Opposition Skill Efficiency During Professional Rugby Union Official Games Is Related to Horizontal Force-Production Capacities in Sprinting.

PURPOSE This study aimed to determine relationships between parameters of force-production capacity in sprinting and opposition skill efficiency in rugby union games according to position. METHODS The sprint force-velocity profile of 33 professional rugby union players divided into 2 subgroups (forwards and backs) was measured on a 30-m sprint. Skill efficiencies (in percentage) of offensive duels, tackles, and rucks were assessed using objective criteria during 12 consecutive competitive games. Pearson correlation was used to determine the relationships between parameters of horizontal force-production capacity in sprinting (maximum propulsive power, theoretical maximum force [F0], theoretical maximum velocity, maximum ratio of horizontal force [RFmax], and rate of decrease of this ratio of forces with increasing velocity) and skill efficiencies. Two multiple linear regression models were used to observe whether skill efficiencies could depend on determinants of horizontal force application in low- or high-velocity conditions. A first model including F0 and theoretical maximum velocity was used as a macroscopic analysis, while a second model including RFmax and rate of decrease of this ratio of forces with increasing velocity was used as microscopic analysis to determine the most significant determinants of skill efficiency. RESULTS All skill efficiencies were strongly correlated with maximum propulsive power in forwards and backs. In forwards, F0 and RFmax were the key predictors of dueling, rucking, and tackling efficiency. In backs, F0 was the main predictor of dueling and rucking efficiency, whereas RFmax was the key predictor of dueling and tackling efficiency. F0 and theoretical maximum velocity equivalently contributed to tackling performance. CONCLUSIONS In rugby union forward and back players, skill efficiency is correlated with maximum propulsive power and may be more explained by horizontal force-production capacity and mechanical effectiveness at lower velocities than at higher velocities.

[1]  P. Jiménez-Reyes,et al.  Optimal mechanical force‐velocity profile for sprint acceleration performance , 2021, Scandinavian journal of medicine & science in sports.

[2]  N. Gill,et al.  Horizontal Force-Velocity-Power Profiling of Rugby Players: A Cross-Sectional Analysis of Competition-Level and Position-Specific Movement Demands , 2021, Journal of strength and conditioning research.

[3]  K. Clark,et al.  Influence of Resisted Sled-Pull Training on the Sprint Force-Velocity Profile of Male High-School Athletes. , 2020, Journal of strength and conditioning research.

[4]  P. Jiménez-Reyes,et al.  Individual Sprint Force-Velocity Profile Adaptations to In-Season Assisted and Resisted Velocity-Based Training in Professional Rugby , 2020, Sports.

[5]  P. Hume,et al.  Senior Club-Level Rugby Union Player's Positional Movement Performance Using Individualized Velocity Thresholds and Accelerometer-Derived Impacts in Matches , 2020, Journal of strength and conditioning research.

[6]  A. García-Ramos,et al.  Seasonal Changes in the Sprint Acceleration Force-Velocity Profile of Elite Male Soccer Players , 2020, Journal of strength and conditioning research.

[7]  Jacques Prioux,et al.  Rugby game performances and weekly workload: Using of data mining process to enter in the complexity , 2020, PloS one.

[8]  J. Morin,et al.  Changes in sprint performance and sagittal plane kinematics after heavy resisted sprint training in professional soccer players , 2019, PeerJ.

[9]  J. Morin,et al.  A simple method for computing sprint acceleration kinetics from running velocity data: Replication study with improved design. , 2019, Journal of biomechanics.

[10]  K. Clark,et al.  Sled-Pull Load–Velocity Profiling and Implications for Sprint Training Prescription in Young Male Athletes , 2019, Sports.

[11]  J. Cronin,et al.  Reliability of horizontal force–velocity–power profiling during short sprint-running accelerations using radar technology , 2019, Sports biomechanics.

[12]  A. Carvalho,et al.  Effect of weighted sled towing on sprinting effectiveness, power and force-velocity relationship , 2018, PloS one.

[13]  Pierre Samozino,et al.  Very-Heavy Sled Training for Improving Horizontal-Force Output in Soccer Players. , 2017, International journal of sports physiology and performance.

[14]  Kevin Till,et al.  Rugby union needs a contact skill-training programme , 2016, British Journal of Sports Medicine.

[15]  Sharief Hendricks,et al.  Skills Associated with Line Breaks in Elite Rugby Union. , 2016, Journal of sports science & medicine.

[16]  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.

[17]  Pierre Samozino,et al.  Interpreting Power-Force-Velocity Profiles for Individualized and Specific Training. , 2016, International journal of sports physiology and performance.

[18]  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.

[19]  S. Brown,et al.  Mechanical Properties of Sprinting in Elite Rugby Union and Rugby League. , 2015, International journal of sports physiology and performance.

[20]  J Cronin,et al.  The relationship between physical characteristics and match performance in rugby sevens , 2015, European journal of sport science.

[21]  D. Karpul,et al.  Momentum and kinetic energy before the tackle in rugby union. , 2014, Journal of sports science & medicine.

[22]  M. van Rooyen,et al.  Characteristics of an ‘effective’ tackle outcome in Six Nations rugby , 2014, European journal of sport science.

[23]  K. Quarrie,et al.  The relationship between physical fitness and game behaviours in rugby union players , 2014, European journal of sport science.

[24]  Kenneth L Quarrie,et al.  Positional demands of international rugby union: evaluation of player actions and movements. , 2013, Journal of science and medicine in sport.

[25]  Stafford Murray,et al.  The movement characteristics of English Premiership rugby union players , 2013, Journal of sports sciences.

[26]  Fred Nicolls,et al.  Velocity and acceleration before contact in the tackle during rugby union matches , 2012, Journal of sports sciences.

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

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

[29]  Bruce Davies,et al.  An Evaluation of the Physiological Demands of Elite Rugby Union Using Global Positioning System Tracking Software , 2009, Journal of strength and conditioning research.

[30]  Tim Gabbett,et al.  RELATIONSHIP BETWEEN PHYSICAL FITNESS AND PLAYING ABILITY IN RUGBY LEAGUE PLAYERS , 2007, Journal of strength and conditioning research.

[31]  K. Quarrie,et al.  Changes in player characteristics and match activities in Bledisloe Cup rugby union from 1972 to 2004 , 2007, Journal of sports sciences.

[32]  M. U. Deutsch,et al.  Time – motion analysis of professional rugby union players during match-play , 2007, Journal of sports sciences.

[33]  Grant M. Duthie,et al.  SPRINT PATTERNS IN RUGBY UNION PLAYERS DURING COMPETITION , 2006, Journal of strength and conditioning research.

[34]  Jacob Cohen Statistical Power Analysis for the Behavioral Sciences , 1969, The SAGE Encyclopedia of Research Design.

[35]  Tim J Gabbett,et al.  Physical demands of professional rugby league training and competition using microtechnology. , 2012, Journal of science and medicine in sport.

[36]  P. Reaburn,et al.  Heart rate, blood lactate and kinematic data of elite colts (under-19) rugby union players during competition. , 1998, Journal of sports sciences.