BODY MASS TO PREDICT 4-6 RM OF PECTORAL AND LEG MUSCLES EXERCISES IN BODYBUILDERS

Padulo, Johnny; Larion, Alin; Melenco, Ionel; Kuvačić, Goran; Georgescu, Adrian; Dhahbi, Wissem; Russo, Luca; Iuliano, Enzo; Migliaccio, Gian Mario

doi:10.1590/1517-8692202430012021_0505i

ABSTRACT

Introduction:

Submaximal strength testing appears to be valid to prescribe the intensity for strength training protocols that reduce the risk of injuries and testing time.

Objective:

This study aimed to assess the predictive ability of body mass parameters to estimate 4-6 repetitions maximum (4-6 RM) of Leg press 45°, Chest press, and Pull-down exercises.

Methods:

Eleven male bodybuilders (age 38.27 ± 10.48 years) participated in this study. Participants completed an incremental external load up to find the load allowing them to perform 4 to 6 maximal repetitions for each exercise in random order. The starting load was 50% of body mass for chest press and pull-down exercises and 100% for leg press. The load increment after each set was 20 kg for lower limb exercises and 10 kg for upper body exercises.

Results:

Results revealed that body mass had good to optimal relationships with 4-6 RM for all three exercises. Results showed that body mass had a good prediction ability for all three criterion measures.

Conclusion:

The prediction equations suggested in this study may allow coaches to estimate the 4-6 RM of leg press 45°, chest press, and pull-down performances. Evidence Level IV; Case series.

Keywords:
Predictions and Projections; Muscle Strength; Body Weight

RESUMEN

Introducción:

El test de fuerza submáxima parece ser válido para prescribir la intensidad en protocolos de entrenamiento de fuerza, reduciendo el riesgo de lesiones y la duración del test.

Objetivo:

Evaluar la capacidad predictiva de los parámetros de masa corporal para estimar 4-6 repeticiones máximas (4-6 RM) de ejercicios de Leg press 45°, Chest press y Pull-down realizados por fisicoculturistas.

Métodos:

Once fisicoculturistas masculinos (38,27 ± 10,48 años) participaron en el estudio. Completaron la carga externa incremental hasta encontrar la carga que les permitiera realizar de 4 a 6 repeticiones máximas para cada ejercicio, en orden aleatorio. La carga inicial se fijó en el 50% de la masa corporal para los ejercicios Chest press y Pull-down, y en el 100% para los ejercicios Leg press. El incremento de carga después de cada ronda fue de 20 kg para los miembros inferiores y 10 kg para los miembros superiores.

Resultados:

Los resultados revelaron que la masa corporal tiene relaciones satisfactorias con 4-6 RM para los tres ejercicios. Los resultados mostraron que la masa corporal tiene una buena capacidad predictiva en las tres medidas.

Conclusión:

Las ecuaciones de predicción sugeridas en este estudio pueden permitir a los entrenadores utilizar estos ejercicios para medir el rendimiento a 4-6 RM en ejercicios de Leg press 45°, Chest press y Pull-down. Nivel de Evidencia IV; serie de casos.

Descriptores:
Modelos Predictivos; Fuerza Muscular; Peso Corporal

RESUMO

Introdução:

O teste de força submáxima parece ser válido para prescrever a intensidade nos protocolos de treinamento de força, reduzindo o risco de lesões e duração dos testes.

Objetivo:

Avaliar a capacidade preditiva dos parâmetros de massa corporal para estimar o exercício de 4-6 repetições máximas (4-6 RM) nos exercícios de Leg press 45°, Chest press e Pull-down efetuados por fisiculturistas.

Métodos:

Onze fisiculturistas masculinos (38,27 ± 10,48 anos) participaram do estudo. Eles completaram a carga externa incremental até encontrar a carga que lhes permitia realizar de 4 a 6 repetições máximas para cada exercício, em ordem aleatória. A carga inicial foi fixada em 50% da massa corporal para os exercícios de Chest press e Pull-down, e 100% para o de Leg press. O incremento de carga após cada rodada foi de 20 kg para o exercício de membros inferiores e 10 kg em membros superiores.

Resultados:

Os resultados revelaram que a massa corporal apresenta relações satisfatórias com 4-6 RM para todos os três exercícios. Os resultados mostraram que a massa corporal possui boa capacidade preditiva em todas as três medidas.

Conclusão:

As equações de previsão sugeridas nesse estudo podem permitir o uso desses exercícios pelos técnicos para medir a performance a 4-6 RM nos exercícios de Leg press 45°, Chest press, e Pull-down. Nível de evidência IV; série de casos.

Descritores:
Modelos de Predição; Força muscular; Peso Corporal

INTRODUCTION

One-repetition maximum (1-RM) is regarded as a popular test commonly used for muscular testing and conditioning¹1 Padulo J, Laffaye G, Chaouachi A, Chamari K. Bench press exercise: The key points. J Sports Med Phys Fitness. 2015;55(6):604-8. since it is considered a valid indicator of maximal dynamic strength,²2 Cormie P, Mcguigan MR, Newton RU. Adaptations in Athletic Performance after Ballistic Power versus Strength Training. Med Sci Sport Exerc. 2010;42(8):1582-98.,³3 Kraemer WJ, Ratamess NA. Fundamentals of Resistance Training: Progression and Exercise Prescription. Med Sci Sport Exerc. 2004;36(4):674-88. defined as the maximal weight that an individual can lift with a single repetition.⁴4 Padulo J, Mignogna P, Mignardi S, Tonni F, D’Ottavio S. Effect of Different Pushing Speeds on Bench Press. Int J Sports Med. 2012;33(5):376-80. Chest press and Pull-down for upper body,⁵5 Palermi S, Bragazzi N, Cular D, Ardigò L. How chest press-based exercises can alleviate the burden of cardiovascular diseases. Hum Mov. 2022;23(4):88-98. and Leg press 45° for lower body,⁶6 Migliaccio GM, Iacono A Dello, Ardigò LP, Samozino P, Iuliano E, Grgantov Z, et al. Leg Press vs. Smith Machine: Quadriceps Activation and Overall Perceived Effort Profiles. Front Physiol. 2018;9.,⁷7 Padulo J, Migliaccio G, Ardigò L, Leban B, Cosso M, Samozino P. Lower Limb Force, Velocity, Power Capabilities during Leg Press and Squat Movements. Int J Sports Med. 2017;38(14):1083-9. are considered the best exercises to assess the muscle strength in a bodybuilders population. In addition, the 1-RM is considered the primary reference for determining baseline measurements and prescribing training loads when constructing resistance training programs for recreational and professional athletes and especially for individuals who intend to undertake resistance training for the first time.³3 Kraemer WJ, Ratamess NA. Fundamentals of Resistance Training: Progression and Exercise Prescription. Med Sci Sport Exerc. 2004;36(4):674-88.,⁸8 Soriano MA, Suchomel TJ, Marín PJ. The Optimal Load for Maximal Power Production During Upper-Body Resistance Exercises: A Meta-Analysis. Sport Med. 2017;47(4):757-68. However, the direct determination of the 1-RM from a single maximal lift has been associated with a number of drawbacks. When performed incorrectly or by novice subjects, it may increase the risk of injury, be time-consuming, and be impractical for large groups.⁹9 Balsalobre-Fernández C, Marchante D, Muñoz-López M, Jiménez SL. Validity and reliability of a novel iPhone app for the measurement of barbell velocity and 1RM on the bench-press exercise. J Sports Sci. 2018;36(1):64-70.,¹⁰10 González-Badillo J, Marques M, Sánchez-Medina L. The Importance of Movement Velocity as a Measure to Control Resistance Training Intensity. J Hum Kinet. 2011;29(A):15-9. Additionally, to obtain an accurate 1-RM, several familiarization and testing sessions for each exercise are needed to establish whether a change occurred due to learning or training.¹¹11 Amarante do Nascimento M, Borges Januário RS, Gerage AM, Mayhew JL, Cheche Pina FL, Cyrino ES. Familiarization and Reliability of One Repetition Maximum Strength Testing in Older Women. J Strength Cond Res. 2013;27(6):1636-42.

Several equations that rely on linear regression modeling are developed to calculate 1-RM indirectly.¹²12 Tillaar R van den, Ball N. Push-Ups are Able to Predict the Bench Press 1-RM and Constitute an Alternative for Measuring Maximum Upper Body Strength Based on Load-Velocity Relationships. J Hum Kinet. 2020;73:7-18.,¹³13 Reynolds JM, Gordon TJ, Robergs RA. Prediction of One Repetition Maximum Strength From Multiple Repetition Maximum Testing and Anthropometry. J Strength Cond Res. 2006;20(3):584-92. These prediction equations are derived from multiple repetition maximum or maximal weight that an individual can lift over a specified number of repetitions.¹⁴14 Baeckle T, Earle R. Essentials of strength training and conditioning. Champaign: Human Kinetics Publishers Inc; 2008. The number of repetitions shouldn't exceed more than ten as prediction equations are more accurate when heavier loads are used.¹³13 Reynolds JM, Gordon TJ, Robergs RA. Prediction of One Repetition Maximum Strength From Multiple Repetition Maximum Testing and Anthropometry. J Strength Cond Res. 2006;20(3):584-92. While multiple repetition maximum involves lifting high relative loads during the fatigued state, 4-6 RM or 7-10 RM submaximal strength assessment appears to be valid for prescribing intensity in strength training protocols¹⁵15 Taylor JD, Fletcher JP. Reliability of the 8-repetition maximum test in men and women. J Sci Med Sport. 2012;15(1):69-73. with no reported symptoms of post-exercise delayed onset of muscle soreness.¹⁶16 Dohoney P, Chromiak JA, Lemire D, Abadie BR, Kovacs C. Prediction of one repetition maximum (1-RM) strength from a 4-6 RM and a7-10 RM submaximal strength test in healthy young adult males. J Exerc Physiol Online. 2002;5(3):54-9.

Recent literature has shown that anthropometric measures can predict 1-RM loads.¹⁷17 García-Ramos A, Haff GG, Pestaña-Melero FL, Pérez-Castilla A, Rojas FJ, Balsalobre-Fernández C, et al. Feasibility of the 2-Point Method for Determining the 1-Repetition Maximum in the Bench Press Exercise. Int J Sports Physiol Perform. 2018;13(4):474-81.–²¹21 Noel MB, VanHeest JL, Zaneteas P, Rodgers CD. Body Composition in Division I Football Players. J Strength Cond Res. 2003;17(2):228-37. The body mass routinely used to predict pectoral machine and leg press, particularly correlated to 1-RM performance.¹⁹19 Keogh J, Hume PA, Pearson SN, Mellow P. Anthropometric dimensions of male powerlifters of varying body mass. J Sports Sci. 2007;25(12):1365-76.,²²22 Caruso JF, Taylor ST, Lutz BM, Olson NM, Mason ML, Borgsmiller JA, et al. Anthropometry as a Predictor of Bench Press Performance Done at Different Loads. J Strength Cond Res. 2012;26(9):2460-7. It is possible that greater accuracy can be achieved by using a submaximal strength test combined with anthropometric measurements to estimate 1-RM. It should be noted that Whisenant et al.²³23 Whisenant MJ, Panton LB, East WB, Broeder CE. Validation of Submaximal Prediction Equations for the 1 Repetition Maximum Bench Press Test on a Group of Collegiate Football Players. J Strength Cond Res. 2003;17(2):221-7. restricted anthropometric measurements to the body height and body mass, which limited their evaluation of the ability of anthropometric measures to reduce prediction error. This seems surprising based on the findings of previous studies showing relatively strong relationships between body mass variables and the expression of strength.¹⁹19 Keogh J, Hume PA, Pearson SN, Mellow P. Anthropometric dimensions of male powerlifters of varying body mass. J Sports Sci. 2007;25(12):1365-76.,²⁰20 Keogh J, Hume P, Mellow P, Pearson S. The use of anthropometric variables to predict bench press and squat strength in well-trained strength athletes. ISBS - Conference Proceedings Archive. 2005:126-9. Coaches and individuals interested in ‘athletes’ body strength evaluation²⁴24 Laffaye G, Collin JM, Levernier G, Padulo J. Upper-limb Power Test in Rock-climbing. Int J Sports Med. 2014;35(8):670-5.,²⁵25 Dhahbi W, Chaouachi A, Padulo J, Behm DG, Chamari K. Five-Meter Rope-Climbing: A Commando-Specific Power Test of the Upper Limbs. Int J Sports Physiol Perform. 2015;10(4):509-15. may benefit from a reasonably accurate conversion of body mass to estimates of %RM strength exercises, especially for bodybuilders. Bodybuilders are a specific population of athletes whose ultimate goal is to achieve a large muscle mass (MM) with low quantities of fat mass (FM).²⁶26 Graybeal AJ, Moore ML, Cruz MR, Tinsley GM. Body Composition Assessment in Male and Female Bodybuilders: A 4-Compartment Model Comparison of Dual-Energy X-Ray Absorptiometry and Impedance-Based Devices. J Strength Cond Res. 2020;34(6):1676-89. Elevated quantities of fat-free mass (FFM) are crucial in physique sports like bodybuilding, and absolute levels of FFM/MM may be the most significant anthropometric determinant of maximal strength.¹⁹19 Keogh J, Hume PA, Pearson SN, Mellow P. Anthropometric dimensions of male powerlifters of varying body mass. J Sports Sci. 2007;25(12):1365-76. Although investigations that deal with anthropometric measurement and strength tests to estimate %RM in different sports exist,¹⁹19 Keogh J, Hume PA, Pearson SN, Mellow P. Anthropometric dimensions of male powerlifters of varying body mass. J Sports Sci. 2007;25(12):1365-76.,²⁰20 Keogh J, Hume P, Mellow P, Pearson S. The use of anthropometric variables to predict bench press and squat strength in well-trained strength athletes. ISBS - Conference Proceedings Archive. 2005:126-9. the efficacy of this approach in bodybuilding is unknown.

Therefore, the purpose of the present study was to examine the predictive ability of body mass to estimate the 4-6 RM in the leg press 45°, chest press, and pull-down exercises. We hypothesized that body mass would explain significant amount of variance in performance for all three exercises at submaximal loads.

MATERIALS AND METHODS

Participants

Eleven senior male bodybuilding voluntarily participated in this study. The participant's body measurements and characteristics are shown in Table 1. All participants had at least ten years of bodybuilding practice, with ∼15 training sessions per week routine. Twenty-four hours before and during the study period, participants were asked to avoid medication, alcohol, drugs, and dietary supplements consumption to reduce any interference in the testing. Participants were also free from any injury or pain that would have prevented maximal effort during testing. They all gave their written informed consent to participate in the study after a thorough explanation of the ‘study's protocol. The protocol conformed to internationally accepted policy statements regarding the use of human participants in accordance with the Declaration of Helsinki and was approved by the ‘Ovidius University's Ethics Committee (292/2021).

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Table 1
‘Participants’ body measurements and characteristics.

Procedures

Body mass was measured using a portable digital scale (Tanita body fat analyzer, model TBF 105) with ± 0.1 kg precision, while body height was measured with an accuracy of one millimeter (Harpenden Portable Stadiometer 603 VR, Holtain LTD, Crosswell, UK). Body mass index (BMI) was calculated using the equation: body weight (kg) / [body height (m)]². To determine 4-6 RM for each exercise, participants were evaluated starting with an initial load of 100% body mass for leg press 45° and 50% body mass for chest press and pull-down exercise. When the participant performed 12 repetitions, each exercise was interrupted, and after 5 min of passive rest, the external load of the exercises was increased. The increased load was 20 kg for leg press exercises and 10 kg for chest press and pull-down exercises. According to the protocol described by Brzycki,²⁷27 Brzycki M. Strength Testing—Predicting a One-Rep Max from Reps-to-Fatigue. J Phys Educ Recreat Danc. 1993;64(1):88-90. the participants concluded the tests when they reached a maximum number of repetitions ranging between 4 and 6 for each exercise. The load with which the participants were able to perform 4 to 6 correct and complete repetitions was considered 4-6 RM and used for further statistical analyses.

The participants were instructed and supervised by the same assessor who had at least ten years of experience in exercise testing during the testing sessions. Furthermore, before each testing session, the participants performed ∼15 min of a warm-up, including circumduction, adduction/abduction, and flexion/extension exercises of the upper and lower limbs with self-selected intensity and dynamic stretching. After the warm-up, the participants rested for ∼5 minutes. The participants were asked to avoid any intense effort (i.e., the rate of perceived exertion was less than <6.5/10) in the 72 hours preceding the study. All sessions were performed in the morning to avoid any circadian variations, starting at around 10 am.

Statistical analysis

Data analyses were performed using SPSS version 23.0 for Windows (SPSS, Inc. Chicago, IL, USA). As all variables followed a Gaussian distribution (Kolmogorov– Smirnov test), results were presented as mean ± standard deviation (SD). The Pearson's product-moment correlation coefficient (r) and the determination coefficient (r²) were used to evaluate the possible correlation between 4-6 RM and body mass for each exercise. For the interpretation of the magnitude of the correlations, the following scale was used:²⁸28 Hopkins W. Measures of Reliability in Sports Medicine and Science. Sport Med. 2000;30(1):1-15. trivial (< 0.1), small (0.1-0.3), moderate (0.3-0.5), high (0.5-0.7), very high (0.7-0.9), or almost perfect (> 0.9). The equations and the standard error of estimate (SEE) to predict the 4-6 RM loads by BM for each exercise were determined using the coefficients obtained by linear regression analyses (LRA). Cohen's f² was also calculated as a quantitative measure of the magnitude of the experimental effect (effect size). The following scale was used for the interpretation of the f²: small (³ 0.02), medium (³ 0.15), and large effect size (³ 0.35). Finally, the 1-RM of the three exercises was estimated using 4-6 RM load and the respective number of repetitions via Brzycki equation:²⁷27 Brzycki M. Strength Testing—Predicting a One-Rep Max from Reps-to-Fatigue. J Phys Educ Recreat Danc. 1993;64(1):88-90. Lifted load ÷ (1.0278 – (0.0278 × number of repetitions).

RESULTS

Leg press

The estimated 4-6-RM for the leg press ranged from 270 to 400 kg (324.55 ± 44.80 kg). The results for the leg press indicated that the correlation between body mass and 4-6 RM (Figure 1A) was almost perfect (r = 0.92; r² = 84.1%; f²= 5.3).

Figure 1
Correlation between body mass (BM) and 4-6 RM on Leg Press (A), Chest Press (B), and Pull-down (C).

Using the intercept and slope values of the LRA, it was possible to compute the following equation:

\begin{matrix} 4 - 6 RM (kg) for Leg press = 5.08 \times body mass (kg) - 82.41 \\ SEE = 18.81 kg \end{matrix}

The estimated 1-RM for the leg press ranged from 295 to 450 kg (364.55 ± 52.56 kg).

Chest press

The 4-6 RM for the chest press exercise ranged from 90 to 150 kg (114.55 ± 16.35 kg). The results indicated that the correlation between body mass and 4-6 RM (Figure 1B) was very high (r = 0.72; r² = 51.2%; f²= 1.05).

Using the intercept and slope values of the LRA, it was possible to compute the following equation:

\begin{matrix} 4 - 6 RM (kg) for Chest press = 1.45 \times body mass (kg) - 1.32 \\ SEE = 12.03 kg \end{matrix}

The estimated 1-RM for the chest press ranged from 98 to 164 kg (125.82 ± 17.92 kg).

Pull-down

The 4-6 RM for the pull-down ranged from 110 to 150 kg (127.73±14.21 kg). The results indicated that the correlation between body mass and 4-6 RM (Figure 1C) was very high (r = 0.89; r² = 78.4%; f²= 3.63).

Using the intercept and slope values of the LRA, it was possible to compute the following equation:

\begin{matrix} 4 - 6 RM (kg) for Pull-down = 1.56 \times body mass (kg) + 3.17 \\ SEE = 6.96 kg \end{matrix}

The estimated 1-RM for the pull-down ranged from 123 to 169 kg (141.31 ± 15.38 kg).

The scatter plot of the correlation between body mass and 4-6 RM for each exercise is presented in Figure 1. Body mass had very hight to almost perfect correlations with 4-6 RM load in all three exercises (leg-press 45°: r = 0.92, chest-press: r = 0.72, pull down: r = 0.89) exercises.

DISCUSSION

This study was designed to explore the feasibility of individualized body mass parameters for determining the 4-6 RM in the leg-press 45°, chest press, and pull-down exercises. Results revealed that body mass had significant correlations with 4-6 RM (range from “very high” to “almost perfect”). Moreover, body mass was a good predictor to estimate 4-6 RM in all three exercises.

Other studies found similar relationships between body mass and bench press 1-RM loads in male powerlifters (r = 0.49).¹⁹19 Keogh J, Hume PA, Pearson SN, Mellow P. Anthropometric dimensions of male powerlifters of varying body mass. J Sports Sci. 2007;25(12):1365-76. Authors conclude that muscle thickness and body mass are the best predictors of strength in upper and lower limbs.¹⁹19 Keogh J, Hume PA, Pearson SN, Mellow P. Anthropometric dimensions of male powerlifters of varying body mass. J Sports Sci. 2007;25(12):1365-76.,²⁰20 Keogh J, Hume P, Mellow P, Pearson S. The use of anthropometric variables to predict bench press and squat strength in well-trained strength athletes. ISBS - Conference Proceedings Archive. 2005:126-9. Moreover, similar correlations between body mass and bench press 1-RM load were obtained in college football players (r ranged from 0.53 to 0.61).²⁹29 Mayhew JL, Piper FC, Ware JS. Anthropometric correlates with strength performance among resistance trained athletes. J Sports Med Phys Fitness. 1993;33(2):159-65.,³⁰30 Mayhew JL, Jacques JA, Ware JS, Chapman PP, Bemben MG, Ward TE, et al. Anthropometric dimensions do not enhance one repetition maximum prediction from the NFL-225 test in college football players. J Strength Cond Res. 2004;18(3):572-8. Thus, our results are in line with previous investigations indicating that male athletes routinely demonstrate upper and lower strength, namely that body mass acts as a strong correlate to this criterion. However, it is important to note that, unlike body mass and 1-RM% relationships in the current and previous studies,¹⁹19 Keogh J, Hume PA, Pearson SN, Mellow P. Anthropometric dimensions of male powerlifters of varying body mass. J Sports Sci. 2007;25(12):1365-76.,²⁰20 Keogh J, Hume P, Mellow P, Pearson S. The use of anthropometric variables to predict bench press and squat strength in well-trained strength athletes. ISBS - Conference Proceedings Archive. 2005:126-9.,²⁹29 Mayhew JL, Piper FC, Ware JS. Anthropometric correlates with strength performance among resistance trained athletes. J Sports Med Phys Fitness. 1993;33(2):159-65. recent findings showed body mass inclusion as an additional independent variable could improve the prediction capacity of multivariate analyses.²⁰20 Keogh J, Hume P, Mellow P, Pearson S. The use of anthropometric variables to predict bench press and squat strength in well-trained strength athletes. ISBS - Conference Proceedings Archive. 2005:126-9.,²²22 Caruso JF, Taylor ST, Lutz BM, Olson NM, Mason ML, Borgsmiller JA, et al. Anthropometry as a Predictor of Bench Press Performance Done at Different Loads. J Strength Cond Res. 2012;26(9):2460-7.,²⁹29 Mayhew JL, Piper FC, Ware JS. Anthropometric correlates with strength performance among resistance trained athletes. J Sports Med Phys Fitness. 1993;33(2):159-65. Thus, the inclusion of body mass as a predictor variable is an excellent way to explain the criterion variance because initial determination for submaximal exercises performance (i.e., 4-6 RM) and body mass were good (r²= 51 - 84%).²⁰20 Keogh J, Hume P, Mellow P, Pearson S. The use of anthropometric variables to predict bench press and squat strength in well-trained strength athletes. ISBS - Conference Proceedings Archive. 2005:126-9.,²²22 Caruso JF, Taylor ST, Lutz BM, Olson NM, Mason ML, Borgsmiller JA, et al. Anthropometry as a Predictor of Bench Press Performance Done at Different Loads. J Strength Cond Res. 2012;26(9):2460-7.,²⁹29 Mayhew JL, Piper FC, Ware JS. Anthropometric correlates with strength performance among resistance trained athletes. J Sports Med Phys Fitness. 1993;33(2):159-65.

Previous studies showed that body composition could increase the amount of explained 4-6 RM variance.¹⁹19 Keogh J, Hume PA, Pearson SN, Mellow P. Anthropometric dimensions of male powerlifters of varying body mass. J Sports Sci. 2007;25(12):1365-76.,²²22 Caruso JF, Taylor ST, Lutz BM, Olson NM, Mason ML, Borgsmiller JA, et al. Anthropometry as a Predictor of Bench Press Performance Done at Different Loads. J Strength Cond Res. 2012;26(9):2460-7. For instance, to improve performance, American football athletes in certain playing positions slowly raise their body weight in order to yield higher relative gains in fat mass than fat free mass.²¹21 Noel MB, VanHeest JL, Zaneteas P, Rodgers CD. Body Composition in Division I Football Players. J Strength Cond Res. 2003;17(2):228-37.,³⁰30 Mayhew JL, Jacques JA, Ware JS, Chapman PP, Bemben MG, Ward TE, et al. Anthropometric dimensions do not enhance one repetition maximum prediction from the NFL-225 test in college football players. J Strength Cond Res. 2004;18(3):572-8. Such practices skew body mass 1-RM relationships, as athletes become heavier but not necessarily stronger.³⁰30 Mayhew JL, Jacques JA, Ware JS, Chapman PP, Bemben MG, Ward TE, et al. Anthropometric dimensions do not enhance one repetition maximum prediction from the NFL-225 test in college football players. J Strength Cond Res. 2004;18(3):572-8. This, in part, accounts for the inability of body mass to increase the amount of explained variance.³⁰30 Mayhew JL, Jacques JA, Ware JS, Chapman PP, Bemben MG, Ward TE, et al. Anthropometric dimensions do not enhance one repetition maximum prediction from the NFL-225 test in college football players. J Strength Cond Res. 2004;18(3):572-8. Mayhew et al.,²³23 Whisenant MJ, Panton LB, East WB, Broeder CE. Validation of Submaximal Prediction Equations for the 1 Repetition Maximum Bench Press Test on a Group of Collegiate Football Players. J Strength Cond Res. 2003;17(2):221-7. whose sample was comprised solely of American football players, found out that the poorest relative bench press efforts came from individuals with the higher body mass and fat percentage. High muscle mass (MM) and low fat mass (FM) is even more pronounced in bodybuilders, and indeed assertion of MM improves 1-RM loads. Previous studies confirm a poor relationship between body mass and 1-RM when individuals with high FM are included in testing protocols.¹⁹19 Keogh J, Hume PA, Pearson SN, Mellow P. Anthropometric dimensions of male powerlifters of varying body mass. J Sports Sci. 2007;25(12):1365-76.,²⁰20 Keogh J, Hume P, Mellow P, Pearson S. The use of anthropometric variables to predict bench press and squat strength in well-trained strength athletes. ISBS - Conference Proceedings Archive. 2005:126-9.,³⁰30 Mayhew JL, Jacques JA, Ware JS, Chapman PP, Bemben MG, Ward TE, et al. Anthropometric dimensions do not enhance one repetition maximum prediction from the NFL-225 test in college football players. J Strength Cond Res. 2004;18(3):572-8.

CONCLUSION

The prediction equations suggested in this study may allow coaches to use these exercises to measure the 4-6 RM performances, corrected by the following linear regression equation specific for each modality of exercises:

Leg-press 45° 4-6 RM (kg) = 5.08 × body mass - 82.41
Chest press 4-6 RM (kg) = 1.45 × body mass - 1.32
Pull down 4-6 RM (kg) = 1.56 × body mass + 3.17

Knowing the maximum capabilities of athletes is essential to develop and implement a good training process, which is both safe and effective. Future investigations should focus on expanding the range of tested exercises in a different population of athletes and non-athletes. Identifying anthropometric variables that have excellent ability to estimate multiple repetition maximum should be helpful in creating strength and conditioning programs.

REFERENCES

¹
Padulo J, Laffaye G, Chaouachi A, Chamari K. Bench press exercise: The key points. J Sports Med Phys Fitness. 2015;55(6):604-8.
²
Cormie P, Mcguigan MR, Newton RU. Adaptations in Athletic Performance after Ballistic Power versus Strength Training. Med Sci Sport Exerc. 2010;42(8):1582-98.
³
Kraemer WJ, Ratamess NA. Fundamentals of Resistance Training: Progression and Exercise Prescription. Med Sci Sport Exerc. 2004;36(4):674-88.
⁴
Padulo J, Mignogna P, Mignardi S, Tonni F, D’Ottavio S. Effect of Different Pushing Speeds on Bench Press. Int J Sports Med. 2012;33(5):376-80.
⁵
Palermi S, Bragazzi N, Cular D, Ardigò L. How chest press-based exercises can alleviate the burden of cardiovascular diseases. Hum Mov. 2022;23(4):88-98.
⁶
Migliaccio GM, Iacono A Dello, Ardigò LP, Samozino P, Iuliano E, Grgantov Z, et al. Leg Press vs. Smith Machine: Quadriceps Activation and Overall Perceived Effort Profiles. Front Physiol. 2018;9.
⁷
Padulo J, Migliaccio G, Ardigò L, Leban B, Cosso M, Samozino P. Lower Limb Force, Velocity, Power Capabilities during Leg Press and Squat Movements. Int J Sports Med. 2017;38(14):1083-9.
⁸
Soriano MA, Suchomel TJ, Marín PJ. The Optimal Load for Maximal Power Production During Upper-Body Resistance Exercises: A Meta-Analysis. Sport Med. 2017;47(4):757-68.
⁹
Balsalobre-Fernández C, Marchante D, Muñoz-López M, Jiménez SL. Validity and reliability of a novel iPhone app for the measurement of barbell velocity and 1RM on the bench-press exercise. J Sports Sci. 2018;36(1):64-70.
¹⁰
González-Badillo J, Marques M, Sánchez-Medina L. The Importance of Movement Velocity as a Measure to Control Resistance Training Intensity. J Hum Kinet. 2011;29(A):15-9.
¹¹
Amarante do Nascimento M, Borges Januário RS, Gerage AM, Mayhew JL, Cheche Pina FL, Cyrino ES. Familiarization and Reliability of One Repetition Maximum Strength Testing in Older Women. J Strength Cond Res. 2013;27(6):1636-42.
¹²
Tillaar R van den, Ball N. Push-Ups are Able to Predict the Bench Press 1-RM and Constitute an Alternative for Measuring Maximum Upper Body Strength Based on Load-Velocity Relationships. J Hum Kinet. 2020;73:7-18.
¹³
Reynolds JM, Gordon TJ, Robergs RA. Prediction of One Repetition Maximum Strength From Multiple Repetition Maximum Testing and Anthropometry. J Strength Cond Res. 2006;20(3):584-92.
¹⁴
Baeckle T, Earle R. Essentials of strength training and conditioning. Champaign: Human Kinetics Publishers Inc; 2008.
¹⁵
Taylor JD, Fletcher JP. Reliability of the 8-repetition maximum test in men and women. J Sci Med Sport. 2012;15(1):69-73.
¹⁶
Dohoney P, Chromiak JA, Lemire D, Abadie BR, Kovacs C. Prediction of one repetition maximum (1-RM) strength from a 4-6 RM and a7-10 RM submaximal strength test in healthy young adult males. J Exerc Physiol Online. 2002;5(3):54-9.
¹⁷
García-Ramos A, Haff GG, Pestaña-Melero FL, Pérez-Castilla A, Rojas FJ, Balsalobre-Fernández C, et al. Feasibility of the 2-Point Method for Determining the 1-Repetition Maximum in the Bench Press Exercise. Int J Sports Physiol Perform. 2018;13(4):474-81.
¹⁸
García-Ramos A, Torrejón A, Feriche B, Morales-Artacho AJ, Pérez-Castilla A, Padial P, et al. Prediction of the Maximum Number of Repetitions and Repetitions in Reserve From Barbell Velocity. Int J Sports Physiol Perform. 2018;13(3):353-9.
¹⁹
Keogh J, Hume PA, Pearson SN, Mellow P. Anthropometric dimensions of male powerlifters of varying body mass. J Sports Sci. 2007;25(12):1365-76.
²⁰
Keogh J, Hume P, Mellow P, Pearson S. The use of anthropometric variables to predict bench press and squat strength in well-trained strength athletes. ISBS - Conference Proceedings Archive. 2005:126-9.
²¹
Noel MB, VanHeest JL, Zaneteas P, Rodgers CD. Body Composition in Division I Football Players. J Strength Cond Res. 2003;17(2):228-37.
²²
Caruso JF, Taylor ST, Lutz BM, Olson NM, Mason ML, Borgsmiller JA, et al. Anthropometry as a Predictor of Bench Press Performance Done at Different Loads. J Strength Cond Res. 2012;26(9):2460-7.
²³
Whisenant MJ, Panton LB, East WB, Broeder CE. Validation of Submaximal Prediction Equations for the 1 Repetition Maximum Bench Press Test on a Group of Collegiate Football Players. J Strength Cond Res. 2003;17(2):221-7.
²⁴
Laffaye G, Collin JM, Levernier G, Padulo J. Upper-limb Power Test in Rock-climbing. Int J Sports Med. 2014;35(8):670-5.
²⁵
Dhahbi W, Chaouachi A, Padulo J, Behm DG, Chamari K. Five-Meter Rope-Climbing: A Commando-Specific Power Test of the Upper Limbs. Int J Sports Physiol Perform. 2015;10(4):509-15.
²⁶
Graybeal AJ, Moore ML, Cruz MR, Tinsley GM. Body Composition Assessment in Male and Female Bodybuilders: A 4-Compartment Model Comparison of Dual-Energy X-Ray Absorptiometry and Impedance-Based Devices. J Strength Cond Res. 2020;34(6):1676-89.
²⁷
Brzycki M. Strength Testing—Predicting a One-Rep Max from Reps-to-Fatigue. J Phys Educ Recreat Danc. 1993;64(1):88-90.
²⁸
Hopkins W. Measures of Reliability in Sports Medicine and Science. Sport Med. 2000;30(1):1-15.
²⁹
Mayhew JL, Piper FC, Ware JS. Anthropometric correlates with strength performance among resistance trained athletes. J Sports Med Phys Fitness. 1993;33(2):159-65.
³⁰
Mayhew JL, Jacques JA, Ware JS, Chapman PP, Bemben MG, Ward TE, et al. Anthropometric dimensions do not enhance one repetition maximum prediction from the NFL-225 test in college football players. J Strength Cond Res. 2004;18(3):572-8.

Edited by

Associate Editor responsible for the review process: Júlia Maria

Publication Dates

Publication in this collection
16 June 2023
Date of issue
2024

History

Received
29 Nov 2021
Accepted
15 Aug 2022

This is an Open Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

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Padulo J, Migliaccio G, Ardigò L, Leban B, Cosso M, Samozino P. Lower Limb Force, Velocity, Power Capabilities during Leg Press and Squat Movements. Int J Sports Med. 2017;38(14):1083-9.

[8] ⁸
Soriano MA, Suchomel TJ, Marín PJ. The Optimal Load for Maximal Power Production During Upper-Body Resistance Exercises: A Meta-Analysis. Sport Med. 2017;47(4):757-68.

[9] ⁹
Balsalobre-Fernández C, Marchante D, Muñoz-López M, Jiménez SL. Validity and reliability of a novel iPhone app for the measurement of barbell velocity and 1RM on the bench-press exercise. J Sports Sci. 2018;36(1):64-70.

[10] ¹⁰
González-Badillo J, Marques M, Sánchez-Medina L. The Importance of Movement Velocity as a Measure to Control Resistance Training Intensity. J Hum Kinet. 2011;29(A):15-9.

[11] ¹¹
Amarante do Nascimento M, Borges Januário RS, Gerage AM, Mayhew JL, Cheche Pina FL, Cyrino ES. Familiarization and Reliability of One Repetition Maximum Strength Testing in Older Women. J Strength Cond Res. 2013;27(6):1636-42.

[12] ¹²
Tillaar R van den, Ball N. Push-Ups are Able to Predict the Bench Press 1-RM and Constitute an Alternative for Measuring Maximum Upper Body Strength Based on Load-Velocity Relationships. J Hum Kinet. 2020;73:7-18.

[13] ¹³
Reynolds JM, Gordon TJ, Robergs RA. Prediction of One Repetition Maximum Strength From Multiple Repetition Maximum Testing and Anthropometry. J Strength Cond Res. 2006;20(3):584-92.

[14] ¹⁴
Baeckle T, Earle R. Essentials of strength training and conditioning. Champaign: Human Kinetics Publishers Inc; 2008.

[15] ¹⁵
Taylor JD, Fletcher JP. Reliability of the 8-repetition maximum test in men and women. J Sci Med Sport. 2012;15(1):69-73.

[16] ¹⁶
Dohoney P, Chromiak JA, Lemire D, Abadie BR, Kovacs C. Prediction of one repetition maximum (1-RM) strength from a 4-6 RM and a7-10 RM submaximal strength test in healthy young adult males. J Exerc Physiol Online. 2002;5(3):54-9.

[17] ¹⁷
García-Ramos A, Haff GG, Pestaña-Melero FL, Pérez-Castilla A, Rojas FJ, Balsalobre-Fernández C, et al. Feasibility of the 2-Point Method for Determining the 1-Repetition Maximum in the Bench Press Exercise. Int J Sports Physiol Perform. 2018;13(4):474-81.

[18] ¹⁸
García-Ramos A, Torrejón A, Feriche B, Morales-Artacho AJ, Pérez-Castilla A, Padial P, et al. Prediction of the Maximum Number of Repetitions and Repetitions in Reserve From Barbell Velocity. Int J Sports Physiol Perform. 2018;13(3):353-9.

[19] ¹⁹
Keogh J, Hume PA, Pearson SN, Mellow P. Anthropometric dimensions of male powerlifters of varying body mass. J Sports Sci. 2007;25(12):1365-76.

[20] ²⁰
Keogh J, Hume P, Mellow P, Pearson S. The use of anthropometric variables to predict bench press and squat strength in well-trained strength athletes. ISBS - Conference Proceedings Archive. 2005:126-9.

[21] ²¹
Noel MB, VanHeest JL, Zaneteas P, Rodgers CD. Body Composition in Division I Football Players. J Strength Cond Res. 2003;17(2):228-37.

[22] ²²
Caruso JF, Taylor ST, Lutz BM, Olson NM, Mason ML, Borgsmiller JA, et al. Anthropometry as a Predictor of Bench Press Performance Done at Different Loads. J Strength Cond Res. 2012;26(9):2460-7.

[23] ²³
Whisenant MJ, Panton LB, East WB, Broeder CE. Validation of Submaximal Prediction Equations for the 1 Repetition Maximum Bench Press Test on a Group of Collegiate Football Players. J Strength Cond Res. 2003;17(2):221-7.

[24] ²⁴
Laffaye G, Collin JM, Levernier G, Padulo J. Upper-limb Power Test in Rock-climbing. Int J Sports Med. 2014;35(8):670-5.

[25] ²⁵
Dhahbi W, Chaouachi A, Padulo J, Behm DG, Chamari K. Five-Meter Rope-Climbing: A Commando-Specific Power Test of the Upper Limbs. Int J Sports Physiol Perform. 2015;10(4):509-15.

[26] ²⁶
Graybeal AJ, Moore ML, Cruz MR, Tinsley GM. Body Composition Assessment in Male and Female Bodybuilders: A 4-Compartment Model Comparison of Dual-Energy X-Ray Absorptiometry and Impedance-Based Devices. J Strength Cond Res. 2020;34(6):1676-89.

[27] ²⁷
Brzycki M. Strength Testing—Predicting a One-Rep Max from Reps-to-Fatigue. J Phys Educ Recreat Danc. 1993;64(1):88-90.

[28] ²⁸
Hopkins W. Measures of Reliability in Sports Medicine and Science. Sport Med. 2000;30(1):1-15.

[29] ²⁹
Mayhew JL, Piper FC, Ware JS. Anthropometric correlates with strength performance among resistance trained athletes. J Sports Med Phys Fitness. 1993;33(2):159-65.

[30] ³⁰
Mayhew JL, Jacques JA, Ware JS, Chapman PP, Bemben MG, Ward TE, et al. Anthropometric dimensions do not enhance one repetition maximum prediction from the NFL-225 test in college football players. J Strength Cond Res. 2004;18(3):572-8.

Sample size (n =11)	Mean±SD
Age (years)	38.27±10.48
Body mass (kg)	80.05±8.08
Height (m)	1.76±0.08
BMI (kg/m²)	25.71±0.64
Training experience (years)	16.55±8.18

Brasil

Brasil

BODY MASS TO PREDICT 4-6 RM OF PECTORAL AND LEG MUSCLES EXERCISES IN BODYBUILDERS

PREDICCIÓN DE 4-6 RM DE EJERCICIOS DE PIERNAS Y PECTORALES POR MASA CORPORAL

ABSTRACT

Introduction:

Objective:

Methods:

Results:

Conclusion:

RESUMEN

Introducción:

Objetivo:

Métodos:

Resultados:

Conclusión:

RESUMO

Introdução:

Objetivo:

Métodos:

Resultados:

Conclusão:

INTRODUCTION

MATERIALS AND METHODS

Participants

Procedures

Statistical analysis

RESULTS

Leg press

Chest press

Pull-down

DISCUSSION

CONCLUSION

REFERENCES

Edited by

Publication Dates

History