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Journal of Strength and Conditioning Research, 2007, 21(4), 1082–1086 䉷 2007 National Strength & Conditioning Association

EFFECTS OF EXERCISE ORDER ON UPPER-BODY MUSCLE ACTIVATION AND EXERCISE PERFORMANCE PAULO GENTIL,1,2 ELKE OLIVEIRA,2 VALDINAR AND MARTIM BOTTARO3

DE

ARAU´JO ROCHA JU´NIOR,3 JAKE

DO

CARMO,3

College of Physical Education, Catholic University of Brasilia, Brasilia, Brazil; 2College of Health Science, University of Brasilia, Brasilia, Brazil; 3College of Physical Education and Exercise Science, University of Brasilia, Brasilia, Brazil. 1

ABSTRACT. Gentil, P., E. Oliveira, V.A. Rocha Ju´nior, J. do Carmo, and M. Bottaro. Effects of exercise order on upper-body muscle activation and exercise performance. J. Strength Cond. Res. 21(4):1082–1086. 2007.—With the purpose of manipulating training stimuli, several techniques have been employed to resistance training. Two of the most popular techniques are the pre-exhaustion (PRE) and priority system (PS). PRE involves exercising the same muscle or muscle group to the point of muscular failure using a single-joint exercise immediately before a multi-joint exercise (e.g., peck-deck followed by chest press). On the other hand, it is often recommended that the complex exercises should be performed first in a training session (i.e., chest press before peck-deck), a technique known as PS. The purpose of the present study was to compare upper-body muscle activation, total repetitions (TR), and total work (TW) during PRE and PS. Thirteen men (age 25.08 ⫾ 2.58 years) with recreational weight-training experience performed 1 set of PRE and 1 set of PS in a balanced crossover design. The exercises were performed at the load obtained in a 10 repetition maximum (10RM) test. Therefore, chest press and peck-deck were performed with the same load during PRE and PS. Electromyography (EMG) was recorded from the triceps brachii (TB), anterior deltoids, and pectoralis major during both exercises. According to the results, TW and TR were not significantly different (p ⬎ 0.05) between PRE and PS. Likewise, during the peck-deck exercise, no significant (p ⬎ 0.05) EMG change was observed between PRE and PS order. However, TB activity was significantly (p ⬍ 0.05) higher when chest press was performed after the peck-deck exercise (PRE). Our findings suggest that performing pre-exhaustion exercise is no more effective in increasing the activation of the prefatigued muscles during the multi-joint exercise. Also, independent of the exercise order (PRE vs. PS), TW is similar when performing exercises for the same muscle group. In summary, if the coach wants to maximize the athlete performance in 1 specific resistance exercise, this exercise should be placed at the beginning of the training session. KEY WORDS. resistance training, electromyography, fatigue

INTRODUCTION esistance training has a fundamental role in physical activity programs, and has been recommended by many major health organizations (1, 12, 16, 22, 29). With the purpose of manipulating training stimuli, several resistance exercise order techniques have been employed. Two of the most popular techniques are the pre-exhaustion (PRE) and priority system (PS). Pre-exhaustion involves exercising the same muscle or muscle group to the point of muscular failure using a single-joint exercise immediately before a multi-joint exercise (11). The rationale for PRE utilization probably lies in muscle behavior during fatigue, but the evidence is contradictory. Some studies found a progressive increase

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in the electromyographic (EMG) signal amplitude during submaximal isometric voluntary contractions (7, 18, 19). These results suggested that additional motor units (MU) are recruited in order to compensate for the loss of functionality of others. However, studies using near maximum efforts reported that fatigue resulted in a significant reduction in motor unit activation (5, 15, 18). The activity of accessory muscles may also be altered during PRE because of the fatigue of prime movers. Akima et al. (2), Newham et al. (20), and Nyland et al. (21) reported that prime movers fatigue is compensated by increasing MU recruitment of accessory muscles. Akima et al. (2) reported that vastus lateralis fatigue resulted in recruitment pattern alterations during knee extension exercise, leading to a decrease in vastus lateralis muscle activation and an increase in vastus medialis and rectus femoris muscle activation. Augustsson et al. (3) investigated the effects of PRE exercise on lower extremity muscle activation during leg press and reported that the performance of 10 repetition maximum (10RM) knee extension exercise immediately before leg press exercise resulted in a decrease in the activation of rectus femoris and vastus lateralis muscles. Although the data showed no significant change in gluteus maximus muscle activation, the authors suggested that it is possible that there were changes in the activation of other muscles, such as adductors and gastrocnemius. It is important to note that Augustsson et al. (3) did not investigate EMG activity on leg press exercise followed by a knee extension exercise. Another popular resistance training method is the PS. It is usually recommended that the major goal exercises should be placed first in a training session in order to perform these exercises with maximal intensity (11). Sforzo and Touey (23) reported that the total work of a training session was greater when multi-joint exercises were performed first in the workout session. When analyzing a single exercise, Sima˜o et al. (24) found that the number of repetitions was decreased when the resistance exercise was performed later in a training session. However, Spreuwenberg et al. (26) reported that performing the squat exercise after a whole-body workout session may result in a greater power output. Therefore, the effect of PS on muscle performance is still unclear. Additionally, to our knowledge no study has investigated the effect of exercise order on EMG activity of upper-body muscles. Thus, the purpose of the present study was to investigate the effects of exercise order (PRE vs. PS) on the total work output, total number of repetitions performed and upperbody muscle activation in trained young men.

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EMG was recorded from 3 upper-body muscles (triceps brachii [TB], anterior deltoids [AD], and pectoralis major [PM]) in 2 different situations: (a) PRE (peck-deck before chest press) and (b) PS (chest press before peck-deck). Total work (TW ⫽ resistance ⫻ repetitions) and total repetitions (TR ⫽ sum of repetitions performed during chest press and peck-deck exercise) were also recorded during PRE and PS.

The analyses were made with the mean of the EMG signals calculated from the repetitions performed, excluding the first and the last repetitions. Raw EMG signals were recorded using the Bagnoli-8 EMG system (DelSys) with a common mode rejection ratio of 90 dB. The EMG signal was preamplified with a gain of 1,000 and band pass-filtered between 20 and 500 Hz. The signal was sampled at a rate of 2,000 Hz and rectified. The average of the amplitude was calculated using the root mean square method. The amplitude was normalized to the peak EMG value obtained during the tests for each subject (6, 30).

Subjects

Experimental Procedures

Thirteen healthy men (age: 25.08 ⫾ 2.58 years; weight: 71.68 ⫾ 8.65 kg; height: 172.50 ⫾ 6.49 cm) with 7.37 ⫾ 4.42 years of resistance exercise experience volunteered to participate in the experiment. In order to do so, subjects must have been performing recreational resistance training at least 3 times a week during the previous 12 months and have had no health problems that could be negatively influenced by the tests. All subjects were accustomed to training with both exercise orders. None of the subjects had a recent or remote history of significant upper-body injury. Before participation, each subject read and signed a detailed consent form. The study was approved by the Institutional Review Board.

Subjects were instructed not to perform any resistance exercises involving the PM, AD, or TB muscles during the 72 hours before the tests. Before testing, each subject was instructed in the proper technique for each exercise. Subjects were instructed to maintain a constant velocity of 2 seconds in the concentric phase and 2 seconds in the eccentric phase, with no pause between phases. To help control movement velocity, a metronome was used. All exercises were performed at the load obtained during the 10RM tests; therefore, the load for chest press and peck-deck was the same during PRE and PS. During PRE, the subjects performed 1 set of the peck-deck exercise to the point of muscular failure, immediately followed by 1 set of as many repetitions as possible of the chest press exercise. PS involved the performance of 1 set to failure of the chest press exercise, immediately followed by 1 set to failure of peck-deck. PRE and PS were executed in the same day in a balanced crossover design (7 subjects performed PRE first, and the other 6 performed PS first), with 20 to 30 minutes of rest between them.

METHODS Experimental Approach to the Problem

Determination of 10 Maximum Repetition Loads

Ten repetition maximum (10RM) tests were used in order to attenuate errors between subjects and exercises due to the application of percentages of maximum loads (14, 28). In the week before the experiment, the load for 10RM was determined for each subject in the chest press and the peck-deck exercises (High On model, Righetto Fitness Equipment, Sa˜o Paulo, Brazil) by using the maximum weight that could be lifted for 10 consecutive repetitions at a constant velocity of 4 seconds per repetition (2 seconds in concentric and 2 seconds in eccentric phase). If the subject did not accomplish 10RM in the first attempt, the weight was adjusted by 4–10 kg and a minimum 5minute rest was given before the next attempt. Only 3 trials were allowed per testing session. The tests were repeated in all subjects and data were analyzed by Pearson product moment correlations to estimate day-to-day 10RM reliability (r ⫽ 0.98). Peck-deck and chest press 10RM load were 71.54 ⫾ 13.13 and 66.92 ⫾ 15.91 kg, respectively. Electromyography

Recommendations of the International Society of Electrophysiology and Kinesiology pertaining to the use and interpretation of electromyographic data were followed for collecting, managing, normalizing, and analyzing EMG data (17, 25). All EMG measurements were taken on the dominant side of the body. Bipolar 9-mm shielded silver-silver chloride electrodes (DelSys Incorporated, Boston, MA) were placed parallel to the muscle fibers of the TB, AD, and PM following shaving, alcohol cleansing, and mild abrading of the sites. Electrodes were held in place with special double-sized adhesive tape. Recommendations by Zipp (31) on anatomical reference for electrode placement were followed for TB and AD. For PM, the electrodes were placed according to the procedures proposed by Clemons and Aaron (8). All test sites were identified and prepared by the same investigator. After electrode positioning, impedance was verified and accepted when less than 5k⍀.

Statistical Analyses

Results are presented in values of mean ⫾ SD. The 10RM load for chest press and peck-deck were compared using a dependent t-test. A 3-way analysis of variance (ANOVA), 2 ⫻ 2 ⫻ 3 (exercise order [PRE and PS] ⫻ exercises [peck-deck and chest press] ⫻ muscles [AD, TB, and PM]), was used to compare EMG signal. When differences were found, multiple comparisons were made with confidence interval adjustment according to the Bonferroni procedure. TR and TW were compared between PRE and PS using a dependent t-test. An alpha level of 0.05 was used for all comparisons.

RESULTS There were no differences in 10RM load between the chest press and the peck-deck exercises (p ⬎ 0.05). Three-way ANOVA revealed a significant exercise order by exercises by muscles interaction (p ⬍ 0.05). There were also significant interactions between exercises and muscles for EMG activity (p ⬍ 0.05). During the chest press exercise, PM muscle activation was significantly higher than TB (p ⬍ 0.05) for both exercise orders. There were no significant differences in EMG signal amplitude between AD and PM, or AD and TB during chest press for PRE and PS (Figure 1). No significant difference for AD and PM muscle activation was reported between PRE and PS during the chest press exercise. However, significantly (p ⬍ 0.001) higher TB activation was reported in the chest press exercise during PRE compared to PS (Figure 1). There was no significant difference between AD and PM muscle activation during the peck-deck exercise in both exercise orders; however, PM and AD muscle acti-

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significant reduction of 5.44% in PM muscle activation. These results are in agreement with previous studies, which reported greater activation of accessories muscles after fatigue of prime movers (2, 20, 21). The increases in TB muscle activation without a significant decrease in PM muscle activation could be explained by the differences in muscle sizes, which might have resulted in an expressive increase in TB muscle activation to compensate for a slight decrease in PM muscle activation. Some authors propose that fatigue may be a protective strategy to maintain muscle reserve and inhibit muscle activity before any irreparable damage occurs (9, 10, 13, 27). It has been suggested that high-intensity contractions may result in several peripheral changes that activate this protection mechanism and impair exercise performance. Some peripheral mechanisms are: impaired excitation-contraction coupling, shift of Na⫹ and K⫹ concentration in intracellular and extracellular fluids, reductions in Ca⫹⫹ release (9, 10, 13, 27). Although the changes at the muscle level have an important role in fatigue, the central nervous system may also be involved (13, 27). Thus, recruitment strategies may be changed in order to preserve muscle functionality and maintain the performance of a determined task. During PRE, after the peck-deck performance, a portion of the PM motor units may became fatigued, and the tension could have been distributed to other muscles in order to protect fatigued fibers and allow the exercise to continue, which may have lead to an increase in TB muscle activation. Similar results were reported by Akima et al. (2); the researchers induced fatigue of the vastus lateralis muscle in 6 male subjects by transcutaneous electromyostimulation. Quadriceps muscle activation during the knee extension exercise was compared using magnetic resonance images between 2 situations: (a) before and (b) immediately after electromyostimulation. The results showed that fatigue of the vastus lateralis muscle induced a greater recruitment of vastus medialis and rectus femoris muscles during the knee extension exercise. According to the authors, the motor program was apparently modified due to fatigue of 1 muscle; therefore synergists were used to a greater extent. Augustsson et al. (3) assessed the EMG activity of the rectus femoris, vastus lateralis, and gluteus maximus in 17 recreationally trained young men during the leg press exercise with and without PRE. In the study, PRE was characterized as a previous set of 10RM on the knee extension exercise. According to the results, PRE promoted a decrease in the quadriceps muscles activation, with no alterations in gluteus maximus muscle activation; however, the authors suggested that it is possible that there was different activation of other hip extensors or plantar flexion muscles. The present results reported that MU activation did not increase due to fatigue, which is in agreement with previous studies (5, 15). However, Carpentier et al. (7) and Moritani et al. (19) reported an increase in MU ac-

FIGURE 1. Chest press electromyographic (EMG) signal amplitude during priority system (PS) and pre-exhaustion (PRE). TB ⫽ triceps brachii; AD ⫽ anterior deltoids; PM ⫽ pectoralis major. * p ⬍ 0.05, TB activity during PS vs. PRE. † p ⬍ 0.05, PM vs. TB activity during PS. ‡ p ⬍ 0.05, PM vs. TB activity during PRE.

FIGURE 2. Peck-deck electromyographic (EMG) signal amplitude during priority system (PS) and pre-exhaustion (PRE). TB ⫽ triceps brachii; AD ⫽ anterior deltoids; PM ⫽ pectoralis major. * p ⬍ 0.05, TB vs. PM; TB vs. AD, during PS. † p ⬍ 0.05, TB vs. PM; TB vs. AD, during PRE.

vation was significantly higher than TB (p ⬍ 0.05). No significant differences for TB, AD, or PM muscle activation were observed between PS and PRE during the peckdeck exercise (Figure 2). Repetitions performed during the peck-deck exercise were significantly higher during PRE in comparison to PS (p ⬍ 0.01). However, repetitions performed during the chest press exercise were significantly higher during PS (p ⬍ 0.01). There were no significant differences between exercise orders for TR and TW (Table 1).

DISCUSSION Pre-exhaustion resulted in a 33.67% increase in TB muscle activation during chest press, concomitant with a nonTABLE 1.

Exercise performance during pre-exhaustion (PRE) and priority system (PS). Values expressed as mean ⫾ SD.

Variable Chest press (repetitions)* Peck-deck (repetitions)* Total repetitions Total work (repetitions ⫻ kg) * p ⬍ 0.05, PRE vs. PS.

Pre-exhaustion 5.33 10.17 15.50 1,093.17

⫾ ⫾ ⫾ ⫾

1.15 0.58 1.17 249.90

Priority system 9.50 5.17 14.67 1,013.92

⫾ ⫾ ⫾ ⫾

0.80 1.64 1.72 283.62

EFFECTS

tivation during prolonged contractions. These contradictions could be attributed to contraction intensity. Carpentier et al. (7) and Moritani et al. (19) reported an increase in MU activation during isometric contractions at 40 and 50% of maximal voluntary contraction (MVC), respectively. In these studies, a limited number of MUs were recruited initially and this number increased with the progression of the exercise. However, at near maximum efforts, as used by Babault et al. (4), Kay et al. (15), and the present study, most of the muscles fibers were recruited at the beginning of the exercise and, therefore, there was a possible limitation to the increase of MU activation. Furthermore, Moritani et al. (18) compared the EMG activity in the biceps brachii of 12 male subjects during 2 different intensities of isometric contractions: (a) MVC, and (b) contractions at 50% of MVC. The authors reported that EMG amplitude was progressively reduced during MVC, while the opposite occurred during contractions at 50% of MVC. According to the results, if an exercise was performed first it was possible to perform more repetitions with the same load, leading to a greater work, as previously shown by other authors (3, 24, 26). Thus, the present results confirm that if one wants to put an emphasis in an exercise, this exercise should come first in the training session. In the present study, TW and TR were not different between PS and PRE. Contrary to our results, Sforzo and Touey (23) reported that TW was significantly greater when multi-joint exercises were performed before singlejoint exercises. However, there were important methodological differences between the 2 studies. Sforzo and Touey (23) studied muscular performance of 17 trained young men during 2 resistance training sessions with different exercise orders: (a) squat, leg extension, leg flexion, chest press, military press, and triceps pushdown; and (b) leg flexion, leg extension, squat, triceps pushdown, military press, and chest press. The subjects performed 4 sets of each exercise, with 2 minutes of rest between sets. In the present study only 2 exercises (chest press and peckdeck) were used, with 1 set of each exercise with an interval of less than 20 seconds. In the study of Sforzo and Touey (23) the multiple joint exercises (squat and chest press) are normally performed with higher loads than the single-joint exercises (leg extension, leg flexion, and triceps pushdown). Thus, when the multiple joint exercises were performed first, TW (repetitions ⫻ load) was greater. In our study, however, there were no differences between resistance used for chest press and peck-deck. Consequently, TW was not affected by exercise order.

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rather than a prime mover agonistic muscle group, before performing the primary exercise movement. A practical example of this strategy is performing bench press after performing the triceps pressdown. Future research should also address the chronic effects of PRE and PS to assess the long-term consequences of these acute alterations.

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PRACTICAL APPLICATIONS According to the present results, there is no difference between the performances of a single-joint exercise immediately before (PRE) or after (PS) a multi-joint upperbody exercise. Also, we confirmed that independent of the exercise order (PRE or PS), subjects performed less repetition when the exercise was performed later in a training session, when load was kept constant. Therefore, if the coach wants to maximize the athletic performance in 1 specific resistance exercise, this exercise should be placed at the beginning of the training session. However, it appears that PRE may have an increasing effect in the accessory muscles activity (TB). Regarding this finding, future research in the area of exercise order should look for the effects of a fatiguing synergistic muscle group,

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Address correspondence to Paulo Gentil, paulogentil@ hotmail.com.