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Modelling extracellular matrix and cellular contributions to whole muscle mechanics
Skeletal muscle tissue has a highly complex and heterogeneous structure comprising several physical length scales. In the simplest model of muscle tissue, it can be represented as a one dimensional nonlinear spring in the direction of muscle fibres. However, at the finest level, muscle tissue includ...
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| Published in: | PloS one 2021-04, Vol.16 (4), p.e0249601-e0249601 |
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| creator | Konno, Ryan N Nigam, Nilima Wakeling, James M |
| description | Skeletal muscle tissue has a highly complex and heterogeneous structure comprising several physical length scales. In the simplest model of muscle tissue, it can be represented as a one dimensional nonlinear spring in the direction of muscle fibres. However, at the finest level, muscle tissue includes a complex network of collagen fibres, actin and myosin proteins, and other cellular materials. This study shall derive an intermediate physical model which encapsulates the major contributions of the muscle components to the elastic response apart from activation-related along-fibre responses. The micro-mechanical factors in skeletal muscle tissue (eg. connective tissue, fluid, and fibres) can be homogenized into one material aggregate that will capture the behaviour of the combination of material components. In order to do this, the corresponding volume fractions for each type of material need to be determined by comparing the stress-strain relationship for a volume containing each material. This results in a model that accounts for the micro-mechanical features found in muscle and can therefore be used to analyze effects of neuro-muscular diseases such as cerebral palsy or muscular dystrophies. The purpose of this study is to construct a model of muscle tissue that, through choosing the correct material parameters based on experimental data, will accurately capture the mechanical behaviour of whole muscle. This model is then used to look at the impacts of the bulk modulus and material parameters on muscle deformation and strain energy-density distributions. |
| doi_str_mv | 10.1371/journal.pone.0249601 |
| format | article |
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In the simplest model of muscle tissue, it can be represented as a one dimensional nonlinear spring in the direction of muscle fibres. However, at the finest level, muscle tissue includes a complex network of collagen fibres, actin and myosin proteins, and other cellular materials. This study shall derive an intermediate physical model which encapsulates the major contributions of the muscle components to the elastic response apart from activation-related along-fibre responses. The micro-mechanical factors in skeletal muscle tissue (eg. connective tissue, fluid, and fibres) can be homogenized into one material aggregate that will capture the behaviour of the combination of material components. In order to do this, the corresponding volume fractions for each type of material need to be determined by comparing the stress-strain relationship for a volume containing each material. This results in a model that accounts for the micro-mechanical features found in muscle and can therefore be used to analyze effects of neuro-muscular diseases such as cerebral palsy or muscular dystrophies. The purpose of this study is to construct a model of muscle tissue that, through choosing the correct material parameters based on experimental data, will accurately capture the mechanical behaviour of whole muscle. This model is then used to look at the impacts of the bulk modulus and material parameters on muscle deformation and strain energy-density distributions.</description><identifier>ISSN: 1932-6203</identifier><identifier>EISSN: 1932-6203</identifier><identifier>DOI: 10.1371/journal.pone.0249601</identifier><identifier>PMID: 33798249</identifier><language>eng</language><publisher>United States: Public Library of Science</publisher><subject>Analysis ; Biology and Life Sciences ; Biomechanics ; Cellular proteins ; Connective tissue ; Continuum mechanics ; Density distribution ; Energy ; Energy distribution ; Experimental data ; Extracellular matrix ; Finite element analysis ; Finite element method ; Homogenization ; Mathematical models ; Mathematics ; Mechanical properties ; Mechanics ; Medicine and Health Sciences ; Muscles ; Musculoskeletal system ; Physical Sciences ; Physiological aspects ; Skeletal muscle ; Stiffness ; Strain ; Strain analysis ; Three dimensional models</subject><ispartof>PloS one, 2021-04, Vol.16 (4), p.e0249601-e0249601</ispartof><rights>COPYRIGHT 2021 Public Library of Science</rights><rights>2021 Konno et al. 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In the simplest model of muscle tissue, it can be represented as a one dimensional nonlinear spring in the direction of muscle fibres. However, at the finest level, muscle tissue includes a complex network of collagen fibres, actin and myosin proteins, and other cellular materials. This study shall derive an intermediate physical model which encapsulates the major contributions of the muscle components to the elastic response apart from activation-related along-fibre responses. The micro-mechanical factors in skeletal muscle tissue (eg. connective tissue, fluid, and fibres) can be homogenized into one material aggregate that will capture the behaviour of the combination of material components. In order to do this, the corresponding volume fractions for each type of material need to be determined by comparing the stress-strain relationship for a volume containing each material. This results in a model that accounts for the micro-mechanical features found in muscle and can therefore be used to analyze effects of neuro-muscular diseases such as cerebral palsy or muscular dystrophies. The purpose of this study is to construct a model of muscle tissue that, through choosing the correct material parameters based on experimental data, will accurately capture the mechanical behaviour of whole muscle. This model is then used to look at the impacts of the bulk modulus and material parameters on muscle deformation and strain energy-density distributions.</description><subject>Analysis</subject><subject>Biology and Life Sciences</subject><subject>Biomechanics</subject><subject>Cellular proteins</subject><subject>Connective tissue</subject><subject>Continuum mechanics</subject><subject>Density distribution</subject><subject>Energy</subject><subject>Energy distribution</subject><subject>Experimental data</subject><subject>Extracellular matrix</subject><subject>Finite element analysis</subject><subject>Finite element method</subject><subject>Homogenization</subject><subject>Mathematical models</subject><subject>Mathematics</subject><subject>Mechanical properties</subject><subject>Mechanics</subject><subject>Medicine and Health Sciences</subject><subject>Muscles</subject><subject>Musculoskeletal system</subject><subject>Physical Sciences</subject><subject>Physiological 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Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Konno, Ryan N</au><au>Nigam, Nilima</au><au>Wakeling, James M</au><au>Garcia Aznar, Jose Manuel</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Modelling extracellular matrix and cellular contributions to whole muscle mechanics</atitle><jtitle>PloS one</jtitle><addtitle>PLoS One</addtitle><date>2021-04-02</date><risdate>2021</risdate><volume>16</volume><issue>4</issue><spage>e0249601</spage><epage>e0249601</epage><pages>e0249601-e0249601</pages><issn>1932-6203</issn><eissn>1932-6203</eissn><abstract>Skeletal muscle tissue has a highly complex and heterogeneous structure comprising several physical length scales. In the simplest model of muscle tissue, it can be represented as a one dimensional nonlinear spring in the direction of muscle fibres. However, at the finest level, muscle tissue includes a complex network of collagen fibres, actin and myosin proteins, and other cellular materials. This study shall derive an intermediate physical model which encapsulates the major contributions of the muscle components to the elastic response apart from activation-related along-fibre responses. The micro-mechanical factors in skeletal muscle tissue (eg. connective tissue, fluid, and fibres) can be homogenized into one material aggregate that will capture the behaviour of the combination of material components. In order to do this, the corresponding volume fractions for each type of material need to be determined by comparing the stress-strain relationship for a volume containing each material. This results in a model that accounts for the micro-mechanical features found in muscle and can therefore be used to analyze effects of neuro-muscular diseases such as cerebral palsy or muscular dystrophies. The purpose of this study is to construct a model of muscle tissue that, through choosing the correct material parameters based on experimental data, will accurately capture the mechanical behaviour of whole muscle. This model is then used to look at the impacts of the bulk modulus and material parameters on muscle deformation and strain energy-density distributions.</abstract><cop>United States</cop><pub>Public Library of Science</pub><pmid>33798249</pmid><doi>10.1371/journal.pone.0249601</doi><tpages>e0249601</tpages><orcidid>https://orcid.org/0000-0003-1761-5266</orcidid><oa>free_for_read</oa></addata></record> |
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| subjects | Analysis Biology and Life Sciences Biomechanics Cellular proteins Connective tissue Continuum mechanics Density distribution Energy Energy distribution Experimental data Extracellular matrix Finite element analysis Finite element method Homogenization Mathematical models Mathematics Mechanical properties Mechanics Medicine and Health Sciences Muscles Musculoskeletal system Physical Sciences Physiological aspects Skeletal muscle Stiffness Strain Strain analysis Three dimensional models |
| title | Modelling extracellular matrix and cellular contributions to whole muscle mechanics |
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