Bart Bolsterlee scite author profile

During contraction the energy of muscle tissue increases due to energy from the hydrolysis of ATP. This energy is distributed across the tissue as strain-energy potentials in the contractile elements, strain-energy potential from the 3D deformation of the base-material tissue (containing cellular and extracellular matrix effects), energy related to changes in the muscle's nearly incompressible volume and external work done at the muscle surface. Thus, energy is redistributed through the muscle's tissue as it contracts, with only a component of this energy being used to do mechanical work and develop forces in the muscle's longitudinal direction. Understanding how the strain-energy potentials are redistributed through the muscle tissue will help enlighten why the mechanical performance of whole muscle in its longitudinal direction does not match the performance that would be expected from the contractile elements alone. Here we demonstrate these physical effects using a 3D muscle model based on the finite element method. The tissue deformations within contracting muscle are large, and so the mechanics of contraction were explained using the principles of continuum mechanics for large deformations. We present simulations of a contracting medial gastrocnemius muscle, showing tissue deformations that mirror observations from magnetic resonance imaging. This paper tracks the redistribution of strain-energy potentials through the muscle tissue during fixed-end contractions, and shows how fibre shortening, pennation angle, transverse bulging and anisotropy in the stress and strain of the muscle tissue are all related to the interaction between the material properties of the muscle and the action of the contractile elements.

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Reliability and robustness of muscle architecture measurements obtained using diffusion tensor imaging with anatomically constrained tractography

Bolsterlee

D’Souza

Herbert

2019

Journal of Biomechanics

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Comparison of measurements of medial gastrocnemius architectural parameters from ultrasound and diffusion tensor images

Bolsterlee

Veeger

Helm

et al. 2015

Journal of Biomechanics

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Bart Bolsterlee

The Energy of Muscle Contraction. I. Tissue Force and Deformation During Fixed-End Contractions

Reliability and robustness of muscle architecture measurements obtained using diffusion tensor imaging with anatomically constrained tractography

Comparison of measurements of medial gastrocnemius architectural parameters from ultrasound and diffusion tensor images

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