Energetics of male field-sport athletes during the 3-min all-out test for linear and shuttle-based running
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[1] R. Pettitt,et al. Oxygen uptake kinetics and speed-time correlates of modified 3-minute all-out shuttle running in soccer players , 2018, PloS one.
[2] L. Passfield,et al. Critical power: How different protocols and models affect its determination. , 2017, Journal of science and medicine in sport.
[3] Mark E. Hartman,et al. Validation of the 3-Minute All-Out Exercise Test for Shuttle Running Prescription. , 2017, Journal of strength and conditioning research.
[4] I. E. Clark,et al. Normative Data for Critical Speed and D' for High-Level Male Rugby Players , 2017, Journal of strength and conditioning research.
[5] A. Vanhatalo,et al. The ‘Critical Power’ Concept: Applications to Sports Performance with a Focus on Intermittent High-Intensity Exercise , 2017, Sports Medicine.
[6] Anni Vanhatalo,et al. Critical Power: An Important Fatigue Threshold in Exercise Physiology. , 2016, Medicine and science in sports and exercise.
[7] M. Halaki,et al. Energetic and Metabolic Power Demands of National Rugby League Match-Play , 2016, International Journal of Sports Medicine.
[8] J Cassirame,et al. Monitoring Locomotor Load in Soccer: Is Metabolic Power, Powerful? , 2015, International Journal of Sports Medicine.
[9] P. Beek,et al. Measured and estimated energy cost of constant and shuttle running in soccer players. , 2015, Medicine and science in sports and exercise.
[10] Ermanno Rampinini,et al. Metabolic power and energetic costs of professional Australian Football match-play. , 2015, Journal of science and medicine in sport.
[11] A. Botter,et al. The energy cost of sprint running and the role of metabolic power in setting top performances , 2015, European Journal of Applied Physiology.
[12] Paola Zamparo,et al. Energetics of shuttle runs: the effects of distance and change of direction. , 2014, International journal of sports physiology and performance.
[13] G. Sandercock,et al. Pilot investigation of the oxygen demands and metabolic cost of incremental shuttle walking and treadmill walking in patients with cardiovascular disease , 2014, BMJ Open.
[14] F. Diefenthaeler,et al. Continuous and intermittent running to exhaustion at maximal lactate steady state: neuromuscular, biochemical and endocrinal responses. , 2013, Journal of science and medicine in sport.
[15] J. Fulford,et al. Muscle metabolic responses during high-intensity intermittent exercise measured by (31)P-MRS: relationship to the critical power concept. , 2013, American journal of physiology. Regulatory, integrative and comparative physiology.
[16] Hiroaki Tanaka,et al. A novel method for calculating the energy cost of turning during running , 2013, Open access journal of sports medicine.
[17] T. Barstow,et al. A single test for the determination of parameters of the speed–time relationship for running , 2013, Respiratory Physiology & Neurobiology.
[18] P. E. D. Prampero,et al. The energy cost of shuttle running , 2013, European Journal of Applied Physiology.
[19] P. Weyand,et al. Sprint Exercise Performance: Does Metabolic Power Matter? , 2012, Exercise and sport sciences reviews.
[20] N. Jamnick,et al. 3-min All-out Exercise Test for Running , 2012, International Journal of Sports Medicine.
[21] G. Ferretti,et al. Energetics of running in top-level marathon runners from Kenya , 2012, European Journal of Applied Physiology.
[22] S. Ahmaidi,et al. Assessing running economy during field running with changes of direction: application to 20 m shuttle runs. , 2011, International journal of sports physiology and performance.
[23] Anni Vanhatalo,et al. Muscle fiber recruitment and the slow component of O2 uptake: constant work rate vs. all-out sprint exercise. , 2011, American journal of physiology. Regulatory, integrative and comparative physiology.
[24] C. Kamphoff,et al. Validity of 3 Protocols for Verifying VO2max , 2011, International journal of sports medicine.
[25] Andrew M. Jones,et al. Similar metabolic perturbations during all‐out and constant force exhaustive exercise in humans: a 31P magnetic resonance spectroscopy study , 2010, Experimental physiology.
[26] F. Nakamura,et al. Physiological Responses to Shuttle Repeated-Sprint Running , 2010, International journal of sports medicine.
[27] Peter Hamer,et al. Fatigue in repeated-sprint exercise is related to muscle power factors and reduced neuromuscular activity , 2008, European Journal of Applied Physiology.
[28] Matthew W Bundle,et al. Energetics of high-speed running: integrating classical theory and contemporary observations. , 2005, American journal of physiology. Regulatory, integrative and comparative physiology.
[29] David C. Poole,et al. Oxygen Uptake Kinetics in Sport, Exercise and Medicine , 2005 .
[30] Matthew W Bundle,et al. High-speed running performance: a new approach to assessment and prediction. , 2003, Journal of applied physiology.
[31] A. Minetti,et al. Energy cost of walking and running at extreme uphill and downhill slopes. , 2002, Journal of applied physiology.
[32] J. Wilmore,et al. Physiology of Sport and Exercise , 1995 .
[33] K. Sahlin,et al. Metabolic Factors in Fatigue , 1992, Sports medicine.
[34] David A. Winter,et al. Biomechanics and Motor Control of Human Movement , 1990 .
[35] Riccardo Bernardini,et al. Energy cost and metabolic power in elite soccer: a new match analysis approach. , 2010, Medicine and science in sports and exercise.
[36] S. Marshall,et al. Progressive statistics for studies in sports medicine and exercise science. , 2009, Medicine and science in sports and exercise.
[37] D. Allen,et al. Skeletal muscle fatigue: cellular mechanisms. , 2008, Physiological reviews.
[38] R. Connett,et al. How phosphocreatine buffers cyclic changes in ATP demand in working muscle. , 1989, Advances in experimental medicine and biology.