The relative peak power output of amateur mountain bikers is inversely correlated with body fat but not with fat-free mass

Arriel, Rhaí André; Graudo, Juliana Alves; Oliveira, Jorge Luiz Duarte de; Ribeiro, Guilherme Guedes Silva; Meireles, Anderson; Marocolo, Moacir

doi:10.1590/S1980-6574202000030034

Abstract

Aims:

To evaluate whether body mass (BM) and body composition may influence mountain bike cycling performance.

Methods:

Forty male amateur mountain bikers attended the laboratory on two non-consecutive days. At the first visit, anthropometric measures (height, BM, body fat [BF], fat-free mass [FFM] and body mass index [BMI]) and familiarization to incremental cycling test were performed. On the second visit, cyclists performed again the incremental cycling test to measure peak power output (PPO), peak power output relative to BM (PPO-BM), and time to exhaustion (TE), which were posteriorly correlated with BM and anthropometric measures.

Results:

A low and moderate significant correlation were observed between TE and BM (p<0.01; r=0.40) and FFM (p<0.01; r=0.56). Moderate significant correlation was found between PPO and BM (p<0.01; r=0.45), BMI (p=0.03; r=0.35) and strong with FFM (p<0.01; r=0.59). Also, PPO-BM significantly correlated with BM (p=0.04; r=-0.31), BMI (p=0.02; r=-0.35) and BF (p<0.01; r=-0.55). No other significant correlations were observed.

Conclusion:

Considering PPO-BM as mainly performance variable, BM and BF can be a determining factor in mountain biking performance but FFM did not.

Keywords:
cyclists; performance; body composition; off-road cyclists; body mass; body mass index

Introduction

Mountain biking (MTB) is an off-road cycling modality including various types of terrain and repeated up- and downhills¹1. Impellizzeri FM, Marcora SM. The physiology of mountain biking. Sports Med Auckl NZ 2007; 37: 59-71.. Since it was included in the Olympic Games programme, it became a more traditional and widespread sport around the world, comprising a large number of recreational, amateur and elite cyclists¹1. Impellizzeri FM, Marcora SM. The physiology of mountain biking. Sports Med Auckl NZ 2007; 37: 59-71..

In this sense, the determinants of MTB performance are drawing the attention of sports scientists¹1. Impellizzeri FM, Marcora SM. The physiology of mountain biking. Sports Med Auckl NZ 2007; 37: 59-71.

2. Engelbrecht L, Terblanche E. Physiological performance predictors in mountain bike multi-stage races. J Sports Med Phys Fitness. Epub ahead of print 28 April 2017. DOI: 10.23736/S0022-4707.17.07139-0.
https://doi.org/10.23736/S0022-4707.17.0... -³3. Sanchez-Munoz C, Muros JJ, Zabala M. World and Olympic mountain bike champions anthropometry, body composition and somatotype. J Sports Med Phys Fitness 2018; 58: 843-851.. They included technical ability, nutritional strategies, physiological aspects, and body composition (BC)¹1. Impellizzeri FM, Marcora SM. The physiology of mountain biking. Sports Med Auckl NZ 2007; 37: 59-71., being the last one also a determinant of performance in various other sports modalities⁴4. Barbieri D, Zaccagni L, Babic V, Rakovac M, Misigoj-Durakovic M, Gualdi-Russo E. Body composition and size in sprint athletes. J Sports Med Phys Fitness 2017; 57: 1142-1146.

5. Barlow MJ, Findlay M, Gresty K, Cooke C. Anthropometric variables and their relationship to performance and ability in male surfers. Eur J Sport Sci 2014; 14 Suppl 1: S171-177.-⁶6. Siegel-Tike P, Rosales-Soto G, Herrera Valenzuela T, Duran S, Yanez-Sepulveda R. Body composition parameters and relationship with the maximal aerobic power in recreational cyclists. Nutr Hosp 2015; 32: 2223-2227.. In sprint runners, a greater fat-free mass (FFM) and lower body fat (BF) are directly correlated with better speed performance⁴4. Barbieri D, Zaccagni L, Babic V, Rakovac M, Misigoj-Durakovic M, Gualdi-Russo E. Body composition and size in sprint athletes. J Sports Med Phys Fitness 2017; 57: 1142-1146., and in ultra-marathon runners, body mass index (BMI) was positively correlated with the race time⁷7. Knechtle B, Knechtle P, Rosemann T, Senn O. What is associated with race performance in male 100-km ultra-marathoners-anthropometry, training or marathon best time? J Sports Sci 2011; 29: 571-577.. Lastly, in recreational male Ironman triathletes and ultra-cyclists, the percent BF was associated with total race time⁸8. Rust CA, Knechtle B, Knechtle P, Wirth A, Rosemann TJ. A comparison of anthropometric and training characteristics among recreational male Ironman triathletes and ultra-endurance cyclists. Chin J Physiol 2012; 55: 114-124..

Although the BC, which includes BF, FFM and both alter body mass (BM), depends on the genetic compound, this parameter can be modified accordingly physical training⁹9. Mujika I, Ronnestad BR, Martin DT. Effects of Increased Muscle Strength and Muscle Mass on Endurance-Cycling Performance. Int J Sports Physiol Perform 2016; 11: 283-289. and/or nutritional behavior¹⁰10. Rossi FE, Landreth A, Beam S, Jones T, Norton L, Cholewa M. The Effects of a Sports Nutrition Education Intervention on Nutritional Status, Sport Nutrition Knowledge, Body Composition, and Performance during Off-Season Training in NCAA Division I Baseball Players. J Sports Sci Med 2017; 16: 60-68.. Since MTB performance indicators, such as power output and oxygen consumption, are more determinants when normalized by BM¹¹11. Impellizzeri FM, Marcora SM, Rampinini E, Mognoni P, Sassi A. Correlations between physiological variables and performance in the high-level cross country off-road cyclists. Br J Sports Med 2005; 39: 747-751. and, considering that BC is quite homogeneous among elite MTB athletes¹²12. Bejder J, Bonne TC, Nyberg M, Sjoberg KA, Nordsborg NB. Physiological determinants of elite mountain bike cross-country Olympic performance. J Sports Sci 2019; 37: 1154-1161., this parameter could be not too relevant for success in this level. However, a higher variation of BC on amateur cyclists⁶6. Siegel-Tike P, Rosales-Soto G, Herrera Valenzuela T, Duran S, Yanez-Sepulveda R. Body composition parameters and relationship with the maximal aerobic power in recreational cyclists. Nutr Hosp 2015; 32: 2223-2227. can lead to a direct influence of performance. Although their effect on road¹³13. Del Vecchio L, Stanton R, Reaburn P, Macgregor C, Meerkin J, Villegas J. Effects of Combined Strength and Sprint Training on Lean Mass, Strength, Power, and Sprint Performance in Masters Road Cyclists. J Strength Cond Res 2019; 33: 66-79. and elite MTB¹²12. Bejder J, Bonne TC, Nyberg M, Sjoberg KA, Nordsborg NB. Physiological determinants of elite mountain bike cross-country Olympic performance. J Sports Sci 2019; 37: 1154-1161. cyclists performance were presented, there is still limited evidence on the performance of amateur mountain bikers⁶6. Siegel-Tike P, Rosales-Soto G, Herrera Valenzuela T, Duran S, Yanez-Sepulveda R. Body composition parameters and relationship with the maximal aerobic power in recreational cyclists. Nutr Hosp 2015; 32: 2223-2227.,¹⁴14. Knechtle B, Knechtle P, Rosemann T, Senn O. Personal best time and training volume, not anthropometry, is related to race performance in the Swiss Bike Masters mountain bike ultramarathon. J Strength Cond Res 2011; 25: 1312-1317.. Therefore, considering these parameters, this study aimed to evaluate whether BC and BM influence the performance of amateur mountain bikers.

Methods

Subjects

Forty male amateur mountain bikers were recruited to participate in the study. The power statistic was calculated by G*power software¹⁵15. Faul F, Erdfelder E, Lang A-G, Buchner A. G*Power 3: a flexible statistical power analysis program for the social, behavioral, and biomedical sciences. Behav Res Methods 2007; 39: 175-191. based on the current sample size in this study (test power = 0.63). To inclusion, they needed to have a cycling training with a minimum of 2 hours per week and achieve at least 250 W or more in the incremental test¹⁶16. Jeukendrup AE, Craig NP, Hawley JA. The bioenergetics of World Class Cycling. J Sci Med Sport 2000; 3: 414-433.. The exclusion criteria were: i) any cardiovascular, metabolic, or respiratory disease; ii) any potential substance that could improve the exercise performance; iii) musculoskeletal, bone, or joint injury that could unsettle the exercise performance; iv) caffeine supplement intake; v) smoking history. This information, as well as the information about training and cycling experience, were identified via a questionnaire. Table 1 shows the volunteers’ characteristics. This study was approved by the local Ethics Committee (number 2.250.458) for human experiments and was carried out in conformity with the Declaration of Helsinki. All the volunteers were informed about the testing procedures. Furthermore, all of them provided written informed consent about the research.

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Table 1
Demographic and anthropometric characteristics of the volunteers

Experimental design

The cyclists attended the laboratory on two non-consecutive days (48 h of the interval), at the same time of day to prevent circadian influences¹⁷17. Fernandes AL, Lopes-Silva JP, Bertuzzi R, Casarini DE, Arita DY, Bishop DJ, et al. Effect of time of day on performance, hormonal and metabolic response during a 1000-M cycling time trial. PloS One 2014; 9: e109954.. All tests were performed in a controlled environment (temperature: 22.3 ± 1.5˚C; relative humidity: 72.7 ± 7.2%). At the first visit, anthropometric measures and familiarization with the incremental test were performed. At the second visit, which happened 48 hours later, they performed an incremental test for analysis. The cyclists were also asked to maintain their dietary intake throughout the experiment. They were directed not to perform any moderate or intense physical exercise and all of them were prohibited from intake caffeine products, tea, and alcohol 48 h before the tests.

Body Composition

The anthropometric dimensions were taken by an experienced and trained professional. Height (m) and BM (kg) were measured to the nearest 0.1 kg using calibrated scales and 0.5 cm using calibrated stadiometer (Health-O-Meter, model 402EXP; Badger Scale, Inc., Milwaukee, WI, USA), respectively, with participant’s unshod and wearing cycling apparel. Three skinfold thicknesses (Sanny^®, Brazil, precision 0.5 mm) at three sites (pectoral, abdominal, and thigh) were taken on the right side of the body. All measurements of skinfold thicknesses were taken three times in a non-consecutive way, and then the mean value was used for calculation.

BF percentage (%BF) was estimated according to Jackson and Pollock¹⁸18. Jackson AS, Pollock ML. Generalized equations for predicting body density of men. Br J Nutr 1978; 40: 497-504.. Absolute BF was determined multiplying BM by %BF divided by 100; FFM was estimated through the difference between BM (kg) and BF (kg) (BM - BF); and finally, BMI using BM divided by squared height.

Incremental test

The cycle ergometer (Monark 839 E, Sweden) was used in all incremental tests. The bike setup was done by the cyclists before the familiarization test and maintained during the test for analysis. Participants completed a 4-minute warm-up at 40 W. The test then started at 40 W that was increased by 20 W per min until voluntary exhaustion and the participants were required to maintain a cadence of 80-90 rpm (measured electronically). The test was terminated on voluntary exhaustion or failure to maintain the required cadence for 10 seconds, where the time to exhaustion (TE) was recorded (total exercise time performed). The peak power output (PPO) was defined by multiplying the cadence by the total load (this load indicates the force applied on the pedals to spin the flywheel that was tensioned by a broken belt connected by a pendulum weight) of the final stage. The peak power output relative to BM (PPO-BM) was measured by PPO divided by the BM of the cyclists. The incremental test procedures were based on the Arriel et al.¹⁹19. Arriel RA, de Souza HLR, da Mota GR, Marocolo M. Declines in exercise performance are prevented 24 hours after post-exercise ischemic conditioning in amateur cyclists. PloS One 2018; 13: e0207053. and De Groot²⁰20. de Groot PCE, Thijssen DHJ, Sanchez M, Ellenkamp R, Hopman MTE. Ischemic preconditioning improves maximal performance in humans. Eur J Appl Physiol 2010; 108: 141-146. studies.

Statistical analysis

The statistical analysis was performed through software GraphPad^® (Prism 6.0, San Diego, CA, USA). The Shapiro-Wilk test was used to verify the normality of the data. For measurement of the correlations between anthropometric and performance variables, Pearson´s or Kendall´s bivariate correlations test were performed, using a scale to analyze the correlation coefficient (proposed by Hopkins - www.sportsci.org), where: < 0.1, trivial relationship; 0.1- 0.3, low; 0.3-0.5 moderate; 0.5-0.7, strong; 0.7-0.9, very strong; > 0.9, nearly perfect. The level of significance adopted was ≤ 0.05.

Results

The TE was significantly correlated with BM (Figure 1A) and FFM (Figure 1C) (p < 0.05). Although the TE did not correlate significantly with BMI (Figure 1D) (p > 0.05), there was a low correlation coefficient (r = 0.30). No significant association between TE and BF (Figure 1B) was found (p > 0.05).

Regarding PPO, moderate correlations were found with BM (Figure 2A) and BMI (Figure 2D), but strong to FFM (Figure 2C) (p < 0.05). No significant correlation between PPO and BF (Figure 2B) was found (p > 0.05).

When peak power output was normalized to BM (PPO-BM), there was a moderate significant correlation with BM (Figure 3A) and BMI (Figure 3B), and a strong significant correlation to BF (Figure 3B) (p < 0.05). However, no significant correlation between PPO-BM and FFM (Figure 3C) was found.

Figure 1
Correlation between time to exhaustion and body mass (A), body fat (B), fat-free mass (C), and body mass index (BMI) (D). The values of r and p are shown in each figure.

Figure 2
Correlation between peak power output and body mass (A), body fat (B), fat-free mass (C), and body mass index (BMI) (D). The values of r and p are shown in each figure.

Figure 3
Correlation between peak power output relative to BM and body mass (A), body fat (B), fat-free mass (C), and body mass index (BMI) (D). The values of r and p are shown in each figure.

Discussion

This study aimed to investigate whether BC and BM influenced amateur mountain bikers. Our findings were that some components of BC have a significant correlation with TE, PPO, and PPO-BM. In absolute values, the most significant findings were the possible influence of FFM and BM on TE and PPO. In relative values, a possible negative influence of the BM, BMI, and, mainly, BF on PPO-BM, but in FFM did not. However, it is important to highlight that indices of aerobic fitness, such as power output or oxygen uptake, when normalized to BM are more determinants of performance¹¹11. Impellizzeri FM, Marcora SM, Rampinini E, Mognoni P, Sassi A. Correlations between physiological variables and performance in the high-level cross country off-road cyclists. Br J Sports Med 2005; 39: 747-751.. Moreover, the incremental test performed in this study was in cycle ergometer, which considers only absolute performance values. Thus, the PPO-BM value is closest to the actual values of a field test, which considers BM. Therefore, our finds identify possible effects of BF on cycling performance of amateurs MTB athletes.

The BF is an important energetic substrate for long time exercise. However, the excess of BF leads to an increase of BM which is associated with a negative effect on anaerobic²¹21. Maciejczyk M, Wiecek M, Szymura J, Szygula Z, Brown LE. Influence of increased body mass and body composition on cycling anaerobic power. J Strength Cond Res 2015; 29: 58-65. and aerobic²²22. Maciejczyk M, Wiecek M, Szymura J, Cempla J, Wiecha S, Szygula Z, et al. Effect of body composition on respiratory compensation point during an incremental test. J Strength Cond Res 2014; 28: 2071-2077. exercise performance of non-professional athletes, possibly caused by a decrease of the maximal power output and maximal oxygen uptake normalized to BM, respectively. However, in elite MTB athletes, no significant correlation was found between BF and race time performance in Olympic cross-country¹²12. Bejder J, Bonne TC, Nyberg M, Sjoberg KA, Nordsborg NB. Physiological determinants of elite mountain bike cross-country Olympic performance. J Sports Sci 2019; 37: 1154-1161.. As observed in figure 3, the subjects with higher BF had a lower PPO-BM and the subjects with smaller BF had a higher PPO-BM. However, in figures 1 and 2, we did not find the influences of BF on TE and PPO. As the BF is a passive tissue during exercise, its excess may lead the subject to great effort on the same workload during weight-bearing activities, but without influence on stationary exercises. Thus, these results suggest that an increase in BF could negatively influence the aerobic performance of amateur MTB cyclists in field test or race time.

On the other hand, a greater in BM, resulting from an increase in muscle mass, as a consequence of anaerobic²¹21. Maciejczyk M, Wiecek M, Szymura J, Szygula Z, Brown LE. Influence of increased body mass and body composition on cycling anaerobic power. J Strength Cond Res 2015; 29: 58-65. but not aerobic²²22. Maciejczyk M, Wiecek M, Szymura J, Cempla J, Wiecha S, Szygula Z, et al. Effect of body composition on respiratory compensation point during an incremental test. J Strength Cond Res 2014; 28: 2071-2077. exercise performance. According to the study of Maciejczyk et al.²²22. Maciejczyk M, Wiecek M, Szymura J, Cempla J, Wiecha S, Szygula Z, et al. Effect of body composition on respiratory compensation point during an incremental test. J Strength Cond Res 2014; 28: 2071-2077., a higher BM may be a limiting factor, regardless of BC, because substantially reduced aerobic endurance performance of recreationally active subjects, where an excess of BF or high muscle mass levels exhibited similar responses. Unlike our findings, the BF adversely affects PPO-BM, but the FFM level, which contains a high muscle mass value, did not. However, the PPO and TE were significantly correlated with FFM. Therefore, in endurance performance, the change in FFM does not seem to be a determinant factor to modify the performance of amateur MTB athletes in exercises with weight-bearing, such as field tests and MTB races. The same has been related to elite MTB athletes¹²12. Bejder J, Bonne TC, Nyberg M, Sjoberg KA, Nordsborg NB. Physiological determinants of elite mountain bike cross-country Olympic performance. J Sports Sci 2019; 37: 1154-1161..

The BMI and skinfold thicknesses are the most used anthropometric indicators of BC. According to Malina²³23. Malina RM. Body composition in athletes: assessment and estimated fatness. Clin Sports Med 2007; 26: 37-68., BMI is reasonably well correlated with BF. However, BMI has limitations with professional and amateur athletes since this parameter did not consider the BC of the subjects, once physically active persons present a higher FFM²²22. Maciejczyk M, Wiecek M, Szymura J, Cempla J, Wiecha S, Szygula Z, et al. Effect of body composition on respiratory compensation point during an incremental test. J Strength Cond Res 2014; 28: 2071-2077.. In this study, we found significate adverse effects on PPO-BM when correlated with BMI, BM, and BF but no significate result to FFM. The BMI (BM/Body height²2. Engelbrecht L, Terblanche E. Physiological performance predictors in mountain bike multi-stage races. J Sports Med Phys Fitness. Epub ahead of print 28 April 2017. DOI: 10.23736/S0022-4707.17.07139-0.
https://doi.org/10.23736/S0022-4707.17.0... ) is influenced by BM and body height. However, as the height of the participants was well homogeneous (1.75 ± 0.4 m), the BM of the cyclists (77.8 ± 9.65 kg) had a greater influence on BMI. Therefore, during weight-bearing activities, we can suggest that a high BMI can adversely affect the performance of amateur MTB cyclists due to a high BM, probably resulting from a high BF and not FFM.

The incremental cycling test is often used in research to evaluate psychophysiological responses¹¹11. Impellizzeri FM, Marcora SM, Rampinini E, Mognoni P, Sassi A. Correlations between physiological variables and performance in the high-level cross country off-road cyclists. Br J Sports Med 2005; 39: 747-751.,²⁴24. Arriel RA, Souza HLR de, Silva BVC da, Marocolo M. Ischemic preconditioning delays the time of exhaustion in cycling performance during the early but not in the late phase. Mot Rev Educ Física; 25. Epub ahead of print 2019. DOI: 10.1590/s1980-6574201800040050.
https://doi.org/10.1590/s1980-6574201800... which are highly correlated with cycling performance¹¹11. Impellizzeri FM, Marcora SM, Rampinini E, Mognoni P, Sassi A. Correlations between physiological variables and performance in the high-level cross country off-road cyclists. Br J Sports Med 2005; 39: 747-751.. However, for greater accuracy in correlation analysis, especially in laboratory studies, the indices of aerobic fitness should be normalized to BM. In our study, the BM influenced TE and PPO positively, but PPO-BM negatively. Probably this fact happened because the tests performed on cycle ergometers do not consider BM. In this way when the indices of aerobic fitness are normalized to BM, the results are different compared to non-normalized. To confirm this, Siegel-Tike et al.⁶6. Siegel-Tike P, Rosales-Soto G, Herrera Valenzuela T, Duran S, Yanez-Sepulveda R. Body composition parameters and relationship with the maximal aerobic power in recreational cyclists. Nutr Hosp 2015; 32: 2223-2227., investigating the relationship of the BC parameters on recreational trained cyclists performance, found a strong significant correlation between relative maximal oxygen uptake (i.e. ml/kg/min) and BF (r = -0.81; p < 0.05). However, no correlation was found between PPO and BF (r = 0.19; p > 0.05). The same happened for muscle mass. Although our study did not evaluate maximal oxygen uptake, considering the BF, the result is in line with our finding when considered the PPO but not when considered PPO-BM. Moreover, Lee et al.²⁵25. Lee H, Martin DT, Anson JM, Grundy D, Hahn AG. Physiological characteristics of successful mountain bikers and professional road cyclists. J Sports Sci 2002; 20: 1001-1008. found no differences between elite mountain bikers and professional road cyclists in maximal oxygen uptake, PPO, and the lactate threshold expressed in absolute values. However, the same variables, when normalized to BM, presented higher values to mountain bikers. These results confirm the importance of relative parameters to BM in elite¹1. Impellizzeri FM, Marcora SM. The physiology of mountain biking. Sports Med Auckl NZ 2007; 37: 59-71. and amateur mountain bikers.

Limitations

The variability of the methods used for BC estimation could be highlighted as a limitation of this study since there are more precise methods. Skinfolds method presents a low cost and it is more feasible.¹⁸18. Jackson AS, Pollock ML. Generalized equations for predicting body density of men. Br J Nutr 1978; 40: 497-504. However, for not measuring the FFM components (such as water, mineral, protein, and additional minor constituents), this model may present some limitations when compared with a more current model of four-compartment²⁶26. Silva AM, Fields DA, Quitério AL, Sardinha LB. Are skinfold-based models accurate and suitable for assessing changes in body composition in highly trained athletes? J Strength Cond Res 2009; 23: 1688-1696.. In this way, the within-subject differences, particularly in the proportion of water and mineral, can interfere in FFM measurement. Thus, the correlation between indices of performance (such as TE, PPO, and PPO-BM) and FFM should be analyzed with caution.

Other tests, as Wingate²⁷27. Inoue A, Sá Filho AS, Mello FCM, Santos TM. Relationship between anaerobic cycling tests and mountain bike cross-country performance. J Strength Cond Res 2012; 26: 1589-1593. and time trial²⁸28. Burt DG, Twist C. The effects of exercise-induced muscle damage on cycling time-trial performance. J Strength Cond Res 2011; 25: 2185-2192., can also measure performance. However, the characteristics of each test (i.e. time, intensity, and environment) may influence the relationship between BC and exercise performance. For example, anaerobic power performance is not affected by an increase in BM resulting only from an increased FFM²¹21. Maciejczyk M, Wiecek M, Szymura J, Szygula Z, Brown LE. Influence of increased body mass and body composition on cycling anaerobic power. J Strength Cond Res 2015; 29: 58-65., but maybe a limiting factor to aerobic performance²²22. Maciejczyk M, Wiecek M, Szymura J, Cempla J, Wiecha S, Szygula Z, et al. Effect of body composition on respiratory compensation point during an incremental test. J Strength Cond Res 2014; 28: 2071-2077.. In this study, we correlate BC with TE and PPO values that are above of lactate threshold and below the maximal power anaerobic achieved in short-time exercise, which is crucial for MTB performance¹1. Impellizzeri FM, Marcora SM. The physiology of mountain biking. Sports Med Auckl NZ 2007; 37: 59-71.,²⁷27. Inoue A, Sá Filho AS, Mello FCM, Santos TM. Relationship between anaerobic cycling tests and mountain bike cross-country performance. J Strength Cond Res 2012; 26: 1589-1593.. Therefore, the results of this study should not be generalized.

Lastly, it is important to highlight that, as related by Impellizzeri et al.¹¹11. Impellizzeri FM, Marcora SM, Rampinini E, Mognoni P, Sassi A. Correlations between physiological variables and performance in the high-level cross country off-road cyclists. Br J Sports Med 2005; 39: 747-751., significant positive or negative correlation does not imply causality. Therefore, futures experimental studies should investigate whether the changes in BM or BC components lead to changes in the performance of mountain bikers.

Practical Applications

Considering our results, changes in BM and BC (in order to reduce the fat mass that is a passive tissue during pedaling exercise) may be effective at improving MTB performance due to an increase in PPO-BM. However, the FFM should be maintained because, although this variable may increase BM, it is an important tissue to optimize power output in a short time duration such as sprints and technical climbs. In this hand, the nutrition strategy and the resistance training, as the main strategy to increase or maintain FFM and maximal force, should be included in the training routine of MTB amateur athletes.

Conclusion

The body mass and body composition could be determinant for mountain biking performance, where body fat influenced negatively the performance of amateur mountain bikers but the fat-free mass did not.

References

¹
Impellizzeri FM, Marcora SM. The physiology of mountain biking. Sports Med Auckl NZ 2007; 37: 59-71.
²
Engelbrecht L, Terblanche E. Physiological performance predictors in mountain bike multi-stage races. J Sports Med Phys Fitness. Epub ahead of print 28 April 2017. DOI: 10.23736/S0022-4707.17.07139-0.
» https://doi.org/10.23736/S0022-4707.17.07139-0
³
Sanchez-Munoz C, Muros JJ, Zabala M. World and Olympic mountain bike champions anthropometry, body composition and somatotype. J Sports Med Phys Fitness 2018; 58: 843-851.
⁴
Barbieri D, Zaccagni L, Babic V, Rakovac M, Misigoj-Durakovic M, Gualdi-Russo E. Body composition and size in sprint athletes. J Sports Med Phys Fitness 2017; 57: 1142-1146.
⁵
Barlow MJ, Findlay M, Gresty K, Cooke C. Anthropometric variables and their relationship to performance and ability in male surfers. Eur J Sport Sci 2014; 14 Suppl 1: S171-177.
⁶
Siegel-Tike P, Rosales-Soto G, Herrera Valenzuela T, Duran S, Yanez-Sepulveda R. Body composition parameters and relationship with the maximal aerobic power in recreational cyclists. Nutr Hosp 2015; 32: 2223-2227.
⁷
Knechtle B, Knechtle P, Rosemann T, Senn O. What is associated with race performance in male 100-km ultra-marathoners-anthropometry, training or marathon best time? J Sports Sci 2011; 29: 571-577.
⁸
Rust CA, Knechtle B, Knechtle P, Wirth A, Rosemann TJ. A comparison of anthropometric and training characteristics among recreational male Ironman triathletes and ultra-endurance cyclists. Chin J Physiol 2012; 55: 114-124.
⁹
Mujika I, Ronnestad BR, Martin DT. Effects of Increased Muscle Strength and Muscle Mass on Endurance-Cycling Performance. Int J Sports Physiol Perform 2016; 11: 283-289.
¹⁰
Rossi FE, Landreth A, Beam S, Jones T, Norton L, Cholewa M. The Effects of a Sports Nutrition Education Intervention on Nutritional Status, Sport Nutrition Knowledge, Body Composition, and Performance during Off-Season Training in NCAA Division I Baseball Players. J Sports Sci Med 2017; 16: 60-68.
¹¹
Impellizzeri FM, Marcora SM, Rampinini E, Mognoni P, Sassi A. Correlations between physiological variables and performance in the high-level cross country off-road cyclists. Br J Sports Med 2005; 39: 747-751.
¹²
Bejder J, Bonne TC, Nyberg M, Sjoberg KA, Nordsborg NB. Physiological determinants of elite mountain bike cross-country Olympic performance. J Sports Sci 2019; 37: 1154-1161.
¹³
Del Vecchio L, Stanton R, Reaburn P, Macgregor C, Meerkin J, Villegas J. Effects of Combined Strength and Sprint Training on Lean Mass, Strength, Power, and Sprint Performance in Masters Road Cyclists. J Strength Cond Res 2019; 33: 66-79.
¹⁴
Knechtle B, Knechtle P, Rosemann T, Senn O. Personal best time and training volume, not anthropometry, is related to race performance in the Swiss Bike Masters mountain bike ultramarathon. J Strength Cond Res 2011; 25: 1312-1317.
¹⁵
Faul F, Erdfelder E, Lang A-G, Buchner A. G*Power 3: a flexible statistical power analysis program for the social, behavioral, and biomedical sciences. Behav Res Methods 2007; 39: 175-191.
¹⁶
Jeukendrup AE, Craig NP, Hawley JA. The bioenergetics of World Class Cycling. J Sci Med Sport 2000; 3: 414-433.
¹⁷
Fernandes AL, Lopes-Silva JP, Bertuzzi R, Casarini DE, Arita DY, Bishop DJ, et al. Effect of time of day on performance, hormonal and metabolic response during a 1000-M cycling time trial. PloS One 2014; 9: e109954.
¹⁸
Jackson AS, Pollock ML. Generalized equations for predicting body density of men. Br J Nutr 1978; 40: 497-504.
¹⁹
Arriel RA, de Souza HLR, da Mota GR, Marocolo M. Declines in exercise performance are prevented 24 hours after post-exercise ischemic conditioning in amateur cyclists. PloS One 2018; 13: e0207053.
²⁰
de Groot PCE, Thijssen DHJ, Sanchez M, Ellenkamp R, Hopman MTE. Ischemic preconditioning improves maximal performance in humans. Eur J Appl Physiol 2010; 108: 141-146.
²¹
Maciejczyk M, Wiecek M, Szymura J, Szygula Z, Brown LE. Influence of increased body mass and body composition on cycling anaerobic power. J Strength Cond Res 2015; 29: 58-65.
²²
Maciejczyk M, Wiecek M, Szymura J, Cempla J, Wiecha S, Szygula Z, et al. Effect of body composition on respiratory compensation point during an incremental test. J Strength Cond Res 2014; 28: 2071-2077.
²³
Malina RM. Body composition in athletes: assessment and estimated fatness. Clin Sports Med 2007; 26: 37-68.
²⁴
Arriel RA, Souza HLR de, Silva BVC da, Marocolo M. Ischemic preconditioning delays the time of exhaustion in cycling performance during the early but not in the late phase. Mot Rev Educ Física; 25. Epub ahead of print 2019. DOI: 10.1590/s1980-6574201800040050.
» https://doi.org/10.1590/s1980-6574201800040050
²⁵
Lee H, Martin DT, Anson JM, Grundy D, Hahn AG. Physiological characteristics of successful mountain bikers and professional road cyclists. J Sports Sci 2002; 20: 1001-1008.
²⁶
Silva AM, Fields DA, Quitério AL, Sardinha LB. Are skinfold-based models accurate and suitable for assessing changes in body composition in highly trained athletes? J Strength Cond Res 2009; 23: 1688-1696.
²⁷
Inoue A, Sá Filho AS, Mello FCM, Santos TM. Relationship between anaerobic cycling tests and mountain bike cross-country performance. J Strength Cond Res 2012; 26: 1589-1593.
²⁸
Burt DG, Twist C. The effects of exercise-induced muscle damage on cycling time-trial performance. J Strength Cond Res 2011; 25: 2185-2192.

Editor:

Ricardo Barbieri. Estacio-UniSEB/Ribeirão Preto, SP, Brazil
Acknowledgment:

The authors would like to thank the Federal University of Juiz de Fora for the support given to the study.

Publication Dates

Publication in this collection
19 Oct 2020
Date of issue
Oct 2020

History

Received
08 Mar 2020
Accepted
14 July 2020

This is an open-access article distributed under the terms of the Creative Commons Attribution License

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Maciejczyk M, Wiecek M, Szymura J, Szygula Z, Brown LE. Influence of increased body mass and body composition on cycling anaerobic power. J Strength Cond Res 2015; 29: 58-65.

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Maciejczyk M, Wiecek M, Szymura J, Cempla J, Wiecha S, Szygula Z, et al. Effect of body composition on respiratory compensation point during an incremental test. J Strength Cond Res 2014; 28: 2071-2077.

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Malina RM. Body composition in athletes: assessment and estimated fatness. Clin Sports Med 2007; 26: 37-68.

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Arriel RA, Souza HLR de, Silva BVC da, Marocolo M. Ischemic preconditioning delays the time of exhaustion in cycling performance during the early but not in the late phase. Mot Rev Educ Física; 25. Epub ahead of print 2019. DOI: 10.1590/s1980-6574201800040050.
» https://doi.org/10.1590/s1980-6574201800040050

[25] ²⁵
Lee H, Martin DT, Anson JM, Grundy D, Hahn AG. Physiological characteristics of successful mountain bikers and professional road cyclists. J Sports Sci 2002; 20: 1001-1008.

[26] ²⁶
Silva AM, Fields DA, Quitério AL, Sardinha LB. Are skinfold-based models accurate and suitable for assessing changes in body composition in highly trained athletes? J Strength Cond Res 2009; 23: 1688-1696.

[27] ²⁷
Inoue A, Sá Filho AS, Mello FCM, Santos TM. Relationship between anaerobic cycling tests and mountain bike cross-country performance. J Strength Cond Res 2012; 26: 1589-1593.

[28] ²⁸
Burt DG, Twist C. The effects of exercise-induced muscle damage on cycling time-trial performance. J Strength Cond Res 2011; 25: 2185-2192.

Characteristics	N = 40
Age (years)	27.9 ± 4.19
Height (m)	1.75 ± 0.4
Body mass (kg)	77.8 ± 9.65
Body fat (%)	15.6 ± 4.21
Body mass index (kg/m²)	25.3 ± 2.7
Fat-free mass (kg)	65.6 ± 7.3
*Skinfolds*
Pectoral (mm)	10.6 ± 2.7
Abdominal (mm)	22.5 ± 7.4
Thigh (mm)	20.5 ± 7.4
*Indices of Performance*
Time to exhaustion (s)	796.6 ± 141.8
Power output (W)	326.4 ± 53.9
Power output (W.kg^-1)	4.2 ± 0.7
*Training History*
Experience (years)	5.1 ± 4.26
Hours per week	2.5 ± 0.96

Brasil