Biophysical Impact of 5-Week Training Cessation on Sprint Swimming Performance

Jesús J Ruiz-Navarro; Ana Gay; Rodrigo Zacca; Francisco Cuenca-Fernández; Óscar López-Belmonte; Gracia López-Contreras; Esther Morales-Ortiz; Raúl Arellano

doi:10.1123/ijspp.2022-0045

Biophysical Impact of 5-Week Training Cessation on Sprint Swimming Performance

Int J Sports Physiol Perform. 2022 Jul 21;17(10):1463-1472. doi: 10.1123/ijspp.2022-0045. Print 2022 Oct 1.

Authors

Jesús J Ruiz-Navarro¹, Ana Gay¹, Rodrigo Zacca^{2

3}, Francisco Cuenca-Fernández¹, Óscar López-Belmonte¹, Gracia López-Contreras¹, Esther Morales-Ortiz¹, Raúl Arellano¹

Affiliations

¹ Aquatics Lab, Faculty of Sport Sciences, Department of Physical Education and Sports, University of Granada, Granada,Spain.
² Research Center in Physical Activity, Health and Leisure (CIAFEL), Faculty of Sports, University of Porto (FADEUP), Porto,Portugal.
³ Laboratory for Integrative and Translational Research in Population Health (ITR), Porto,Portugal.

PMID: 35894894
DOI: 10.1123/ijspp.2022-0045

Abstract

Purpose: To assess changes in swimming performance, anthropometrics, kinematics, energetics, and strength after 5-week training cessation.

Methods: Twenty-one trained and highly trained swimmers (13 males: 17.4 [3.1] y; 50-m front crawl 463 [77] FINA points; 8 females: 16.7 [1.7] y; 50-m front crawl 535 [48] FINA points) performed a 50-m front-crawl all-out swim test, dryland and pool-based strength tests, and 10-, 15-, 20-, and 25-m front-crawl all-out efforts for anaerobic critical velocity assessment before and after a 5-week training cessation. Heart rate and oxygen uptake (V˙O2) were continuously measured before and after the 50-m swim test (off-kinetics).

Results: Performance was impaired 1.9% (0.54 s) for males (P = .007, d = 0.91) and 2.9% (0.89 s) for females (P = .033, d = 0.93). Neither the anthropometrical changes (males: r2 = .516, P = .077; females: r2 = .096, P = .930) nor the physical activities that each participant performed during the off-season (males: r2 = .060, P = .900; females: r2 = .250, P = .734) attenuated performance impairments. Stroke rate and clean swimming speed decreased (P < .05), despite similar stroke length and stroke index (P > .05). Blood lactate concentrations remained similar (P > .05), but V˙O2 peak decreased in females (P = .04, d = 0.85). Both sexes showed higher heart rate before and after the 50-m swim test after 5 weeks (P < .05). Anaerobic metabolic power deterioration was only observed in males (P = .035, d = 0.65). Lower in-water force during tethered swimming at zero speed was observed in males (P = .033, d = 0.69). Regarding dryland strength, lower-body impairments were observed for males, while females showed upper-body impairments (P < .05).

Conclusions: A 5-week training cessation yielded higher heart rate in the 50-m front crawl, anaerobic pathways, and dryland strength impairments. Coaches should find alternatives to minimize detraining effects during the off-season.

Keywords: biomechanics; detraining; energetic; exercise physiology; oxygen uptake kinetics.

MeSH terms

Biomechanical Phenomena / physiology
Female
Humans
Lactic Acid*
Male
Oxygen
Swimming* / physiology
Water

Substances

Water
Lactic Acid
Oxygen