Abstract:This study aimed (I) to compare the number of repetitions that can be completed to failure (XRM) and before reaching a 15%, 30%, or 45% velocity loss threshold (XVLT) in the bench press exercise performed using different grip widths, and (II) to examine the inter-individual variability in the percentage of completed repetitions with respect to the XRM when the set volume is prescribed based on a fixed number of repetitions (FNR) and several velocity loss thresholds (VLT). Nineteen men performed four separate s… Show more
“…The discrepancy between studies may be attributed to certain methodological differences, such as the load adjustment method (% 1RM vs. velocity obtained from general or individual load-velocity relationships), velocity variable (mean velocity vs. mean propulsive velocity), or execution mode (touch-and-go technique vs. concentric-only technique from the bar holders or chest). Furthermore, the present findings are in line with previous studies (6,19,24) that have observed a comparable interindividual variability for the %Rep completed for a given %VL (between-subjects CV = 2.9–31.3%) and the actual number of repetitions that can be completed to failure against a given relative load (between-subjects CV = 8.6–38.5%). The high interindividual variability generally reported for the %Rep associated with different %VL suggests that implementing the same magnitude of %VL for all subjects does not ensure a homogeneous level of effort across individuals.…”
Section: Discussionsupporting
confidence: 93%
“…Therefore, it is plausible to observe a slightly lower interindividual variability for the maximal number of repetitions that can be completed to failure when loads are prescribed from the individual load-velocity relationship (8,24). Finally, in line with previous studies (6–8,19,22,24), the use of a Smith machine, which restricts the movement of the barbell to the vertical direction, may have limited the ecological validity of our results for athletes using free weights in their training programs. Future studies should examine the pattern of repetition velocity decline during training sets to failure with free-weight exercises, but a greater accuracy of velocity recordings for the free-weight variants of the exercises examined above is unlikely.
Practical Applications
The individual %Rep-%VL relationships present a better fit than the general %Rep-%VL relationships when they are determined in sets of the Smith machine prone bench pull exercise performed to failure against different loads.…”
Section: Discussionsupporting
confidence: 61%
“…González-Badillo et al (7) and Sánchez-Moreno et al (24) observed low-to-unacceptable interindividual variability (between-subjects CV from 2.5 to 21.4%) for the %Rep as the %VL decreased from 85 to 15% against loads ranging from 50 to 90% 1RM. In contrast, García-Ramos et al (6) and Pérez-Castilla et al (19) reported a higher interindividual variability for the %Rep achieved at 15%VL (between-subjects CV = 28.5–34.3%), 30%VL (between-subjects CV = 16.6–25.7%), and 45 %VL (between-subjects CV = 10.7–19.1%) against multiple short (≤12 repetitions) or long (>12 repetitions) training sets or the 75% 1RM load using different grip widths (narrow, medium, wide, or self-selected), respectively. In agreement with Pérez-Castilla et al (19), the %Rep associated with different %VL also showed a high interindividual variability for the 3 loads evaluated in this study (60% 1RM, 70% 1RM, and 80% 1RM).…”
Section: Discussionmentioning
confidence: 93%
“…In contrast, García-Ramos et al (6) and Pérez-Castilla et al (19) reported a higher interindividual variability for the %Rep achieved at 15%VL (between-subjects CV = 28.5–34.3%), 30%VL (between-subjects CV = 16.6–25.7%), and 45 %VL (between-subjects CV = 10.7–19.1%) against multiple short (≤12 repetitions) or long (>12 repetitions) training sets or the 75% 1RM load using different grip widths (narrow, medium, wide, or self-selected), respectively. In agreement with Pérez-Castilla et al (19), the %Rep associated with different %VL also showed a high interindividual variability for the 3 loads evaluated in this study (60% 1RM, 70% 1RM, and 80% 1RM). The discrepancy between studies may be attributed to certain methodological differences, such as the load adjustment method (% 1RM vs. velocity obtained from general or individual load-velocity relationships), velocity variable (mean velocity vs. mean propulsive velocity), or execution mode (touch-and-go technique vs. concentric-only technique from the bar holders or chest).…”
Section: Discussionmentioning
confidence: 93%
“…In addition, the numbers of repetitions based on %VL has been justified by the strong relationship observed between the magnitude of %VL and the percentage of completed repetitions with respect to the maximal number of repetitions that can be completed to failure (%Rep) against a given relative load (coefficient of determination [ R 2 ] = 0.80–1.00) (7,8,22,24,25). The %Rep estimated from different general %Rep-%VL equations has a poor interindividual variability (between-subjects CV = 2.5–21.4%) (7,24), although definitive evidence is still lacking (6,19). Based on these findings, it has been suggested that when different subjects reach a given %VL, they likely experience a comparable level of effort independently of the actual number of repetitions performed (7).…”
Pérez-Castilla, A, Miras-Moreno, S, Janicijevic, D, and García-Ramos, A. Velocity loss is not an accurate predictor of the percentage of completed repetitions during the prone bench pull exercise. J Strength Cond Res 37(5): 1001–1008, 2023—The primary aim of this study was to explore the goodness of fit and accuracy of both general and individual relationships between the magnitude of velocity loss (%VL) and the percentage of performed repetitions with respect to the maximal number of repetitions that can be completed to failure (%Rep) during the Smith machine prone bench pull exercise. Fifteen male sports science students completed a preliminary session to determine the bench pull one-repetition maximum (1RM) and 2 identical experimental sessions separated by 48–72 hours. In each experimental session, subjects randomly performed single sets of repetitions to failure separated by 10 minutes against the 60% 1RM, 70% 1RM, and 80% 1RM during the Smith machine bench pull exercise. Individual %Rep-%VL relationships presented a greater goodness of fit than general %Rep-%VL relationships at the 60% 1RM (R2 = 0.85–0.97 vs. 0.79–0.85), 70% 1RM (R2 = 0.84–0.99 vs. 0.77–0.84), and 80% 1RM (R2 = 0.84–1.00 vs. 0.74–0.80). However, the accuracy (absolute errors) in estimating the %Rep during the second testing session based on the %Rep-%VL equations obtained in the first testing session did not differ between the individual and general %Rep-%VL equations in 8 of 9 comparisons (p ≥ 0.102). The absolute errors between the actual and predicted %REP were unacceptable (>10%) in 11 of 18 comparisons, and acceptable (5–10%) in 7 of 18 comparisons. These results highlight that the %Rep cannot be estimated with high degree of accuracy from VL recordings during the Smith machine bench pull exercise, regardless of whether individual or general Rep-%VL relationships are considered.
“…The discrepancy between studies may be attributed to certain methodological differences, such as the load adjustment method (% 1RM vs. velocity obtained from general or individual load-velocity relationships), velocity variable (mean velocity vs. mean propulsive velocity), or execution mode (touch-and-go technique vs. concentric-only technique from the bar holders or chest). Furthermore, the present findings are in line with previous studies (6,19,24) that have observed a comparable interindividual variability for the %Rep completed for a given %VL (between-subjects CV = 2.9–31.3%) and the actual number of repetitions that can be completed to failure against a given relative load (between-subjects CV = 8.6–38.5%). The high interindividual variability generally reported for the %Rep associated with different %VL suggests that implementing the same magnitude of %VL for all subjects does not ensure a homogeneous level of effort across individuals.…”
Section: Discussionsupporting
confidence: 93%
“…Therefore, it is plausible to observe a slightly lower interindividual variability for the maximal number of repetitions that can be completed to failure when loads are prescribed from the individual load-velocity relationship (8,24). Finally, in line with previous studies (6–8,19,22,24), the use of a Smith machine, which restricts the movement of the barbell to the vertical direction, may have limited the ecological validity of our results for athletes using free weights in their training programs. Future studies should examine the pattern of repetition velocity decline during training sets to failure with free-weight exercises, but a greater accuracy of velocity recordings for the free-weight variants of the exercises examined above is unlikely.
Practical Applications
The individual %Rep-%VL relationships present a better fit than the general %Rep-%VL relationships when they are determined in sets of the Smith machine prone bench pull exercise performed to failure against different loads.…”
Section: Discussionsupporting
confidence: 61%
“…González-Badillo et al (7) and Sánchez-Moreno et al (24) observed low-to-unacceptable interindividual variability (between-subjects CV from 2.5 to 21.4%) for the %Rep as the %VL decreased from 85 to 15% against loads ranging from 50 to 90% 1RM. In contrast, García-Ramos et al (6) and Pérez-Castilla et al (19) reported a higher interindividual variability for the %Rep achieved at 15%VL (between-subjects CV = 28.5–34.3%), 30%VL (between-subjects CV = 16.6–25.7%), and 45 %VL (between-subjects CV = 10.7–19.1%) against multiple short (≤12 repetitions) or long (>12 repetitions) training sets or the 75% 1RM load using different grip widths (narrow, medium, wide, or self-selected), respectively. In agreement with Pérez-Castilla et al (19), the %Rep associated with different %VL also showed a high interindividual variability for the 3 loads evaluated in this study (60% 1RM, 70% 1RM, and 80% 1RM).…”
Section: Discussionmentioning
confidence: 93%
“…In contrast, García-Ramos et al (6) and Pérez-Castilla et al (19) reported a higher interindividual variability for the %Rep achieved at 15%VL (between-subjects CV = 28.5–34.3%), 30%VL (between-subjects CV = 16.6–25.7%), and 45 %VL (between-subjects CV = 10.7–19.1%) against multiple short (≤12 repetitions) or long (>12 repetitions) training sets or the 75% 1RM load using different grip widths (narrow, medium, wide, or self-selected), respectively. In agreement with Pérez-Castilla et al (19), the %Rep associated with different %VL also showed a high interindividual variability for the 3 loads evaluated in this study (60% 1RM, 70% 1RM, and 80% 1RM). The discrepancy between studies may be attributed to certain methodological differences, such as the load adjustment method (% 1RM vs. velocity obtained from general or individual load-velocity relationships), velocity variable (mean velocity vs. mean propulsive velocity), or execution mode (touch-and-go technique vs. concentric-only technique from the bar holders or chest).…”
Section: Discussionmentioning
confidence: 93%
“…In addition, the numbers of repetitions based on %VL has been justified by the strong relationship observed between the magnitude of %VL and the percentage of completed repetitions with respect to the maximal number of repetitions that can be completed to failure (%Rep) against a given relative load (coefficient of determination [ R 2 ] = 0.80–1.00) (7,8,22,24,25). The %Rep estimated from different general %Rep-%VL equations has a poor interindividual variability (between-subjects CV = 2.5–21.4%) (7,24), although definitive evidence is still lacking (6,19). Based on these findings, it has been suggested that when different subjects reach a given %VL, they likely experience a comparable level of effort independently of the actual number of repetitions performed (7).…”
Pérez-Castilla, A, Miras-Moreno, S, Janicijevic, D, and García-Ramos, A. Velocity loss is not an accurate predictor of the percentage of completed repetitions during the prone bench pull exercise. J Strength Cond Res 37(5): 1001–1008, 2023—The primary aim of this study was to explore the goodness of fit and accuracy of both general and individual relationships between the magnitude of velocity loss (%VL) and the percentage of performed repetitions with respect to the maximal number of repetitions that can be completed to failure (%Rep) during the Smith machine prone bench pull exercise. Fifteen male sports science students completed a preliminary session to determine the bench pull one-repetition maximum (1RM) and 2 identical experimental sessions separated by 48–72 hours. In each experimental session, subjects randomly performed single sets of repetitions to failure separated by 10 minutes against the 60% 1RM, 70% 1RM, and 80% 1RM during the Smith machine bench pull exercise. Individual %Rep-%VL relationships presented a greater goodness of fit than general %Rep-%VL relationships at the 60% 1RM (R2 = 0.85–0.97 vs. 0.79–0.85), 70% 1RM (R2 = 0.84–0.99 vs. 0.77–0.84), and 80% 1RM (R2 = 0.84–1.00 vs. 0.74–0.80). However, the accuracy (absolute errors) in estimating the %Rep during the second testing session based on the %Rep-%VL equations obtained in the first testing session did not differ between the individual and general %Rep-%VL equations in 8 of 9 comparisons (p ≥ 0.102). The absolute errors between the actual and predicted %REP were unacceptable (>10%) in 11 of 18 comparisons, and acceptable (5–10%) in 7 of 18 comparisons. These results highlight that the %Rep cannot be estimated with high degree of accuracy from VL recordings during the Smith machine bench pull exercise, regardless of whether individual or general Rep-%VL relationships are considered.
The maximal number of repetitions that can be completed at various percentages of the one repetition maximum (1RM) [REPS ~ %1RM relationship] is foundational knowledge in resistance exercise programming. The current REPS ~ %1RM relationship is based on few studies and has not incorporated uncertainty into estimations or accounted for between-individuals variation. Therefore, we conducted a meta-regression to estimate the mean and between-individuals standard deviation of the number of repetitions that can be completed at various percentages of 1RM. We also explored if the REPS ~ %1RM relationship is moderated by sex, age, training status, and/or exercise. A total of 952 repetitions-to-failure tests, completed by 7289 individuals in 452 groups from 269 studies, were identified. Study groups were predominantly male (66%), healthy (97%), < 59 years of age (92%), and resistance trained (60%). The bench press (42%) and leg press (14%) were the most commonly studied exercises. The REPS ~ %1RM relationship for mean repetitions and standard deviation of repetitions were best described using natural cubic splines and a linear model, respectively, with mean and standard deviation for repetitions decreasing with increasing %1RM. More repetitions were evident in the leg press than bench press across the loading spectrum, thus separate REPS ~ %1RM tables were developed for these two exercises. Analysis of moderators suggested little influences of sex, age, or training status on the REPS ~ %1RM relationship, thus the general main model REPS ~ %1RM table can be applied to all individuals and to all exercises other than the bench press and leg press. More data are needed to develop REPS ~ %1RM tables for other exercises.
This study examined the impact of different inter-repetition rest (IRR)
configurations (zero seconds [IRR0], three seconds [IRR3], and self-selected
less than five seconds [SSIRR]) on estimating the number of repetitions (Nrep)
and the percentage of completed repetitions relative to the maximum number of
repetitions possible to failure (%rep) after reaching 10%,
20%, and 30% velocity loss thresholds (VLT). Eighteen men
completed three sessions, each with a different IRR configuration, separated by
48–72 hours. Single sets of repetitions to momentary muscular
failure were performed against 65%, 75%, and 85% of the
one-repetition maximum during free-weight back squat and bench press exercises.
No significant differences were reported between IRR configurations for the Nrep
(P≥0.089) and %rep (P≥0.061), except
for %rep after reaching the 20–30%VLT against
65%1RM and the 10–20%VLT against 75%1RM in the
bench press exercise (P≤0.048). Additionally, both Nrep and
%rep exhibited high interindividual variability (between-subject
CV=14–79%) across the different IRR configurations. The
individual %rep-%VLT relationships were slightly stronger than
the general %rep-%VLT relationships (median
R
2
=0.914–0.971 vs.
0.698–0.900). Overall, regardless of the IRR configuration, this novel
velocity-based approach does not guarantee the same effort levels across
subjects in the free-weight back squat and bench press sets.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
