How 100‐m event analyses improve our understanding of world‐class men's and women's sprint performance

This study aimed to compare the force (F)–velocity (v)–power (P)–time (t) relationships of female and male world‐class sprinters. A total of 100 distance–time curves (50 women and 50 men) were computed from international 100‐m finals, to determine the acceleration and deceleration phases of each race: (a) mechanical variables describing the velocity, force, and power output; and (b) F‐P‐v relationships and associated maximal power output, theoretical force and velocity produced by each athlete (Pmax, F0, and V0). The results showed that the maximal sprint velocity (Vmax) and mean power output (W/kg) developed over the entire 100 m strongly influenced 100‐m performance (r > −0.80; P ≤ 0.001). With the exception of mean force (N/kg) developed during the acceleration phase or during the entire 100 m, all of the mechanicals variables observed over the race were greater in men. Shorter acceleration and longer deceleration in women may explain both their lower Vmax and their greater decrease in velocity, and in turn their lower performance level, which can be explained by their higher V0 and its correlation with performance. This highlights the importance of the capability to keep applying horizontal force to the ground at high velocities.

[1]  J B Morin,et al.  Direct measurement of power during one single sprint on treadmill. , 2010, Journal of biomechanics.

[2]  H. Monod,et al.  All out anaerobic capacity tests on cycle ergometers , 1985, European Journal of Applied Physiology and Occupational Physiology.

[3]  T. Fukunaga,et al.  Effect of gender on mechanical power output during repeated bouts of maximal running in trained teenagers. , 2003, International journal of sports medicine.

[4]  T. Fukunaga,et al.  Gender differences in the viscoelastic properties of tendon structures , 2003, European Journal of Applied Physiology.

[5]  A Belli,et al.  Spring-Mass Model Characteristics During Sprint Running: Correlation with Performance and Fatigue-Induced Changes , 2005, International journal of sports medicine.

[6]  S. Dorel,et al.  Sprint mechanics in world‐class athletes: a new insight into the limits of human locomotion , 2015, Scandinavian journal of medicine & science in sports.

[7]  H. Gunga,et al.  Effects of long-term head-down-tilt bed rest and different training regimes on the coagulation system of healthy men , 2013, Physiological reports.

[8]  Peter G. Weyand,et al.  Running performance has a structural basis , 2005, Journal of Experimental Biology.

[9]  A. Hill,et al.  The Dynamics of "Sprint" Running , 1927 .

[10]  N. Uth,et al.  Anthropometric comparison of world-class sprinters and normal populations. , 2005, Journal of sports science & medicine.

[11]  B B Shultz,et al.  Gender comparisons in anaerobic power and anaerobic capacity tests. , 1986, British journal of sports medicine.

[12]  Antti Mero,et al.  Age-related differences in 100-m sprint performance in male and female master runners. , 2003, Medicine and science in sports and exercise.

[13]  J. Moon Role of muscle mass on sprint performance: gender differences? by Jorge Perez-Gomez, German Vicente Rodriguez, Ignacio Ara, Hugo Olmedillas, Javier Chavarren, Juan Jose González-Henriquez, Cecilia Dorado and José A. L. Calbet , 2008, European Journal of Applied Physiology.

[14]  Alberto Botter,et al.  The energy cost of sprint running and the role of metabolic power in setting top performances , 2014, European Journal of Applied Physiology.

[15]  Giuseppe Rabita,et al.  In vivo maximal fascicle-shortening velocity during plantar flexion in humans. , 2015, Journal of applied physiology.

[16]  Matthew J D Taylor,et al.  What gives Bolt the edge-A.V. Hill knew it already! , 2010, Journal of biomechanics.

[17]  Robert Carter,et al.  Running Performance Differences between Men and Women , 2005, Sports medicine.

[18]  J. Mendiguchia,et al.  Progression of Mechanical Properties during On-field Sprint Running after Returning to Sports from a Hamstring Muscle Injury in Soccer Players , 2014, International Journal of Sports Medicine.

[19]  O. Inbar,et al.  Gender differences in anaerobic power of the arms and legs--a scaling issue. , 2006, Medicine and science in sports and exercise.

[20]  J. Morin,et al.  Technical ability of force application as a determinant factor of sprint performance. , 2011, Medicine and science in sports and exercise.

[21]  Ji-Seon Ryu,et al.  SPRINTING SPEED OF ELITE SPRINTERS AT THE WORLD CHAMPIONSHIPS , 2012 .

[22]  Stephen Seiler,et al.  The fall and rise of the gender difference in elite anaerobic performance 1952-2006. , 2007, Medicine and science in sports and exercise.

[23]  S. Piazza,et al.  Built for speed: musculoskeletal structure and sprinting ability , 2009, Journal of Experimental Biology.

[24]  M. Bourdin,et al.  Mechanical determinants of 100-m sprint running performance , 2012, European Journal of Applied Physiology.

[25]  C. Denis,et al.  Leg power and hopping stiffness: relationship with sprint running performance. , 2001, Medicine and science in sports and exercise.

[26]  Jared R. Fletcher,et al.  Energy cost of running and Achilles tendon stiffness in man and woman trained runners , 2013, Physiological reports.

[27]  W. Brechue Structure-function Relationships that Determine Sprint Performance and Running Speed in Sport , 2011 .

[28]  F. Hug,et al.  Force-velocity relationship in cycling revisited: benefit of two-dimensional pedal forces analysis. , 2009, Medicine and science in sports and exercise.

[29]  T. Fukunaga,et al.  Ergometry for estimation of mechanical power output in sprinting in humans using a newly developed self-driven treadmill , 2001, European Journal of Applied Physiology.

[30]  J. Skinner,et al.  Comparison of Treadmill and Cycle Ergometer Measurements of Force-Velocity Relationships and Power Output , 1999, International journal of sports medicine.

[31]  Gert-Peter Brüggemann,et al.  Lower leg musculoskeletal geometry and sprint performance. , 2011, Gait & posture.

[32]  J. Patton,et al.  Comparative anaerobic power of men and women. , 1986, Aviation, space, and environmental medicine.

[33]  David Bishop,et al.  Muscle Fatigue in Males and Females during Multiple-Sprint Exercise , 2009, Sports medicine.

[34]  A. Mero,et al.  A Kinematics Analysis Of Three Best 100 M Performances Ever , 2013, Journal of human kinetics.

[35]  F. Billaut,et al.  Maximal intermittent cycling exercise: effects of recovery duration and gender. , 2003, Journal of applied physiology.

[36]  H. Vandewalle,et al.  The Measurement of Maximal (Anaerobic) Power Output on a Cycle Ergometer: A Critical Review , 2013, BioMed research international.

[37]  S. Dorel,et al.  A simple method for measuring power, force, velocity properties, and mechanical effectiveness in sprint running , 2016, Scandinavian journal of medicine & science in sports.

[38]  J. J. González-Henríquez,et al.  Role of muscle mass on sprint performance: gender differences? , 2008, European Journal of Applied Physiology.

[39]  R. Beneke,et al.  Spring Mass Characteristics of the Fastest Men on Earth , 2012, International Journal of Sports Medicine.

[40]  O. Helene,et al.  The force, power, and energy of the 100 meter sprint , 2009, 0911.1952.