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

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.

[1]  M R Drost,et al.  Finite element modelling of contracting skeletal muscle. , 2003, Philosophical transactions of the Royal Society of London. Series B, Biological sciences.

[2]  Gisela Sjøgaard,et al.  Muscle blood flow during isometric activity and its relation to muscle fatigue , 2004, European Journal of Applied Physiology and Occupational Physiology.

[3]  G. R. Liu,et al.  Chapter 3 – Fundamentals for Finite Element Method , 2014 .

[4]  W. Herzog,et al.  The mechanics of agonistic muscles. , 2018, Journal of Biomechanics.

[5]  J. Fernandez,et al.  A diffusion-weighted imaging informed continuum model of the rabbit triceps surae complex , 2017, Biomechanics and modeling in mechanobiology.

[6]  D. Claflin,et al.  Intrinsic stiffness of extracellular matrix increases with age in skeletal muscles of mice. , 2014, Journal of applied physiology.

[7]  Samuel R Ward,et al.  Whole muscle length-tension relationships are accurately modeled as scaled sarcomeres in rabbit hindlimb muscles. , 2011, Journal of biomechanics.

[8]  W. Barnes,et al.  The relationship between maximum isometric strength and intramuscular circulatory occlusion. , 1980, Ergonomics.

[9]  J. Weiss,et al.  Finite element implementation of incompressible, transversely isotropic hyperelasticity , 1996 .

[10]  C. Yucesoy,et al.  Magnetic resonance and diffusion tensor imaging analyses indicate heterogeneous strains along human medial gastrocnemius fascicles caused by submaximal plantar-flexion activity. , 2017, Journal of biomechanics.

[11]  Reinhard Blickhan,et al.  Force reduction induced by unidirectional transversal muscle loading is independent of local pressure. , 2016, Journal of biomechanics.

[12]  N. Curtin,et al.  Energetic aspects of muscle contraction. , 1985, Monographs of the Physiological Society.

[13]  James M. Wakeling,et al.  Muscle gearing during isotonic and isokinetic movements in the ankle plantarflexors , 2012, European Journal of Applied Physiology.

[14]  James M Wakeling,et al.  The effect of external compression on the mechanics of muscle contraction. , 2013, Journal of applied biomechanics.

[15]  J. C. Simo,et al.  Quasi-incompressible finite elasticity in principal stretches. Continuum basis and numerical algorithms , 1991 .

[16]  J. Wakeling,et al.  Multidimensional models for predicting muscle structure and fascicle pennation. , 2015, Journal of theoretical biology.

[17]  Christian Rode,et al.  A hill-type muscle model expansion accounting for effects of varying transverse muscle load. , 2018, Journal of biomechanics.

[18]  Sabrina S. M. Lee,et al.  Quantifying changes in material properties of stroke-impaired muscle. , 2015, Clinical biomechanics.

[19]  Ghassan Hamarneh,et al.  3D fascicle orientations in triceps surae. , 2013, Journal of applied physiology.

[20]  Gennadiy Nikishkov,et al.  Finite Element Model , 2010 .

[21]  A. Hill The heat of shortening and the dynamic constants of muscle , 1938 .

[22]  A. Garrod Animal Locomotion , 1874, Nature.

[23]  T. Roberts,et al.  Variable gearing in pennate muscles , 2008, Proceedings of the National Academy of Sciences.

[24]  Milos Kojic,et al.  Finite element modelling of skeletal muscles coupled with fatigue , 2007 .

[25]  B. Bressler Energetic Aspects of Muscle Contraction. Monographs of the Physiological Society, Number 41.Roger C. Woledge , Nancy A. Curtin , Earl Homsher , 1986 .

[26]  F. Zajac,et al.  Nonuniform shortening in the biceps brachii during elbow flexion. , 2002, Journal of applied physiology.

[27]  S. Delp,et al.  A 3D model of muscle reveals the causes of nonuniform strains in the biceps brachii. , 2005, Journal of biomechanics.

[28]  T. Roberts,et al.  Mechanical properties of the gastrocnemius aponeurosis in wild turkeys. , 2009, Integrative and comparative biology.

[29]  Kevin M. Moerman,et al.  GIBBON: The Geometry and Image-Based Bioengineering add-On , 2018, J. Open Source Softw..

[30]  T. Roberts,et al.  Incompressible fluid plays a mechanical role in the development of passive muscle tension , 2017, Biology Letters.

[31]  C. Simms,et al.  The in vitro passive elastic response of chicken pectoralis muscle to applied tensile and compressive deformation. , 2016, Journal of the mechanical behavior of biomedical materials.

[32]  Sheng-Wei Chi,et al.  Finite element modeling of passive material influence on the deformation and force output of skeletal muscle. , 2012, Journal of the mechanical behavior of biomedical materials.

[33]  Matthew Cobb,et al.  Exorcizing the animal spirits: Jan Swammerdam on nerve function , 2002, Nature Reviews Neuroscience.

[34]  Max A. Viergever,et al.  elastix: A Toolbox for Intensity-Based Medical Image Registration , 2010, IEEE Transactions on Medical Imaging.

[35]  James M. Wakeling,et al.  Passive and dynamic muscle architecture during transverse loading for gastrocnemius medialis in man. , 2019, Journal of biomechanics.

[36]  J. C. Simo,et al.  Variational and projection methods for the volume constraint in finite deformation elasto-plasticity , 1985 .

[37]  Maike Sturmat,et al.  Three-dimensional surface geometries of the rabbit soleus muscle during contraction: input for biomechanical modelling and its validation , 2013, Biomechanics and modeling in mechanobiology.

[38]  David Bradley,et al.  The Physiology of Excitable Cells, 4th edn. By DAVID J. AIDLEY. (Pp. xii+477; illustrated; £70/$95 hardback, £24.95/$47.95 paperback; ISBN 0 521 57415 3 hardback, 0 521 57421 8 paperback.) Cambridge: Cambridge University Press. 1998. , 1999 .

[39]  B. Koopman,et al.  Three-dimensional finite element modeling of skeletal muscle using a two-domain approach: linked fiber-matrix mesh model. , 2001, Journal of biomechanics.

[40]  Andrew A Biewener,et al.  Functional diversification within and between muscle synergists during locomotion , 2008, Biology Letters.

[41]  James M. Wakeling,et al.  Transverse Strains in Muscle Fascicles during Voluntary Contraction: A 2D Frequency Decomposition of B-Mode Ultrasound Images , 2014, Int. J. Biomed. Imaging.

[42]  O. Yeoh Some Forms of the Strain Energy Function for Rubber , 1993 .

[43]  Ciaran K Simms,et al.  A structural model of passive skeletal muscle shows two reinforcement processes in resisting deformation. , 2013, Journal of the mechanical behavior of biomedical materials.

[44]  O. Schmitt The heat of shortening and the dynamic constants of muscle , 2017 .

[45]  D. Louis Collins,et al.  Diffusion Weighted Image Denoising Using Overcomplete Local PCA , 2013, PloS one.

[46]  J. Fridén,et al.  Muscle contracture and passive mechanics in cerebral palsy. , 2019, Journal of applied physiology.

[47]  E. Azizi,et al.  Resistance to radial expansion limits muscle strain and work , 2017, Biomechanics and modeling in mechanobiology.

[48]  S R Taylor,et al.  Nonuniform volume changes during muscle contraction. , 1991, Biophysical journal.

[49]  James M. Wakeling,et al.  A modelling approach for exploring muscle dynamics during cyclic contractions , 2018, PLoS Comput. Biol..

[50]  Bart Bolsterlee,et al.  Reliability and robustness of muscle architecture measurements obtained using diffusion tensor imaging with anatomically constrained tractography. , 2019, Journal of biomechanics.

[51]  David Wells,et al.  The deal.II library, version 8.5 , 2013, J. Num. Math..

[52]  Michael Günther,et al.  A 3D-geometric model for the deformation of a transversally loaded muscle. , 2012, Journal of theoretical biology.

[53]  Markus Böl,et al.  Micromechanical modelling of skeletal muscles based on the finite element method , 2008, Computer Methods in Biomechanics and Biomedical Engineering.

[54]  Thomas L. Daniel,et al.  Axial and Radial Forces of Cross-Bridges Depend on Lattice Spacing , 2010, PLoS Comput. Biol..

[55]  Maike Sturmat,et al.  A new approach for the validation of skeletal muscle modelling using MRI data , 2011 .

[56]  C. Gregorio,et al.  Muscle assembly: a titanic achievement? , 1999, Current opinion in cell biology.

[57]  Reinhard Blickhan,et al.  Work partitioning of transversally loaded muscle: experimentation and simulation , 2014, Computer methods in biomechanics and biomedical engineering.

[58]  Sheng-Wei Chi,et al.  Finite element modeling reveals complex strain mechanics in the aponeuroses of contracting skeletal muscle. , 2010, Journal of biomechanics.

[59]  Timothy D. Verstynen,et al.  Deterministic Diffusion Fiber Tracking Improved by Quantitative Anisotropy , 2013, PloS one.

[60]  Elizabeth L Brainerd,et al.  Muscle fiber angle, segment bulging and architectural gear ratio in segmented musculature , 2005, Journal of Experimental Biology.

[61]  A. Anderson,et al.  Validation of diffusion tensor MRI‐based muscle fiber tracking , 2002, Magnetic resonance in medicine.

[62]  T. Fukunaga,et al.  Architectural and functional features of human triceps surae muscles during contraction. , 1998, Journal of applied physiology.

[63]  J C Gardiner,et al.  Simple shear testing of parallel-fibered planar soft tissues. , 2001, Journal of biomechanical engineering.

[64]  A. Arnold,et al.  Quantifying Achilles tendon force in vivo from ultrasound images. , 2016, Journal of biomechanics.

[65]  C. Yucesoy,et al.  Combined magnetic resonance and diffusion tensor imaging analyses provide a powerful tool for in vivo assessment of deformation along human muscle fibers. , 2016, Journal of the mechanical behavior of biomedical materials.

[66]  J. Wakeling,et al.  Shifting gears: dynamic muscle shape changes and force-velocity behavior in the medial gastrocnemius. , 2017, Journal of applied physiology.

[67]  V. Edgerton,et al.  Muscle architecture of the human lower limb. , 1983, Clinical orthopaedics and related research.

[68]  F. Zajac Muscle and tendon: properties, models, scaling, and application to biomechanics and motor control. , 1989, Critical reviews in biomedical engineering.

[69]  S. Gandevia,et al.  How does passive lengthening change the architecture of the human medial gastrocnemius muscle? , 2017, Journal of applied physiology.

[70]  David S. Ryan,et al.  Size, History-Dependent, Activation and Three-Dimensional Effects on the Work and Power Produced During Cyclic Muscle Contractions. , 2018, Integrative and comparative biology.

[71]  J. Wakeling,et al.  Regionalizing muscle activity causes changes to the magnitude and direction of the force from whole muscles—a modeling study , 2014, Front. Physiol..

[72]  Nilima Nigam,et al.  The effect of intramuscular fat on skeletal muscle mechanics: implications for the elderly and obese , 2015, Journal of The Royal Society Interface.

[73]  Jiun-Shyan Chen,et al.  Pixel-based meshfree modelling of skeletal muscles , 2016, Comput. methods Biomech. Biomed. Eng. Imaging Vis..

[74]  Peter P. Purslow,et al.  The morphology and mechanical properties of endomysium in series-fibred muscles: variations with muscle length , 1994, Journal of Muscle Research & Cell Motility.

[75]  R. Lieber,et al.  Cellular mechanisms of tissue fibrosis. 4. Structural and functional consequences of skeletal muscle fibrosis. , 2013, American journal of physiology. Cell physiology.

[76]  C. Maganaris,et al.  In vivo measurements of the triceps surae complex architecture in man: implications for muscle function , 1998, The Journal of physiology.

[77]  Sabrina S. M. Lee,et al.  Movement mechanics as a determinate of muscle structure, recruitment and coordination , 2011, Philosophical Transactions of the Royal Society B: Biological Sciences.

[78]  J. Fridén,et al.  Functional and clinical significance of skeletal muscle architecture , 2000, Muscle & nerve.

[79]  James M Wakeling,et al.  Transverse anisotropy in the deformation of the muscle during dynamic contractions , 2018, Journal of Experimental Biology.

[80]  P. Huijing,et al.  Changes in geometry of activily shortening unipennate rat gastrocnemius muscle , 1993, Journal of morphology.

[81]  James M Wakeling,et al.  Muscle shortening velocity depends on tissue inertia and level of activation during submaximal contractions , 2016, Biology Letters.

[82]  James M. Wakeling,et al.  Passive Muscle-Tendon Unit Gearing Is Joint Dependent in Human Medial Gastrocnemius , 2016, Front. Physiol..

[83]  Syn Schmitt,et al.  Spreading out Muscle Mass within a Hill-Type Model: A Computer Simulation Study , 2012, Comput. Math. Methods Medicine.

[84]  R. Marsh,et al.  The Multi-Scale, Three-Dimensional Nature of Skeletal Muscle Contraction. , 2019, Physiology.

[85]  Richard L Lieber,et al.  Elucidation of extracellular matrix mechanics from muscle fibers and fiber bundles. , 2011, Journal of biomechanics.

[86]  Markus Böl,et al.  Compressive properties of passive skeletal muscle-the impact of precise sample geometry on parameter identification in inverse finite element analysis. , 2012, Journal of biomechanics.

[87]  R. Herbert,et al.  Behavior of human gastrocnemius muscle fascicles during ramped submaximal isometric contractions , 2016, Physiological reports.

[88]  P. Huijing,et al.  Specifically tailored use of the finite element method to study muscular mechanics within the context of fascial integrity: the linked fiber-matrix mesh model , 2012 .

[89]  R. Blickhan,et al.  A finite-element model for the mechanical analysis of skeletal muscles. , 2000, Journal of theoretical biology.

[90]  A. Pullan,et al.  Three-dimensional finite element modelling of muscle forces during mastication. , 2007, Journal of biomechanics.

[91]  Lucas R. Smith,et al.  Muscle extracellular matrix applies a transverse stress on fibers with axial strain. , 2011, Journal of biomechanics.

[92]  Brent J. Raiteri,et al.  Three-dimensional geometrical changes of the human tibialis anterior muscle and its central aponeurosis measured with three-dimensional ultrasound during isometric contractions , 2016, PeerJ.

[93]  Thomas L. Daniel,et al.  Elastic Energy Storage and Radial Forces in the Myofilament Lattice Depend on Sarcomere Length , 2012, PLoS Comput. Biol..

[94]  C. Gans,et al.  The functional significance of muscle architecture--a theoretical analysis. , 1965, Ergebnisse der Anatomie und Entwicklungsgeschichte.