TY - GEN
T1 - Load-dependency in mechanical properties of subepicardial and subendocardial cardiomyocytes
AU - Khokhlova, Anastasia
AU - Iribe, Gentaro
AU - Solovyova, Olga
PY - 2015/2/16
Y1 - 2015/2/16
N2 - Electrical and mechanical properties of myocardium vary transmurally in the left ventricular wall. Regional differences in the mechanical environment of cardiomyocytes may potentially contribute to this heterogeneity due to mechano-electric feedback. In the present study, we investigate transmural differences in active and passive tensions at different preloads between the subepicardial (EPI) and subendocardial (ENDO) cells isolated from mouse left ventricle, using our recently developed single cell stretch method where each cell end was held by a pair of carbon fibers to apply various extent of preload to the cells. To predict underlying mechanisms of the transmural differences, we used our electromechanical EPI and ENDO cell models to simulate experimentally obtained results. Wet experiments showed that both passive and active tensions at different preloads are higher in ENDO cardiomyocytes, indicating higher stiffness and contractility in ENDO cells compared to EPI cells. Our mathematical models reproduce experimental results, suggesting differences in the kinetics of cross bridges and calcium-troponin C complexes in ENDO and EPI models may essentially contribute to the differences in mechanical properties between the cells.
AB - Electrical and mechanical properties of myocardium vary transmurally in the left ventricular wall. Regional differences in the mechanical environment of cardiomyocytes may potentially contribute to this heterogeneity due to mechano-electric feedback. In the present study, we investigate transmural differences in active and passive tensions at different preloads between the subepicardial (EPI) and subendocardial (ENDO) cells isolated from mouse left ventricle, using our recently developed single cell stretch method where each cell end was held by a pair of carbon fibers to apply various extent of preload to the cells. To predict underlying mechanisms of the transmural differences, we used our electromechanical EPI and ENDO cell models to simulate experimentally obtained results. Wet experiments showed that both passive and active tensions at different preloads are higher in ENDO cardiomyocytes, indicating higher stiffness and contractility in ENDO cells compared to EPI cells. Our mathematical models reproduce experimental results, suggesting differences in the kinetics of cross bridges and calcium-troponin C complexes in ENDO and EPI models may essentially contribute to the differences in mechanical properties between the cells.
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U2 - 10.1109/CIC.2015.7411073
DO - 10.1109/CIC.2015.7411073
M3 - Conference contribution
AN - SCOPUS:84963994850
T3 - Computing in Cardiology
SP - 965
EP - 968
BT - Computing in Cardiology Conference 2015, CinC 2015
A2 - Murray, Alan
PB - IEEE Computer Society
T2 - 42nd Computing in Cardiology Conference, CinC 2015
Y2 - 6 September 2015 through 9 September 2015
ER -