EFFECTS OF TAPER ON SWIM PERFORMANCE - PRACTICAL IMPLICATIONS

被引：52

作者：

HOUMARD, JA

JOHNS, RA

机构：

[1] Human Performance Laboratory, East Carolina University, Greenville, North Carolina, 27858, Sports Medicine Building

[2] Health and Exercise Science Department, Northeast Missouri State University, Kirksville, Missouri

来源：

SPORTS MEDICINE | 1994年 / 17卷 / 04期

关键词：

D O I：

10.2165/00007256-199417040-00003

中图分类号：

G8 [体育];

学科分类号：

04 ; 0403 ;

摘要：

Competitive swimmers commonly focus upon optimising performance at a single competition. A period where training volume is incrementally reduced or 'tapered' often precedes such a competition. The use of taper is justified as increases in muscular power, and the restoration of plasma haematocrit, haemoglobin and creatine kinase are evident with this training reduction. A consistent performance improvement of approximately 3% has also been reported with taper in competitive swimmers. However, there are limitations in terms of what comprises a successful taper schedule. It appears that a taper which improves performance involves a substantial (60 to 90%) graded reduction in training volume. and daily high intensity interval work over a 7- to 21-day period. Training frequency should be reduced by no more than 50%; a more conservative estimate would be to reduce frequency by approximately 20%. Optimal performance is likely when the reduction in training frequency is combined with the qualitative knowledge of the coach and/or athlete during taper.

引用

页码：224 / 232

页数：9

共 37 条

[1]

Burke E.R., Falsetti H.L., Feld R.D., Et al., Creatine kinase levels in competitive swimmers during a season of training, Scandinavian Journal of Sports Science, 4, pp. 1-4, (1982)

[2]

Costill D.L., Carbohydrates for exercise: dietary demands for optimal performance, International Journal of Sports Medicine, 9, pp. 1-18, (1988)

[3]

Costill D.L., King D.S., Holdren A., Et al., Sprint speed vs swimming power, Swimming Technique, 20, pp. 20-21, (1983)

[4]

Costill D.L., King D.S., Thomas R., Et al., Effects of reduced training on muscular power in swimmers, Physician and Sportsmedicine, 13, pp. 94-101, (1985)

[5]

Costill D.L., Rayfield R., Kirwan J., Et al., A computer based system for the measurement of force and power during front crawl swimming, Journal of Swimming Research, 2, pp. 16-19, (1986)

[6]

Costill D.L., Thomas R., Robergs R.A., Et al., Adaptations to swimming training: influence of training volume, Medicine and Science in Sports and Exercise, 23, pp. 371-377, (1991)

[7]

Craig A.B., Pendergast D.R., Relationship of stroke rate, distance per stroke, and velocity in competitive swimming, Medicine and Science in Sports and Exercise, 11, pp. 278-283, (1979)

[8]

Dudley G.A., Djamil R., Incompatibility of endurance- and strength-training modes of exercise, Journal of Applied Physiology, 59, pp. 1446-1451, (1985)

[9]

Fitz-Clarke J.R., Morton R.H., Banister E.W., Optimizing athletic performance by influence curves, Journal of Applied Physiology, 71, pp. 1151-1158, (1991)

[10]

Hickson R.C., Interference of strength development by simultaneously training for strength and endurance, European Journal of Applied Physiology and Occupational Physiology, 45, pp. 255-263, (1980)

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