Abstract
In this contribution we create three-dimensional (3D) finite element models from a series of histological sections of porcine skeletal muscle tissue. Image registration is performed on the stained sections by affinely aligning them using auxiliary markers, followed by image segmentation to determine muscle fibres and the extracellular matrix in each section, with particular regard to the continuity of the fibres through the stack. With this information, 3D virtual tissue samples are reconstructed, discretised, and associated with appropriate non-linear elastic anisotropic material models. While the gross anatomy is directly obtained from the images, the local directions of anisotropy were determined by the use of an analogy with steady state diffusion. The influence of the number of histological sections considered for reconstruction on the numerically simulated mechanical response of the virtual tissue samples is then studied. The results show that muscle tissue is fairly heterogeneous along the fascicles, and that transverse isotropy is inadequate in describing their material symmetry at the typical length scale of a fascicle. Numerical simulations of different load cases suggest that ignoring the undulations of fibres and their non-uniform cross-sections only moderately affects the passive response of the tissue in tensile and compressive modes, but can become crucial when predicting the response to generic loads and activation.
Highlights
Skeletal muscles are responsible for generation of force, motion, and gait stability (Barrett et al, 2016; Lieber, 2002)
Fascicles, and the whole muscle, respectively, are embedded into a continuous network of collagenous sheaths arranged into endomysium, perimysium, and epimysium that collectively, together with other constituents, form the muscle’s extracellular matrix (ECM) (Lieber, 2002)
The presence of such intricate micro-structure naturally suggests that it could play a pivotal role in the material symmetry, mechanical response, and physiological load transfer mechanisms in skeletal muscle tissue
Summary
Skeletal muscles are responsible for generation of force, motion, and gait stability (Barrett et al, 2016; Lieber, 2002). Fascicles, and the whole muscle, respectively, are embedded into a continuous network of collagenous sheaths arranged into endomysium, perimysium, and epimysium that collectively, together with other constituents, form the muscle’s extracellular matrix (ECM) (Lieber, 2002) The presence of such intricate micro-structure naturally suggests that it could play a pivotal role in the material symmetry, mechanical response, and physiological load transfer mechanisms in skeletal muscle tissue. This causes large variation in muscle fibre sizes resulting in diminished muscle function and causing muscle wastage (Briguet et al, 2004; Emery, 2002)
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