Why is the force-velocity relationship in leg press tasks quasi-linear rather than hyperbolic?

Force-velocity relationships reported in the literature for functional tasks involving a combination of joint rotations tend to be quasi-linear. The purpose of this study was to explain why they are not hyperbolic, like Hill's relationship. For this purpose, a leg press task was simulated with a musculoskeletal model of the human leg, which had stimulation of knee extensor muscles as only independent input. In the task the ankles moved linearly, away from the hips, against an imposed external force that was reduced over contractions from 95 to 5% of the maximum isometric value. Contractions started at 70% of leg length, and force and velocity values were extracted when 80% of leg length was reached. It was shown that the relationship between leg extension velocity and external force was quasi-linear, while the relationship between leg extension velocity and muscle force was hyperbolic. The discrepancy was explained by the fact that segmental dynamics canceled more and more of the muscle force as the external force was further reduced and velocity became higher. External power output peaked when the imposed external force was ∼50% of maximum, while muscle power output peaked when the imposed force was only ∼15% of maximum; in the latter case ∼70% of muscle power was buffered by the leg segments. According to the results of this study, there is no need to appeal to neural mechanisms to explain why, in leg press tasks, the force-velocity relationship is quasi-linear rather than hyperbolic.

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

[2]  V. T. Inman,et al.  Mechanics of human isolated voluntary muscle. , 1947, The American journal of physiology.

[3]  D. Wilkie The relation between force and velocity in human muscle , 1949, The Journal of physiology.

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

[5]  A. Huxley Muscle structure and theories of contraction. , 1957, Progress in biophysics and biophysical chemistry.

[6]  S. Ebashi,et al.  Calcium ion and muscle contraction. , 1968, Progress in biophysics and molecular biology.

[7]  L. Shampine,et al.  Computer solution of ordinary differential equations : the initial value problem , 1975 .

[8]  D. Grieve Prediction of gastrocnemius length from knee and ankle joint posture , 1978 .

[9]  V. Edgerton,et al.  Muscle force-velocity and power-velocity relationships under isokinetic loading. , 1978, Medicine and science in sports.

[10]  D. Arnold,et al.  Computer Solution of Ordinary Differential Equations. , 1981 .

[11]  A. Sargeant,et al.  Maximum leg force and power output during short-term dynamic exercise. , 1981, Journal of applied physiology: respiratory, environmental and exercise physiology.

[12]  V. Edgerton,et al.  Muscle architecture and force-velocity relationships in humans. , 1984, Journal of applied physiology: respiratory, environmental and exercise physiology.

[13]  M. Bobbert,et al.  Coordination in vertical jumping. , 1988, Journal of biomechanics.

[14]  Gerrit Jan VAN INGEN SCHENAU,et al.  From rotation to translation: Constraints on multi-joint movements and the unique action of bi-articular muscles , 1989 .

[15]  P R Cavanagh,et al.  Power equations in endurance sports. , 1990, Journal of biomechanics.

[16]  A. Beelen,et al.  Effect of fatigue on maximal power output at different contraction velocities in humans. , 1991, Journal of applied physiology.

[17]  J Harlaar,et al.  Evaluation of moment-angle curves in isokinetic knee extension. , 1993, Medicine and science in sports and exercise.

[18]  A. Schwab,et al.  The influence of the biarticularity of the gastrocnemius muscle on vertical-jumping achievement. , 1993, Journal of biomechanics.

[19]  A. V. van Soest,et al.  Which factors determine the optimal pedaling rate in sprint cycling? , 2000, Medicine and science in sports and exercise.

[20]  Maarten F. Bobbert,et al.  Why Do People Jump the Way They Do? , 2001, Exercise and sport sciences reviews.

[21]  Reproducibility and reliability of measurements using a linear isokinetic dynamometer, Aristokin. , 2001, The Journal of sports medicine and physical fitness.

[22]  Georges Dalleau,et al.  Force/velocity and power/velocity relationships in squat exercise , 2001, European Journal of Applied Physiology.

[23]  E. Prédine,et al.  Force–velocity characteristics of upper limb extension during maximal wheelchair sprinting performed by healthy able-bodied females , 2003, Journal of sports sciences.

[24]  Joseph Pedlosky,et al.  The Initial Value Problem , 2003 .

[25]  A. Macaluso,et al.  Comparison between young and older women in explosive power output and its determinants during a single leg-press action after optimisation of load , 2003, European Journal of Applied Physiology.

[26]  J. Tihanyi,et al.  A dynamometer for evaluation of dynamic muscle work , 2004, European Journal of Applied Physiology and Occupational Physiology.

[27]  H. Hatze,et al.  A myocybernetic control model of skeletal muscle , 1977, Biological Cybernetics.

[28]  M. Bobbert,et al.  Forward Dynamics of Two-Dimensional Skeletal Models , 2004 .

[29]  S. D. R. Harridge,et al.  Power output of the lower limb during variable inertial loading: a comparison between methods using single and repeated contractions , 2004, European Journal of Applied Physiology.

[30]  Maarten F. Bobbert,et al.  The contribution of muscle properties in the control of explosive movements , 1993, Biological Cybernetics.

[31]  M. Bobbert,et al.  Length and moment arm of human leg muscles as a function of knee and hip-joint angles , 2004, European Journal of Applied Physiology and Occupational Physiology.

[32]  H. Monod,et al.  Force-velocity relationship and maximal power on a cycle ergometer , 2004, European Journal of Applied Physiology and Occupational Physiology.

[33]  N. Ishii,et al.  Steady-state force-velocity relation in human multi-joint movement determined with force clamp analysis. , 2007, Journal of biomechanics.

[34]  Maarten F Bobbert,et al.  Humans adjust control to initial squat depth in vertical squat jumping. , 2008, Journal of applied physiology.

[35]  E. Rejc,et al.  Bilateral deficit and EMG activity during explosive lower limb contractions against different overloads , 2009, European Journal of Applied Physiology.

[36]  N. Ishii,et al.  Aging-Related Differences in Maximum Force, Unloaded Velocity and Power of Human Leg Multi-Joint Movement , 2009, Gerontology.

[37]  N. Ishii,et al.  Force-velocity, force-power relationships of bilateral and unilateral leg multi-joint movements in young and elderly women. , 2009, Journal of biomechanics.

[38]  A. Belli,et al.  Jumping ability: a theoretical integrative approach. , 2010, Journal of theoretical biology.