Impact of 5 Days of Sprint Training in Hypoxia on Performance and Muscle Energy Substances

International Journal of Sports Medicine

Volumn 38, Issue 13, 2017, Pages 983-991

  Kasai, Nobukazu ^a   Kojima, Chihiro ^a   Sumi, Daichi ^a   Takahashi, Hideyuki ^b   Goto, Kazushige ^a   Suzuki, Yasuhiro ^b  

^a RITSUMEIKAN UNIVERSITY   (Japan)

^b JAPAN INSTITUTE OF SPORTS SCIENCES   (Japan)

Author keywords

hypoxic training; muscle glycogen; muscle PCR; short term sprint training; sprinter

Indexed keywords

CREATINE PHOSPHATE; GLYCOGEN;

ATHLETIC PERFORMANCE; CALORIC INTAKE; CONTROLLED STUDY; ENERGY METABOLISM; EXERCISE; EXERCISE TEST; HUMAN; HYPOXIA; MALE; METABOLISM; OXYGEN CONSUMPTION; PHYSIOLOGY; PROCEDURES; RANDOMIZED CONTROLLED TRIAL; RUNNING; SKELETAL MUSCLE; TIME FACTOR; YOUNG ADULT;

ATHLETIC PERFORMANCE; ENERGY INTAKE; ENERGY METABOLISM; EXERCISE TEST; GLYCOGEN; HUMANS; HYPOXIA; MALE; MUSCLE, SKELETAL; OXYGEN CONSUMPTION; PHOSPHOCREATINE; PHYSICAL CONDITIONING, HUMAN; RUNNING; TIME FACTORS; YOUNG ADULT;

EID: 85030693608     PISSN: 01724622     EISSN: 14393964     Source Type: Journal    
DOI: 10.1055/s-0043-117413     Document Type: Article

References (38)

1. 31 P spectroscopy by fully adiabatic extended image selected in vivo spectroscopy: a comparison between 3T and 7T. Magn Reson Med: 2011; 66 923 930
2. Borg GA. Perceived exertion: a note on history and methods. Med Sci Sports: 1973; 5 90 93
3. Brocherie F. Girard O. Faiss R. Millet GP. High-intensity intermittent training in hypoxia: a double-blinded, placebo-controlled field study in youth football players. J Strength Cond Res: 2015; 29 226 237
4. Burgomaster K. A. Cermak N. M. Phillips S. M. Benton C. R. Bonen A. Gibala M. J. Divergent response of metabolite transport proteins in human skeletal muscle after sprint interval training and detraining. Am J Physiol: 2007; 292 R1970 1976
5. Burgomaster K. A. Heigenhauser G. J. Gibala M. J. Effect of short-term sprint interval training on human skeletal muscle carbohydrate metabolism during exercise and time-trial performance. J Appl Physiol: 2006; 100 2041 2047
6. Burgomaster K. A. Howarth K. R. Phillips S. M. Rakobowchuk M. Macdonald M. J. McGee S. L. Gibala M. J. Similar metabolic adaptations during exercise after low volume sprint interval and traditional endurance training in humans. J Physiol: 2008; 586 151 160
7. Burgomaster K. A. Hughes S. C. Heigenhauser G. J. Bradwell S. N. Gibala M. J. Six sessions of sprint interval training increases muscle oxidative potential and cycle endurance capacity in humans. J Appl Physiol: 2005; 98 1985 1990
8. Bussau V. A. Fairchild T. J. Rao A. Steele P. Fournier PA. Carbohydrate loading in human muscle: an improved 1 day protocol. Eur J Appl Physiol: 2002; 87 290 295
9. Cartee G. D. Douen A. G. Ramlal T. Klip A. Holloszy JO. Stimulation of glucose transport in skeletal muscle by hypoxia. J Appl Physiol: 1991; 70 1593 1600
10. Dawson B. Repeated-sprint ability: where are we? Int J Sports Physiol Perform: 2012; 7 285 289
11. Faiss R. Girard O. Millet GP. Advancing hypoxic training in team sports: from intermittent hypoxic training to repeated sprint training in hypoxia. Br J Sports Med: 2013; 47 01 i45 50
12. Faiss R. Leger B. Vesin J. M. Fournier P. E. Eggel Y. Dériaz O. Millet GP. Significant molecular and systemic adaptations after repeated sprint training in hypoxia. PLoS One: 2013; 8 e56522
13. Faiss R. Willis S. Born D. P. Sperlich B. Vesin J. M. Holmberg H. C. Millet GP. Repeated double-poling sprint training in hypoxia by competitive cross-country skiers. Med Sci Sports Exerc: 2015; 47 809 817
14. Forbes S. C. Slade J. M. Meyer RA. Short-term high-intensity interval training improves phosphocreatine recovery kinetics following moderate-intensity exercise in humans. Appl Physiol Nutr Metab: 2008; 33 1124 1131
15. Galvin H. M. Cooke K. Sumners D. P. Mileva K. N. Bowtell JL. Repeated sprint training in normobaric hypoxia. Br J Sports Med: 2013; 47 01 i74 79
16. Gatterer H. Philippe M. Menz V. Mosbach F. Faulhaber M. Burtscher M. Shuttle-run sprint training in hypoxia for youth elite soccer players: a pilot study. J Sports Sci Med: 2014; 13 731 735
17. Gibala M. J. Little J. P. van Essen M. Wilkin G. P. Burgomaster K. A. Safdar A. Raha S. Tarnopolsky M. A. Short-term sprint interval versus traditional endurance training: similar initial adaptations in human skeletal muscle and exercise performance. J Physiol: 2006; 575 901 911
18. Glaister M. Howatson G. Pattison J. R. McInnes G. The reliability and validity of fatigue measures during multiple-sprint work: an issue revisited. J Strength Cond Res: 2008; 22 1597 1601
19. Goods P. S. Dawson B. Landers G. J. Gore C. J. Pelling P. No additional benefit of repeat-sprint training in hypoxia than in normoxia on sea-level repeat-sprint ability. J Sports Sci Med: 2015; 14 681 688
20. Hamlin M. J. Marshall H. C. Hellemans J. Ainslie P. N. Anglem N. Effect of intermittent hypoxic training on 20 km time trial and 30s anaerobic performance. Scand J Med Sci Sports: 2010; 20 651 661
21. Hamlin M. J. Olsen P. D. Marshall H. C. Lizamore C. A. Elliot CA. Hypoxic repeat-sprint training improves rugby player's repeated sprint but not endurance performance. Front Physiol: 2017; 8 24
22. Harriss D. J. Atkinson G. Ethical standards in sport and exercise science research: 2016 update. Int J Sports Med: 2015; 36 1121 1124
23. Hasegawa Y. Ijichi T. Kurosawa Y. Hamaoka T. Goto K. Planned overreaching and subsequent short-term detraining enhance cycle sprint performance. Int J Sports Med: 2015; 36 666 671
24. Inness M. W. Billaut F. Walker E. J. Petersen A. C. Sweeting A. J. Aughey RJ. Heavy resistance training in hypoxia enhances 1RM squat performance. Front Physiol: 2016; 7 502
25. Kasai N. Mizuno S. Ishimoto S. Sakamoto E. Maruta M. Goto K. Effect of training in hypoxia on repeated sprint performance in female athletes. Springerplus: 2015; 4 310
26. Kasai N, Mizuno S, Ishimoto S, Sakamoto E, Maruta M, Kurihara T, Kurosawa Y, Goto K. Impact of 6 consecutive days of sprint training in hypoxia on performance in competitive sprint runners. J Strength Cond Res 2017 [ahead of print]
27. 31 P magnetic resonance spectroscopy techniques: a quantitative review. Acta Physiol (Oxf): 2015; 213 107 144
28. 31 P MRS: a quantitative review. NMR Biomed: 2007; 20 555 565
29. Kon M. Nakagaki K. Ebi Y. Nishiyama T. Russell AP. Hormonal and metabolic responses to repeated cycling sprints under different hypoxic conditions. Growth Horm IGF Res: 2015; 25 121 126
30. Larsen R. G. Maynard L. Kent JA. High-intensity interval training alters ATP pathway flux during maximal muscle contractions in humans. Acta Physiol: 2014; 211 147 160
31. Lundby C. Millet G. P. Calbet J. A. Bärtsch P. Subudhi AW. Does 'altitude training' increase exercise performance in elite athletes? Br J Sports Med: 2012; 46 792 795
32. Mackenzie R. Maxwell N. Castle P. Brickley G. Watt P. Acute hypoxia and exercise improve insulin sensitivity (S(I) (2)) in individuals with type 2 diabetes. Diabetes Metab Res Rev: 2011; 27 94 101
33. McLean B. D. Gore C. J. Kemp J. Application of 'live low-train high' for enhancing normoxic exercise performance in team sport athletes. Sports Med: 2014; 44 1275 1287
34. Parra J. Cadefau J. A. Rodas G. Amigó N. Cussó R. The distribution of rest periods affects performance and adaptations of energy metabolism induced by high-intensity training in human muscle. Acta Physiol Scand: 2000; 169 157 165
35. Richter E. A. Hargreaves M. Exercise, GLUT4, and skeletal muscle glucose uptake. Physiol Rev: 2013; 93 993 1017
36. Rodas G. Ventura J. L. Cadefau J. A. Cussó R. Parra J. A short training programme for the rapid improvement of both aerobic and anaerobic metabolism. Eur J Appl Physiol: 2000; 82 480 486
37. Saanijoki T. Nummenmaa L. Eskelinen J. J. Savolainen A. M. Vahlberg T. Kalliokoski K. K. Hannukainen JC. Affective responses to repeated sessions of high-intensity interval training. Med Sci Sports Exerc: 2015; 47 2604 2611
38. 13 C MRS reveals a small diurnal variation in the glycogen content of human thigh muscle. NMR Biomed: 2015; 28 650 655