Sport specific strength in alpine competitive skiing : What characterizes alpine elite skiers?

Moberg, Mathias

January 2022

Introduction: Alpine skiing has changed since the 1990s and it is unclear what sport specific strength is within modern alpine elite skiing. Purpose: The aim of this study was to create a strength profile and to investigate what sport specific strength is within alpine elite skiers. Method: A total number of 24 participant took part in this cross-sectional study, where eleven alpine elite skiers were compared with thirteen well-trained strength athletes with different sports background. The participants were tested in squat jump (SJ), counter movement jump (CMJ), drop jump (DJ) as well as isometric, isokinetic concentric and isokinetic eccentric strength with different dynamic velocities. In addition to these tests, reaction strength index (RSI) and eccentric utilization ratio (EUR) were calculated. Correlation analyses were performed to investigate if there were any relationships between the jump test variables and the isometric and eccentric strength tests. Results: The SKI group jumped higher in relation to their bodyweight (BW) in SJ (P>0,01), CMJ (P>0,05) and DJ (P>0,01). The SKI group also showed significantly higher RSI values (P>0,05). For the strength tests, the SKI group performed significantly better in all the eccentric velocities (P>0,05), the isometric test (P>0,01) and in the slowest concentric velocity (P>0,01). The SKI group showed significantly higher strength values (P>0,05) in relative isometric strength with knee angles between 20°-60°, where the largest significant difference appeared at 25° (P>0,001). No significant differences were found in the absolute values in either the jump or the strength tests. Only moderate (r=0,30-0,49) significant (P>0,05) correlations were found between the fastest eccentric tests and the SJ and DJ within all athletes. No significant correlations were found within the SKI group alone. Conclusion: This study presented evidence that sport specific strength for alpine elite skiers may primarily consist of isometric strength, training in slow concentric velocities and general eccentric training. The results indicate that the sport specific strength for alpine elite skiers does not include concentric training in moderate and fast concentric movements.

Alpine Skiing

biomechanics

physiology

strength training

elite athletest

alpine elite skiers

Sport and Fitness Sciences

Idrottsvetenskap

The importance of body-mass exponent optimization for evaluation of performance capability in cross-country skiing

Carlsson, Tomas

January 2015

Introduction Performance in cross-country skiing is influenced by the skier’s ability to continuously produce propelling forces and force magnitude in relation to the net external forces. A surrogate indicator of the “power supply” in cross-country skiing would be a physiological variable that reflects an important performance-related capability, whereas the body mass itself is an indicator of the “power demand” experienced by the skier. To adequately evaluate an elite skier’s performance capability, it is essential to establish the optimal ratio between the physiological variable and body mass. The overall aim of this doctoral thesis was to investigate the importance of body-mass exponent optimization for the evaluation of performance capability in cross-country skiing. Methods In total, 83 elite cross-country skiers (56 men and 27 women) volunteered to participate in the four studies. The physiological variables of maximal oxygen uptake (V̇O2max) and oxygen uptake corresponding to a blood-lactate concentration of 4 mmol∙l-1 (V̇O2obla) were determined while treadmill roller skiing using the diagonal-stride technique; mean oxygen uptake (V̇O2dp) and upper-body power output (Ẇ) were determined during double-poling tests using a ski-ergometer. Competitive performance data for elite male skiers were collected from two 15-km classical-technique skiing competitions and a 1.25-km sprint prologue; additionally, a 2-km double-poling roller-skiing time trial using the double-poling technique was used as an indicator of upper-body performance capability among elite male and female junior skiers. Power-function modelling was used to explain the race and time-trial speeds based on the physiological variables and body mass. Results The optimal V̇O2max-to-mass ratios to explain 15-km race speed were V̇O2max divided by body mass raised to the 0.48 and 0.53 power, and these models explained 68% and 69% of the variance in mean skiing speed, respectively; moreover, the 95% confidence intervals (CI) for the body-mass exponents did not include either 0 or 1. For the modelling of race speed in the sprint prologue, body mass failed to contribute to the models based on V̇O2max, V̇O2obla, and V̇O2dp. The upper-body power output-to-body mass ratio that optimally explained time-trial speed was Ẇ ∙ m-0.57 and the model explained 63% of the variance in speed. Conclusions The results in this thesis suggest that V̇O2max divided by the square root of body mass should be used as an indicator of performance in 15-km classical-technique races among elite male skiers rather than the absolute or simple ratio-standard scaled expression. To optimally explain an elite male skier’s performance capability in sprint prologues, power-function models based on oxygen-uptake variables expressed absolutely are recommended. Moreover, to evaluate elite junior skiers’ performance capabilities in 2-km double-poling roller-skiing time trials, it is recommended that Ẇ divided by the square root of body mass should be used rather than absolute or simple ratio-standard scaled expression of power output. / <p>Incorrect ISBN in printed thesis: 973-91-7601-270-3</p>

allometric scaling

power-function modelling

maximal oxygen uptake

body mass

elite skiers

distance skiing

lactate threshold

double poling

sprint skiing

competition

power output

time trial

The importance of body-mass exponent optimization for evaluation of performance capability in cross-country skiing

Carlsson, Tomas

January 2015

Introduction Performance in cross-country skiing is influenced by the skier’s ability to continuously produce propelling forces and force magnitude in relation to the net external forces. A surrogate indicator of the “power supply” in cross-country skiing would be a physiological variable that reflects an important performance-related capability, whereas the body mass itself is an indicator of the “power demand” experienced by the skier. To adequately evaluate an elite skier’s performance capability, it is essential to establish the optimal ratio between the physiological variable and body mass. The overall aim of this doctoral thesis was to investigate the importance of body-mass exponent optimization for the evaluation of performance capability in cross-country skiing. Methods In total, 83 elite cross-country skiers (56 men and 27 women) volunteered to participate in the four studies. The physiological variables of maximal oxygen uptake (V̇O2max) and oxygen uptake corresponding to a blood-lactate concentration of 4 mmol∙l-1 (V̇O2obla) were determined while treadmill roller skiing using the diagonal-stride technique; mean oxygen uptake (V̇O2dp) and upper-body power output (Ẇ) were determined during double-poling tests using a ski-ergometer. Competitive performance data for elite male skiers were collected from two 15-km classical-technique skiing competitions and a 1.25-km sprint prologue; additionally, a 2-km double-poling roller-skiing time trial using the double-poling technique was used as an indicator of upper-body performance capability among elite male and female junior skiers. Power-function modelling was used to explain the race and time-trial speeds based on the physiological variables and body mass. Results The optimal V̇O2max-to-mass ratios to explain 15-km race speed were V̇O2max divided by body mass raised to the 0.48 and 0.53 power, and these models explained 68% and 69% of the variance in mean skiing speed, respectively; moreover, the 95% confidence intervals (CI) for the body-mass exponents did not include either 0 or 1. For the modelling of race speed in the sprint prologue, body mass failed to contribute to the models based on V̇O2max, V̇O2obla, and V̇O2dp. The upper-body power output-to-body mass ratio that optimally explained time-trial speed was Ẇ ∙ m-0.57 and the model explained 63% of the variance in speed. Conclusions The results in this thesis suggest that V̇O2max divided by the square root of body mass should be used as an indicator of performance in 15-km classical-technique races among elite male skiers rather than the absolute or simple ratio-standard scaled expression. To optimally explain an elite male skier’s performance capability in sprint prologues, power-function models based on oxygen-uptake variables expressed absolutely are recommended. Moreover, to evaluate elite junior skiers’ performance capabilities in 2-km double-poling roller-skiing time trials, it is recommended that Ẇ divided by the square root of body mass should be used rather than absolute or simple ratio-standard scaled expression of power output. / <p>Incorrect ISBN in printed thesis: 973-91-7601-270-3</p>

allometric scaling

power-function modelling

maximal oxygen uptake

body mass

elite skiers

distance skiing

lactate threshold

double poling

sprint skiing

competition

power output

time trial

Sport and Fitness Sciences

Idrottsvetenskap