Architecture-based force-velocity models of load-moving skeletal muscles.

A predictive model of muscle force-velocity relationships is presented based on functional architectural variables. The parameters of Hill's equation describing muscle force-velocity relationship of nine muscles were estimated by their relationships with variables extracted from the whole-muscle length-force relationship and the percentage of slow-twitch fibres. Specifically, the maximal unloaded velocity (Vo) was estimated through multiple linear regression, from each muscle's fibre composition and the shortening range through which each muscle could produce active force. The maximal isometric force (Po) was also extracted from each muscle's length-force relationship. The ratio of Hill's dynamic constanta to Po and b to Vo, which determines the degree of curvature of the relation, was determined solely by the percent of slow-twitch fibres. This model was verified by fitting it to experimental force-velocity curves of nine different muscles in the cat's hindlimb. It was found that reasonable fits of force-velocity curves would be obtained with correlation coefficient in the range of 0.61 to 0.92, with an average of 0.82. The model predicted that muscles with relatively long shortening ranges would achieve higher maximal velocity, and that muscles with higher percentage of slow-twitch fibres had less pronounced curvature and lower maximal velocity in their force-velocity relationships. RELEVANCE: The results have direct implications in the design of neuroprosthetic limb control systems, which use electrical stimulation to restore function to muscles paralysed from spinal cord injury. The designer is enabled to optimally calibrate the controller according to the predicted individual force-velocity curves of different muscles by using the length-tension curves and fibre composition data available in the literature.

[1]  A. Seaber,et al.  The effect of muscle architecture on the biomechanical failure properties of skeletal muscle under passive extension , 1988, The American journal of sports medicine.

[2]  P A Huijing,et al.  Architecture of the human gastrocnemius muscle and some functional consequences. , 1985, Acta anatomica.

[3]  R. D'ambrosia,et al.  The isometric length-force models of nine different skeletal muscles. , 1992, Journal of biomechanics.

[4]  K. Edman The velocity of unloaded shortening and its relation to sarcomere length and isometric force in vertebrate muscle fibres. , 1979, The Journal of physiology.

[5]  V. Edgerton,et al.  HINDLIMB MUSCLE FIBER POPULATIONS OF FIVE MAMMALS , 1973 .

[6]  D. Claflin,et al.  The force‐velocity relationship at high shortening velocities in the soleus muscle of the rat. , 1989, The Journal of physiology.

[7]  J A Stephens,et al.  The motor units of cat medial gastrocnemius: Electrical and mechanical properties as a function of muscle length , 1975, Journal of morphology.

[8]  P A Huijing,et al.  Muscle architecture and fibre characteristics of rat gastrocnemius and semimembranosus muscles during isometric contractions. , 1989, Acta anatomica.

[9]  H. Iwamoto,et al.  Force‐velocity relation of frog skeletal muscle fibres shortening under continuously changing load. , 1990, The Journal of physiology.

[10]  Dynamic performance of a load-moving skeletal muscle. , 1991, Journal of applied physiology.

[11]  M. Solomonow,et al.  The dynamic response model of nine different skeletal muscles , 1990, IEEE Transactions on Biomedical Engineering.

[12]  R. Close Dynamic properties of mammalian skeletal muscles. , 1972, Physiological reviews.

[13]  Moshe Solomonow,et al.  External Control of the Neuromuscular System , 1984, IEEE Transactions on Biomedical Engineering.

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

[15]  W. O. Fenn,et al.  Muscular force at different speeds of shortening , 1935, The Journal of physiology.

[16]  M. Johnson,et al.  Data on the distribution of fibre types in thirty-six human muscles. An autopsy study. , 1973, Journal of the neurological sciences.

[17]  B. C. Abbott,et al.  The relation between velocity of shortening and the tension‐length curve of skeletal muscle , 1953, The Journal of physiology.

[18]  K. Edman,et al.  Differences in maximum velocity of shortening along single muscle fibres of the frog. , 1985, The Journal of physiology.

[19]  P. Brand,et al.  Relative tension and potential excursion of muscles in the forearm and hand. , 1981, The Journal of hand surgery.

[20]  V. Edgerton,et al.  Muscle architecture and force-velocity characteristics of cat soleus and medial gastrocnemius: implications for motor control. , 1980, Journal of neurophysiology.

[21]  R. Roy,et al.  Architecture of the hind limb muscles of cats: Functional significance , 1982, Journal of morphology.

[22]  K. Edman Double‐hyperbolic force‐velocity relation in frog muscle fibres. , 1988, The Journal of physiology.