Estimating the One-repetition Maximum on the Leg-press Exercise in Female Breast Cancer Survivors

Overview

Journal PeerJ

Specialties Biology
Environmental Health
General Medicine

Date 2023 Oct 3

PMID 37786578

Authors

David M Diez-Fernandez

Andres Baena-Raya

Amador Garcia-Ramos

Alba Esteban-Simon

Manuel A Rodriguez-Perez

Antonio J Casimiro-Andujar

Alberto Soriano-Maldonado

Affiliations

Soon will be listed here.

Abstract

We examined the accuracy of twelve different velocity-based methods for predicting the bilateral leg-press exercise one-repetition maximum (1RM) in breast cancer survivors. Twenty-one female breast cancer survivors (age 50.2 ± 10.8 years) performed an incremental loading test up to the 1RM. Individual load-velocity relationships were modeled by linear and quadratic polynomial regression models considering the mean velocity (MV) and peak velocity (PV) values recorded at five incremental loads (~45-55-65-75-85% of 1RM) (multiple-point methods) and by a linear regression model considering only the two distant loads (~45-85% of 1RM) (two-point method). The 1RM was always estimated through these load-velocity relationships as the load associated with a general (MV: 0.24 m/s; PV: 0.60 m/s) and an individual (MV and PV of the 1RM trial) minimal velocity threshold (MVT). Compared to the actual 1RM, the 1RMs estimated by all linear regression models showed trivial differences (Hedge's g ranged from 0.08 to 0.17), very large to nearly perfect correlations (r ranged from 0.87 to 0.95), and no heteroscedasticity of the errors (coefficient of determination () < 0.10 obtained from the relationship of the raw differences between the actual and predicted 1RMs with their average value). Given the acceptable and comparable accuracy for all 1RM linear prediction methods, the two-point method and a general MVT could be recommended to simplify the testing procedure of the bilateral leg-press 1RM in breast cancer survivors.

Citing Articles

Optimizing resistance training intensity in supportive care for survivors of breast cancer: velocity-based approach in the row exercise.

Diez-Fernandez D, Esteban-Simon A, Baena-Raya A, Perez-Castilla A, Rodriguez-Perez M, Soriano-Maldonado A Support Care Cancer. 2024; 32(9):617.

PMID: 39207478 DOI: 10.1007/s00520-024-08824-5.

Optimizing exercise prescription during breast cancer rehabilitation in women: Analysis of the load-velocity relationship in the box squat exercise.

Diez-Fernandez D, Esteban-Simon A, Baena-Raya A, Rodriguez-Rosell D, Conceicao F, Rodriguez-Perez M Eur J Sport Sci. 2024; 24(7):1021-1031.

PMID: 38956790 PMC: 11235820. DOI: 10.1002/ejsc.12130.

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