Your search keyword '"Virot, E."' showing total 2 results

1. Elastohydrodynamic Scaling Law for Heart Rates

Author

Virot, E, Spandan, V, Niu, L, van Rees, WM, Mahadevan, L, Virot, E, Spandan, V, Niu, L, van Rees, WM, and Mahadevan, L

Abstract

© 2020 American Physical Society. Animal hearts are soft shells that actively pump blood to oxygenate tissues. Here, we propose an allometric scaling law for the heart rate based on the idea of elastohydrodynamic resonance of a fluid-loaded soft active elastic shell that buckles and contracts axially when twisted periodically. We show that this picture is consistent with numerical simulations of soft cylindrical shells that twist-buckle while pumping a viscous fluid, yielding optimum ejection fractions of 35%-40% when driven resonantly. Our scaling law is consistent with experimental measurements of heart rates over 2 orders of magnitude, and provides a mechanistic basis for how metabolism scales with organism size. In addition to providing a physical rationale for the heart rate and metabolism of an organism, our results suggest a simple design principle for soft fluidic pumps.

Published

2022

2. Elastohydrodynamic Scaling Law for Heart Rates

Author

Massachusetts Institute of Technology. Department of Mechanical Engineering, Virot, E, Spandan, V, Niu, L, Van Rees, Willem Marinus, Mahadevan, L, Massachusetts Institute of Technology. Department of Mechanical Engineering, Virot, E, Spandan, V, Niu, L, Van Rees, Willem Marinus, and Mahadevan, L

Abstract

© 2020 American Physical Society. Animal hearts are soft shells that actively pump blood to oxygenate tissues. Here, we propose an allometric scaling law for the heart rate based on the idea of elastohydrodynamic resonance of a fluid-loaded soft active elastic shell that buckles and contracts axially when twisted periodically. We show that this picture is consistent with numerical simulations of soft cylindrical shells that twist-buckle while pumping a viscous fluid, yielding optimum ejection fractions of 35%-40% when driven resonantly. Our scaling law is consistent with experimental measurements of heart rates over 2 orders of magnitude, and provides a mechanistic basis for how metabolism scales with organism size. In addition to providing a physical rationale for the heart rate and metabolism of an organism, our results suggest a simple design principle for soft fluidic pumps.

Published

2022