Regional heterogeneity in muscle fiber strain: the role of fiber architecture

Regional heterogeneity in muscle fiber strain: the role of fiber architecture

The force, mechanical work and power produced by muscle fibers are profoundly affected by the length changes they undergo during a contraction. These length changes are in turn affected by the spatial orientation of muscle fibers within a muscle (fiber architecture). Therefore any heterogeneity in f...

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Bibliographic Details
Published in:Frontiers in physiology Vol. 5; p. 303
Main Authors: Azizi, E, Deslauriers, Amber R
Format: Journal Article
Language:English
Published: Switzerland Frontiers Media S.A 12-08-2014
Subjects:
Fusiform muscles
muscle architecture
muscle bulging
Physiology
Pinnate
strain differences
pinnate
muscle bulging
muscle architecture
fusiform muscles
strain differences
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Summary:The force, mechanical work and power produced by muscle fibers are profoundly affected by the length changes they undergo during a contraction. These length changes are in turn affected by the spatial orientation of muscle fibers within a muscle (fiber architecture). Therefore any heterogeneity in fiber architecture within a single muscle has the potential to cause spatial variation in fiber strain. Here we examine how the architectural variation within a pennate muscle and within a fusiform muscle can result in regional fiber strain heterogeneity. We combine simple geometric models with empirical measures of fiber strain to better understand the effect of architecture on fiber strain heterogeneity. We show that variation in pennation angle throughout a muscle can result in differences in fiber strain with higher strains being observed at lower angles of pennation. We also show that in fusiform muscles, the outer/superficial fibers of the muscle experience lower strains than central fibers. These results show that regional variation in mechanical output of muscle fibers can arise solely from architectural features of the muscle without the presence of any spatial variation in motor recruitment.
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This article was submitted to Integrative Physiology, a section of the journal Frontiers in Physiology.
Reviewed by: Boris Prilutsky, Georgia Institute of Technology, USA; Glen Lichtwark, The University of Queensland, Australia
Edited by: Emma F. Hodson-Tole, Manchester Metropolitan University, UK
ISSN:1664-042X
1664-042X
DOI:10.3389/fphys.2014.00303