Abstract
Anaerobic capacity is an important performance-determining variable of sprint cross-country skiing. Nevertheless, to date, no study has directly compared the anaerobic capacity, determined using the maximal accumulated oxygen deficit (MAOD) method and gross efficiency (GE) method, while using different skiing sub-techniques.Purpose: To compare the anaerobic capacity assessed using two different MAOD approaches (including and excluding a measured y-intercept) and the GE method during double poling (DP) and diagonal stride (DS) cross-country skiing.Methods: After an initial familiarization trial, 16 well-trained male cross-country skiers performed, in each sub-technique on separate occasions, a submaximal protocol consisting of eight 4-min bouts at intensities between ~47–78% of O2peak followed by a 4-min roller-skiing time trial, with the order of sub-technique being randomized. Linear and polynomial speed-metabolic rate relationships were constructed for both sub-techniques, while using a measured y-intercept (8+YLIN and 8+YPOL) or not (8–YLIN and 8–YPOL), to determine the anaerobic capacity using the MAOD method. The average GE (GEAVG) of all eight submaximal exercise bouts or the GE of the last submaximal exercise bout (GELAST) were used to calculate the anaerobic capacity using the GE method. Repeated measures ANOVA were used to test differences in anaerobic capacity between methods/approaches.Results: A significant interaction was found between computational method and skiing sub-technique (P < 0.001, η2 = 0.51) for the anaerobic capacity estimates. The different methodologies resulted in significantly different anaerobic capacity values in DP (P < 0.001, η2 = 0.74) and in DS (P = 0.016, η2 = 0.27). The 8-YPOL model resulted in the smallest standard error of the estimate (SEE, 0.24 W·kg−1) of the MAOD methods in DP, while the 8-YLIN resulted in a smaller SEE value than the 8+YLIN model (0.17 vs. 0.33 W·kg−1) in DS. The 8-YLIN and GELAST resulted in the closest agreement in anaerobic capacity values in DS (typical error 2.1 mL O2eq·kg−1).Conclusions: It is discouraged to use the same method to estimate the anaerobic capacity in DP and DS sub-techniques. In DP, a polynomial MAOD method (8-YPOL) seems to be the preferred method, whereas the 8-YLIN, GEAVG, and GELAST can all be used for DS, but not interchangeable, with GELAST being the least time-consuming method.
Highlights
As suggested by the performance model introduced by Joyner and Coyle (2008), performance power output or speed is determined by the total metabolic rate multiplied with the gross mechanical efficiency. Losnegard et al (2012) were the first to determine the O2 deficit or anaerobic capacity, determined as the accumulated O2 ( O2) deficit, during a treadmill roller-skiing sprint time trial
In double poling (DP), gross efficiency (GE) and net efficiency were both dependent on speed (GE: F2, 31 = 6.45, P = 0.004, η2 = 0.30; NE: F2, 29 = 19.37, P < 0.001, η2 = 0.56), while in diagonal stride (DS) only net efficiency was dependent on speed (GE: F7, 105 = 1.32, P = 0.247, η2 = 0.08; NE: F7, 105 = 38.80, P < 0.001, η2 = 0.72) (Figure 2)
We found that (1) the effect of computational method differed between the DP and DS sub-techniques; (2) the second degree polynomial maximal accumulated oxygen deficit (MAOD) method excluding a fixed Y-intercept (8-YPOL) described the relationship between speed and submaximal metabolic rate best in DP, while GELAST showed the closest agreement in anaerobic capacity with 8-YPOL in DP; (3) the linear MAOD method excluding a fixed Y-intercept (8-YLIN) described the relationship between speed and submaximal metabolic rate best in DS and showed the closest agreement with GELAST
Summary
As suggested by the performance model introduced by Joyner and Coyle (2008), performance power output or speed is determined by the total metabolic rate (i.e., the sum of the oxygen uptake [V O2] and oxygen [O2] deficit) multiplied with the gross mechanical efficiency. Losnegard et al (2012) were the first to determine the O2 deficit or anaerobic capacity, determined as the accumulated O2 ( O2) deficit, during a treadmill roller-skiing sprint time trial. When sprint time trial performance was assessed multiple times during a skiing season it was shown that training resulted in a significant improvement in sprint time trial performance, which was not accompanied by significant changes in peak V O2 (V O2peak), but was related to a significant improvement in O2 deficit during the season (Losnegard et al, 2013). These studies show that anaerobic capacity is an important performancedetermining variable for sprint cross-country skiing and that anaerobic capacity should be monitored regularly
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