PROTEIN-INTAKE AND ATHLETIC PERFORMANCE

被引：31

作者：

LEMON, PWR

PROCTOR, DN

机构：

[1] Applied Physiology Research Laboratory, Schools of Biomedical Sciences and Physical Education, Recreation and Dance, Kent State University, Kent, Ohio

来源：

SPORTS MEDICINE | 1991年 / 12卷 / 05期

关键词：

D O I：

10.2165/00007256-199112050-00004

中图分类号：

G8 [体育];

学科分类号：

04 ; 0403 ;

摘要：

For most of the current century, exercise/nutritional scientists have generally accepted the belief that exercise has little effect on protein/amino acid requirements. However, during the same time period many athletes (especially strength athletes) have routinely consumed diets high in protein. In recent years, the results of a number of investigations involving both strength and endurance athletes indicate that, in fact, exercise does increase protein/amino acid need. For endurance athletes, regular exercise may increase protein need by 50 to 100%. For strength athletes, the data are less clear; however, protein intakes in excess of sedentary needs may enhance muscle development. Despite these observations increased protein intake may not improve athletic performance because many athletes routinely consume 150 to 200% of sedentary protein requirements. Assuming total energy intake is sufficient to cover the high expenditures caused by daily training, a diet containing 12 to 15% of its energy from protein should be adequate for both types of athletes.

引用

页码：313 / 325

页数：13

共 116 条

[1]

Afting E.G., Berhart W., Janzen R.W.G., Rothig H.-J., Quantitative importance of non-skeletal muscle N<sup>+</sup>-methylhistidine and creatinine in human urine, Biochemical Journal, 200, pp. 449-452, (1981)

[2]

Astrand P.O., Rodahl K., Textbook of work physiology, (1986)

[3]

Babij P., Matthews S.M., Rennie M.F., Changes in blood ammonia, lactate and amino acids in relation to workload during bicycle ergometer exercise in man, European Journal of Applied Physiology, 50, pp. 405-411, (1983)

[4]

Beddoe A.H., Streat S.J., Hill G.L., Knight G.S., New approaches to clinical assessment of body tissues, Body composition in youth and adults, pp. 65-71, (1985)

[5]

Behnke A.R., Wilmore J.H., Evaluation and regulation of body build and composition, (1974)

[6]

Bingham S., Cummings J.H., The use of 4-aminobenzoic acid as a marker to validate completeness of 24h urine collections in man, Clinical Science, 64, pp. 629-635, (1983)

[7]

Bodwell C.E., Schuster E.M., Kyle E., Brooks B., Womack M., Et al., Obligatory urinary and fecal nitrogen losses in young women, older men, and young men and the factorial estimation of adult protein requirements, American Journal of Clinical Nutrition, 32, pp. 2450-2459, (1979)

[8]

Brenner B.M., Meyer T.W., Hostetter T.H., Dietary protein intake and the progressive nature of kidney disease: the role of hemodynamically mediated glomerular injury in the pathogenesis of progressive glomerular sclerosis in aging, renal ablation and intrinsic renal disease, New England Journal of Medicine, 307, pp. 652-659, (1982)

[9]

Brouns F., Saris W.H.M., Beckers E., Adlercreutz H., van der Vusse G.J., Et al., Metabolic changes induced by sustained exhaustive cycling and diet manipulation, International Journal of Sports Medicine, 10, (1989)

[10]

Brouns F., Saris W.H.M., Stroecken J., Beckers E., Thijssen R., Et al., Eating, drinking, and cycling: a controlled Tour de France simulation study, part 1, International Journal of Sports Medicine, 10, (1989)

← 1 2 3 4 5 6 7 8 9 10 →