cor
Cèl·lules
Heart
Cells
Issue Date: 24-Aug-2017
Publisher: Public Library of Science (PLoS)
Abstract: Experimental studies on isolated cardiomyocytes from different animal species and human hearts have demonstrated that there are regional differences in the Ca2+ release, Ca2+ decay and sarcomere deformation. Local deformation heterogeneities can occur due to a combination of factors: regional/local differences in Ca2+ release and/or re-uptake, intra-cellular material properties, sarcomere proteins and distribution of the intracellular organelles. To investigate the possible causes of these heterogeneities, we developed a twodimensional finite-element electromechanical model of a cardiomyocyte that takes into account the experimentally measured local deformation and cytosolic [Ca2+] to locally define the different variables of the constitutive equations describing the electro/mechanical behaviour of the cell. Then, the model was individualised to three different rat cardiac cells. The local [Ca2+] transients were used to define the [Ca2+]-dependent activation functions. The cell-specific local Young's moduli were estimated by solving an inverse problem, minimizing the error between the measured and simulated local deformations along the longitudinal axis of the cell. We found that heterogeneities in the deformation during contraction were determined mainly by the local elasticity rather than the local amount of Ca2+, while in the relaxation phase deformation was mainly influenced by Ca2+ re-uptake. Our electromechanical model was able to successfully estimate the local elasticity along the longitudinal direction in three different cells. In conclusion, our proposed model seems to be a good approximation to assess the heterogeneous intracellular mechanical properties to help in the understanding of the underlying mechanisms of cardiomyocyte dysfunction.
Note: Reproducció del document publicat a: https://doi.org/10.1371/journal.pone.0182915
It is part of: PLoS One, 2017, vol. 12, num. 8, p. e0182915
URI: http://hdl.handle.net/2445/121862
Related resource: https://doi.org/10.1371/journal.pone.0182915
ISSN: 1932-6203
Appears in Collections:Articles publicats en revistes (Cirurgia i Especialitats Medicoquirúrgiques)

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