Abstract
Several studies comparing resistance training (RT) frequencies may have been affected by the large between-subject variability. This study aimed to compare the changes in lower limbs maximal dynamic strength (1RM) and quadriceps femoris cross-sectional area (CSA) after a RT with different weekly frequencies in strength-trained individuals using a within-subject design. Twenty-four men participated in a 9-week RT program, being randomly divided into two conditions: resistance training with equalized total training volume (RTEV) and with unequalized total training volume (RTUV). The RT protocol used the unilateral leg press 45° exercise and each subject’s lower limb executed one of the proposed frequencies (one and three times/week). All conditions effectively increased 1RM and CSA (p<0.001); however, no significant differences were observed in the values of 1RM (p = 0.454) and CSA (p = 0.310) between the RT frequencies in the RTEV and RTUV conditions. Therefore, RT performed three times a week showed similar increases in 1RM and CSA to the program performed once a week, regardless of training volume equalization. Nevertheless, when the higher RT frequency allowed the application of a greater TTV (i.e., RTUV), higher effect size (ES) values (0.51 and 0.63, 1RM and CSA, respectively) were observed for the adaptations.
Introduction
The main adaptations induced by resistance training (RT) are increased strength and skeletal muscle cross-sectional area (i.e., muscle hypertrophy). The magnitude of these adaptations can be modulated through the adequate manipulation of some training variables such as intensity, volume, rest interval, and frequency [1, 2]. Among these, training frequency may be defined as the number of weekly sessions [3, 4]. In RT, frequency is usually expressed by the number of times certain muscle groups are exercised in a given period [5], which in turn is influenced by factors such as training intensity and volume, number of muscle groups trained per session, and practitioner training status [6].
Important guidelines on RT prescription [4, 7] based their training frequency recommendations mostly on studies with untrained individuals, hindering the application of their results to individuals with a higher training status. Moreover, in some of these studies, total training volume (TTV, total amount of weight lifted) was not always equalized for comparison of the effects of different RT frequencies, increasing the risk of mistaken conclusions, since TTV can be determinant for increases in muscle strength [8] and mass [9–11].
It should be mentioned that a high TTV in one training session may result in an increased rate of perceived exertion (RPE) [12, 13], greater fatigue accumulation, and slower rate of neuromuscular recovery [14]. On the other hand, increasing RT frequency facilitates TTV distribution over a larger number of sessions, providing favorable conditions for neuromuscular adaptations [15, 16]. Thus, an increase in RT frequency might be an effective strategy to stimulate the neuromuscular system and, consequently, increase strength performance [12, 17, 18].
Regarding muscle hypertrophy, the importance of a higher RT frequency may be related to the maintenance of elevated rates of post-training muscle protein synthesis (MPS). Trained individuals appear to have a shorter period of MPS compared to untrained individuals [19, 20]. Considering that muscle hypertrophy may be affected by accumulated periods of increased post-exercise MPS [21], keeping a higher RT frequency would be an effective strategy to contribute to such adaptation [20, 22]. Furthermore, TTV can be increased with a higher RT frequency [9], and this increase might be related to ribosomal biogenesis [23], satellite cell activation and proliferation, and myonuclear addition which in turn could influence MPS in long term training conditions [24].
Recent reviews and meta-analyzes [2, 25–27] suggest that there is no significant effect of training frequency on either strength performance or muscle hypertrophy when TTV is equalized. However, the results of several studies in these meta-analyzes may have been affected by the large inter-subject variability when different RT frequencies are compared [28]. The comparison of different RT frequencies with between-subject experimental designs and training volume equalization by number of sets and repetitions may not be the most appropriate approach to this problem [29]. Thus, within-subject experimental design should be prioritized [23] if the aim is to evaluate training frequencies with equalized and unequalized TTV. To the best of our knowledge this is the first study, with trained individuals, comparing the effects of RT frequency applying a within-subject experimental design.
Thus, the present study aimed to compare the effects of different weekly RT frequencies (i.e., one and three times), on maximal strength performance and muscle hypertrophy in trained individuals, using a within- and between- subject experimental designs in two conditions: resistance training with equalized total training volume (RTEV) and with unequalized total training volume (RTUV). This approach tried to reduce the variability existing in the between-subject designs. We hypothesized that the higher RT frequency would result in larger responses in the dependent variables for both conditions, but in the RTUV condition, they would have a greater effect in consequence of a higher TTV over the training period.
Methods
Experimental design
The present study followed a longitudinal within and between-subject experimental designs, which investigated the effect of different weekly RT frequencies (i.e., one and three times) on maximal dynamic strength (1RM) and quadriceps muscle cross-sectional area (CSA) in trained individuals. The participants were classified based on their baseline values of each dependent variable, and counterbalanced divided into two conditions: RTEV—resistance training with equalized TTV (i.e., training volume in the lower limb trained three times being limited by the training volume of the lower limb trained only once) and RTUV—resistance training with unequalized TTV (i.e., training volume in the lower limb trained three times not being limited by the training volume of the lower limb trained only once). All participants performed the unilateral leg press 45° as the RT exercise with each lower limbs submitted to one of the weekly frequencies. The RTEV and RTUV conditions allowed us to investigate the responses of different RT frequencies in a within-subject experimental design (i.e., RTEV 1x vs. RTEV 3x and RTUV 1x vs. RTUV 3x) (See Table 1).
Table 1. Distribution of subjects’ lower limbs among conditions.
| Conditions | Distribution | ||||
|---|---|---|---|---|---|
| RTEV (24 lower limbs) | (n = 12 lower limbs) - 1x/week | ||||
| (n = 12 lower limbs) - 3x/week | |||||
| RTUV (24 lower limbs) | (n = 12 lower limbs) - 1x/week | ||||
| (n = 12 lower limbs) - 3x/week | |||||
RTEV, resistance training with equalized total training volume; RTUV, resistance training with unequalized total training volume. Note: In both conditions, the lower limbs were distributed in a balanced way in the different frequencies (i.e., right lower limbs 1x/week n = 6; left lower limbs 3x/week n = 6; right lower limbs 3x/week n = 6; left lower limbs 1x/week n = 6).
Four weeks before the beginning of the training period, two half-squat 1RM testing sessions were performed (Smith Machine, Hammer Strength®, Rosemont, IL, USA) 72-hours apart. To ensure reproducibility of the test, steps of varying heights (5, 10, and 15 cm) and tapes on the floor were used to determine range of motion (~90° of knee flexion) and feet positioning, respectively. This test was used only to select subjects based on their relative maximum dynamic strength. In the following week, familiarization sessions with the 1RM test in the unilateral leg press 45° were carried on. A minimum of two and a maximum of four sessions (48 hours apart) were necessary to find a reproducible result (variation ≤ 5%) in this test. In the week preceding the beginning of the RT period, all subjects that met the selection criteria performed two evaluation sessions to measure the unilateral leg press 45° 1RM and quadriceps femoris CSA. The same measurements were done one week after the end of the RT program. All participants were instructed not to start any other RT activity for the lower limbs, to maintain their eating habits, and not to use dietary supplements of any category.
Participants
Twenty-four male participants (26.0 ± 4.0 years; 85.8 ± 15.0 kg and 177.4 ± 6.6 cm), experienced in RT (6.2 ± 4.2 years) were selected for the study. According to the inclusion criteria, all subjects presented a relative maximum dynamic strength (i.e., 1RM/body mass) in the half-squat exercise ≥ 1.5 (2.1 ± 0.4 kg.kg-1). They were free from musculoeskeletal injuries and any other health problems that could prevent them from participating in the study or could affect the results. All participants voluntarily signed, before participation, an informed consent form containing information about the experimental procedures, possible risks and benefits involved. The research project was approved by the by the School of Physical Education and Sport, University of São Paulo Research Ethics Committee (Of.CEP/0317/EEFE/09032017).
Maximum dynamic strength test (1RM)
The 1RM tests procedures followed the guidelines of the American Society of Exercise Physiology [30]. Participants performed a general warm-up on a treadmill (E750; Movement®, Pompeia, SP, Brazil) running at 9 km/h for five minutes. Then, they performed a specific warm-up with the unilateral leg press 45°, consisting of a set of eight repetitions with an estimated 50% 1RM followed by a set of three repetitions with an estimated 70% 1RM, two minutes apart. The 1RM test started three minutes after the end of the specific warm up. The first leg to be tested was randomly selected, independent of limb dominance. The test measured the maximum amount of weight that could be lifted in a complete movement cycle, which began and ended with the knees in full extension, whereas reaching 90° flexion in the descendent phase of the movement.
The individual adjustments in the leg press 45° equipment (Bolt; Movement®, Pompeia, SP, Brasil) were determined in the first familiarization session. The backrest height was adjusted to individual preference. The foot was comfortably positioned in the middle third of the equipment platform. A goniometer (Shopfisio®, Mogi Guaçu, SP, Brazil) was used to determine the 90° knee range of motion which was marked on the left lateral column of the equipment with the aid of a measuring tape. In order to ensure reproducibility of subsequent tests, all adjustments were recorded in the participants’ assessment sheets. The 1RM value was determined with a maximum of five attempts with three minutes of rest between them.
Muscle cross-sectional area measurement (CSA)
Quadriceps femoris CSA was obtained by magnetic resonance imaging (Signa LX 9.1; GE Healthcare®, Milwaukee, WI, USA), performed on both lower limbs with the participants positioned supine with their knees extended. An inelastic band was placed on the participants’ feet to contain hip external rotation movement during the measurement. Initially a reference image of the perpendicular distance between the greater trochanter and the lower edge of the lateral epicondyle of the femur was obtained, which was defined as the segment length. Muscle CSA was measured at 50% of the segment length with 0.8 cm scan slice thickness of 3 s duration. The pulse sequence was performed with a field of view between 400 and 420 mm, repetition time of 350 ms, echo time of 9 to 11 ms, two signal acquisitions, and a 256 x 256 mm reconstruction matrix. The CSA was determined using computerized planimetry (Advantage Workstation 4.3; GE Healthcare®, Milwaukee, WI, USA). The image was divided into skeletal muscle, bone and subcutaneous adipose tissue. Next, quadriceps femoris CSA was determined by subtracting bone and subcutaneous adipose tissue area. Images were plotted (OsiriX Lite; Pixmeo Sarl®, Bernex, GE, Switzerland) in duplicate by a specialized blinded researcher, and the mean value between two measurements was used for further analysis.
Resistance training protocols
The unilateral leg press 45° was the exercise performed during the 9-week RT program. Each participants’ lower limb was submitted to one of the proposed weekly training frequencies (i.e., one and three times). The participants were divided under two experimental conditions: RTEV—resistance training with equalized TTV and, RTUV—resistance training with unequalized TTV (Table 1).
Nine exercise sets were performed weekly at both RT frequencies throughout the experimental period, with the number of maximum repetitions changing every three weeks (i.e., linear periodization model): weeks 1–3 = 12RM; weeks 4–6 = 10RM, and weeks 7–9 = 8RM. All training sessions started with a general warm-up in a treadmill (E720; Movement®, Pompeia, SP, Brazil) running at 9 km/h for five minutes. Next, a specific warm-up composed by 15 repetitions in the unilateral leg press 45° exercise at submaximal intensity (~50%1RM) was done. In the first training session of a week, the lower limb intended for lower RT frequency (once/week) began training by performing nine total sets. Next, the lower limb intended for the higher RT frequency (three times/week) performed only three sets. The other six sets were distributed in the next two RT sessions, separated by a 48-hour interval. In the RTEV condition, repetitions in the higher RT frequency were performed with the average weight (i.e., TTV/number of repetitions performed) obtained with the lower RT frequency of the contralateral lower limb. A fractional number was often obtained but weight adjustments in sets guaranteed the same TTV for 1x and 3x/week. As an example, the lower limb that trained 1x/week performed a total of 108 repetitions over nine sets, resulting in a TTV of 14,220 kg with an average weight of 131.7 kg/repetition. Therefore, the contralateral lower limb trained with the same TTV executing three sets with 131 kg in day one, and three sets with 132 kg in day two and three with the same number of total repetitions.
Statistical analysis
Initially the data were analyzed qualitatively and visually for their normal distribution by the Shapiro-Wilk test and the homogeneity of the variances was confirmed by the Levene test. A one-way ANOVA was used to test for initial differences in unilateral leg press 45° 1RM and quadriceps femoris CSA between experimental conditions. To evaluate the effect of different weekly RT frequencies on the 1RM and CSA values, a mixed model for repeated measures was used with frequencies (one and three times) and time (pre- and post-training) as fixed factors, and subjects as random factors (SAS 9.3; SAS Institute Inc.®, Cary, NC, USA). Data were reported as mean and standard deviation, with significance level adopted of p≤0.05.
The standard error of measurement (SEM) between two 1RM testing sessions before the training period (i.e., last familiarization session and pre-training period assessment) and the minimum difference (MD) were calculated based on Weir [31]. Absolute increases above the MD to be considered were reported at the different weekly RT frequencies under the RTEV and RTUV conditions. For CSA the SEM between two different measurements of the same image was used for calculating the within-researcher reproducibility.
Finally, the effect size (ES) was used to determine the magnitude of the changes, bringing a more practical approach to the obtained results [32, 33]. The ES and confidence interval (CI) were calculated from the mean and standard deviation of Δ at 1RM and CSA values, according to the equation 3 found in Nakagawa and Cuthill [33]. Comparisons were made between the different weekly RT frequencies in the conditions RTEV and RTUV. The ES was classified as insignificant (<0.19), small (0.20–0.49), medium (0.50–0.79) and large (0.80–1.29) [34]. The upper and lower CI limits that did not cross zero were considered significant.
Results
Unilateral leg press 45° 1RM and quadriceps femoris CSA baseline values showed no significant differences between RTEV and RTUV conditions (1RM: F = 0.95536 p = 0.422; CSA: F = 0.01339 p = 0.998) (Table 2).
Table 2. Unilateral leg press 45° 1RM and quadriceps femoris CSA values for RTEV and RTUV conditions.
| Conditions | Frequency | 1RM (kg) | % | Δ (kg) | MD | CSA (cm2) | % | Δ (cm2) | ||
|---|---|---|---|---|---|---|---|---|---|---|
| pre | post | (13.7 kg) | pre | post | ||||||
| RTEV | 1x/week | 215.6 ± 53.2 | 246.8 ± 50.9* | ↑ 16.0 ± 10.0 | 31.2 ± 18.1 | ↑ 17.5 ± 18.1 | 100.2 ± 10.6 | 102.3 ± 11.4* | ↑ 2.1 ± 2.1 | 2.1 ± 2.3 |
| 3x/week | 219.0 ± 53.4 | 252.9 ± 54.3* | ↑ 17.2 ± 12.2 | 33.9 ± 21.6 | ↑ 20.2 ± 21.6 | 101.3 ± 10.8 | 103.3 ± 11.2* | ↑ 2.0 ± 2.8 | 2.0 ± 3.0 | |
| RTUV | 1x/week | 186.1 ± 60.7 | 219.0 ± 65.0* | ↑ 19.4 ± 13.1 | 32.9 ± 19.5 | ↑ 19.2 ± 19.5 | 100.4 ± 16.4 | 101.8 ± 16.4* | ↑ 1.5 ± 2.6 | 1.4 ± 3.0 |
| 3x/week | 192.3 ± 65.6 | 235.9 ± 75.1* | ↑ 24.6 ± 14.2 | 43.7 ± 22.9 | ↑ 30.0 ± 22.9 | 100.9 ± 18.7 | 104.8 ± 17.9* | ↑ 4.1 ± 5.0 | 3.9 ± 4.6 | |
1RM, maximal dynamic strength in the unilateral leg press 45°; Δ, absolute difference; MD, minimum difference; CSA, quadriceps femoris cross-sectional area; RTEV, resistance training
with equalized total training volume; RTUV, resistance training with unequalized total training volume; ↑, increase.
* p<0.001 (time effect).
There were no significant differences in the average TTV throughout the study between frequencies in the RTEV condition (167,582 ± 13,673 kg and 167,586 ± 13,661 kg one and three times/week, respectively, p = 0.999) (Fig 1). On the other hand, in the RTUV condition, there were significant differences in TTV between one and three times a week (137,986 ± 8,126 kg and 164,894 ± 12,855 kg, respectively, p = 0.00005) (Fig 2).
Fig 1. Total training volume per week at different frequencies of RTEV.
TTV, total training volume; RTEV, resistance training with equalized total training volume.
Fig 2. Total training volume per week at different frequencies of RTUV.
TTV, total training volume; RTUV, resistance training with unequalized total training volume. *p≤0.05.
In both RTEV and RTUV conditions, there were significant increases (p<0.001) in the unilateral leg press 45° 1RM after training. However, no significant differences were observed between RT frequencies in each condition (p = 0.454). Similarly, there were significant increases (p<0.001) in the quadriceps femoris CSA values; however, no significant differences (p = 0.310) between RT frequencies were observed (see Table 2). The SEM between 1RM tests was 5.0 kg, which resulted in a MD to be considered of 13.7 kg. The variation between two different measurements of the same image for CSA was 0.2 cm2, resulting in a reproducibility of 99.8%.
The ES was 0.15 (i.e., insignificant) with a 95% CI from -0.26 to 0.57 between 1RM values of the different frequencies for the RTEV condition. On the other hand, in the RTUV condition the ES was 0.51 (i.e., medium) with 95% CI from 0.09 to 0.97 (Fig 3A). For CSA values, the ES between the different frequencies of the RTEV condition was -0.02 (i.e., insignificant) with a 95% CI from -0.43 to 0.40 while in the RTUV condition the ES was 0.63 (i.e., medium) with 95% CI from 0.21 to 1.10 (Fig 3B). Therefore, the higher RT frequency (higher TTV) induced significant increases in the RTUV condition for 1RM and CSA, since for both variables the upper and lower CI limits did not crossing zero (Fig 3A and 3B).
Fig 3.
Effect sizes with the confidence interval for 1RM (A) and CSA (B) values at different resistance training frequencies of RTEV and RTUV. ES, effect size; 1RM, maximum dynamic strength; CSA, quadriceps femoris cross-sectional area; RTEV, resistance training with equalized total training volume and; RTUV, resistance training with unequalized total training volume.
Considering the individual changes in the 1RM and CSA values (percentage changes), the mean of individual % changes between 1x and 3x were smaller in the RTEV condition (Fig 4A and 4B) compared to RTUV condition (Fig 5A and 5B).
Fig 4.
Individual percentage change in the values of 1RM (A) and CSA (B) in the RTEV. 1RM, maximum dynamic strength; CSA, quadriceps femoris cross-sectional area; RTEV, resistance training with equalized total training volume; ———, average of the percentage change 1x/week;–––––, average of the percentage 3x/week.
Fig 5.
Individual percentage change in the values of 1RM (A) and CSA (B) in the RTUV. 1RM, maximum dynamic strength; CSA, quadriceps femoris cross-sectional area; RTUV, resistance training with unequalized total training volume; ———, average of the percentage change 1x/week;–––––, average of the percentage change 3x/week.
Discussion
The present study verified the changes in lower limbs 1RM performance and quadriceps femoris muscle CSA after a 9-week RT program executed at different weekly frequencies (one and three times) in a group of trained individuals with a within-subject design. Our main findings showed that there were no significant differences in 1RM and CSA values between the different RT frequencies, regardless of whether or not TTV was equalized. However, ES and CI suggested a greater training effect on 1RM and CSA induced by higher RT frequency compared with lower in the RTUV condition, where the lower limb that trained three times a week showed a higher TTV compared to the contralateral limb once/week. On the other hand, in the RTEV a small training effect was induced by 3x/week compared with 1x/week. In this condition, lower limbs TTV was equalized between different RT frequencies.
McLester Jr. et al. [35] were the first to compare different RT frequencies with equalized volumes in trained individuals. In that study, they compared RT protocols where each muscle group was trained one or three times/week, and significant increases in leg press 1RM values were observed in the group with higher weekly frequency (22.3% vs. 46.1% for one and three times/week, respectively). The divergence found between these results and ours may be explained by two important facts. 1) McLester Jr. et al. [35] applied a between-subject design, which favors higher data variability in RT-induced changes in strength gains [28] which might, at least partially, explain the differences between intervention groups; and 2) the initial diferences in 1RM values presented by the participants of both studies. In the study of McLester Jr. et al. [35] the baseline values of 1RM in the bilateral leg press were 200.3 ± 83.1 kg and 191.2 ± 96.3 kg, for the frequencies of one and three times/week, respectively. In our study, these values were higher (Table 2) considering that the unilateral leg press 45° was the applied test. Apparently, there is a negative relationship between the initial strength level and the percentage of its increase during the training period [36]. According to the American College of Sports Medicine [7], untrained individuals can increase muscle strength by approximately 40% over training periods ranging from four weeks to two years. In contrast, in trained individuals these increases may be approximately 16% for the same period, closer to the results found in this study.
Also comparing weekly RT frequencies of one or three times/week in trained individuals, Schoenfeld et al. [22] did not found significant differences in 1RM increases in the bench press (6.8% and 10.2%) and squat (10.6% and 11.3%) exercises, for the RT performed one and three times a week, respectively. Indeed, the literature has not shown differences in muscle strength gains when different RT frequencies were compared in trained individuals, regardless of whether the TTV was equalized [22, 37–41] or not [42–45]. However, these studies also have not considered between-subjects’ data variability in their design. An important feature of the present study was the use of a within-subject design to decrease this variability, also allowing a rigorous equalization of the TTV performed weekly. Moreover, this is the first study to bring in the same experimental design the comparison of different RT frequencies with equalized (RTEV) and unequalized (RTUV) TTV.
From a more practical approach, in the present study, RTEV and RTUV conditions allowed to us making within- and between-subject comparisons. Considering the within-subject comparison, in the RTEV condition (i.e., different RT frequencies with same TTV), the training effect on strength performance was, in fact, similar between low and high RT frequencies. However, in the RTUV condition (i.e., different RT frequencies and TTV), the training effect on strength gain was more pronounced in the high RT frequency and high TTV (supported by the use of the ES and CI). It is noteworthy that in between-subject approach, the comparison between high RT frequencies (i.e., 3x/week) in the RTEV and RTUV conditions, showed that the RTUV condition presented better results on strength performance (S1 Fig). Considering the same TTV between the different conditions (RTEV and RTUV), one could expect the same training-induced adaptation in muscle strength performance. Even though this result would be hard to reconcile, the between-subjects data variability seems to be a reasonable explanation for the observed difference [28]. Thus, it is possible to suggest that the between-subject approach may be less appropriate for investigating the effects of RT frequency and volume on muscular adaptations.
Differently from the McLester Jr. et al. [35], that estimated muscle mass increase and body composition alterations through skinfold measurements, most recent studies performed these same measurements through dual-energy x-ray absorptiometry [38, 39, 42, 45], air displacement plethysmography [46], and ultrasound images [22, 37, 39–41, 43, 44, 46]. In many of these studies [22, 39–41, 44, 46] authors did not find differences in lower limbs muscle CSA when different RT frequencies were compared. However, Zaroni et al. [43] demonstrated that a greater TTV provided by the higher RT frequencies could contribute to the increase in lower limb muscle CSA. As far as we know, this is the first study with trained individuals that used magnetic resonance imaging to assess changes in muscle CSA following a protocol with different weekly RT frequencies. In the present study no significant differences were observed in increases of quadriceps femoris CSA between the different frequencies of the RTEV condition. In fact, studies with trained individuals have not shown additional benefits to hypertrophic adaptations when the same TTV is distributed with different strategies [47, 48]. In the RTUV condition, no significant differences in CSA increases were also observed between the different RT frequencies; however, the ES and CI suggest a great effect on CSA induced by the higher RT frequency, probably due to the higher TTV (i.e., ES = 0.63; CI = 0.21 to 1.10). The ES interpretation corroborates the recent evidence demonstrating the importance of training volume in muscle adaptations [9, 10]. In practice, increasing the RT frequency would be one of the possible ways to increase TTV over a specific period of time [9, 15, 42–45].
Finally, as similarly discussed for the strength gains, the comparisons between high training frequency in the RTEV and RTUV conditions (i.e., between-subjects’ comparisons) showed that RTUV presented greater muscle CSA increments (see S1 Fig). In both conditions, the subjects trained three times per week and the TTV was similar, so similar adaptations would be expected for both groups, as observed in within-subject comparisons. The reasonable explanation for data discrepancy, strengthened by our experimental design, is also that between-subject data variability is imperative to interfere in the results, likely adding bias to the results.
It is important to mention some limitations of the present study: (a) CSA was measured only in the middle portion of the quadriceps femoris muscle (i.e., 50% of the distance between the greater trochanter and the lateral femoral epicondyle), precluding any speculation about hypertrophic adaptations in the proximal and distal regions; (b) only one exercise (unilateral leg press 45°) was performed during the 9-week RT program and it has been shown that varying exercises may result in larger hypertrophy adaptations [49]; (c) the unilateral RT protocol may promote a cross-education effect, which would increase contralateral limb strength gains [50]; however, this effect is less likely to occur in trained individuals that perform unilateral RT in both lower limbs [47]. In addition, the within-subject experimental design proposed in this study attempted to reduce the interference of the variability found in the between-subject experimental designs; (d) in the RTEV condition, the repetitions performed in the higher RT frequency could not always be considered maximum repetitions, as they were performed with the average weight obtained with the lower weekly frequency of the contralateral lower limb. However, recent evidence has shown that trained individuals in RT programs with equalized TTV can achieve similar or even higher results in both strength [51, 52] and muscle hypertrophy [53], even when maximum repetitions are not performed.
Conclusion
The results of this study demonstrated that RT performed three times a week, increased 1RM and quadriceps femoris CSA similarly to that performed only once a week in trained subjects. When the higher RT frequency resulted in a larger TTV, such as in the RTUV condition (17% more than the lower frequency), greater ES were observed for both 1RM and CSA. Therefore, if trained individuals need higher RT volumes to obtain gains in both strength [8] and muscle mass [9–11], alternatives such as increasing RT frequency could be considered [21, 54]. Moreover, when the same TTV is distributed at different weekly frequencies, no additional benefits in increases in strength and muscle mass are observed.
Supporting information
1RM = 0.44 (ES) with 0.02 to 0.89 (CI) and, CSA = 0.48 (ES) with 0.05 to 0.94 (CI). ES, effect size; 1RM, maximum dynamic strength; CSA, quadriceps femoris cross-sectional area; CI, confidence interval.
(TIF)
Acknowledgments
We would like to acknowledge the Diagnostics of the Americas S/A (DASA) for carrying out the magnetic resonance images of this study. In addition, we would like to express a special thanks to all participants for their dedication and commitment during the research.
Data Availability
All relevant data are within the paper and its Supporting Information files.
Funding Statement
The author(s) received no specific funding for this work.
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Associated Data
This section collects any data citations, data availability statements, or supplementary materials included in this article.
Supplementary Materials
1RM = 0.44 (ES) with 0.02 to 0.89 (CI) and, CSA = 0.48 (ES) with 0.05 to 0.94 (CI). ES, effect size; 1RM, maximum dynamic strength; CSA, quadriceps femoris cross-sectional area; CI, confidence interval.
(TIF)
Data Availability Statement
All relevant data are within the paper and its Supporting Information files.