Muscle Activity in Upper-Body Single-Joint Resistance Exercises with Elastic Resistance Bands vs. Free Weights

Regular resistance training provides several health benefits (Chodzko-Zajko et al., 2009; Kristensen and Franklyn-Miller, 2012; Williams et al., 2007). However, limitations associated with conventional resistance training equipment might restrain therapists, patients and the general population from using this form of exercise. Barbells, dumbbells, weight-plates and resistance training machines are heavy, stationary and require space. Moreover, many people do not have the interest or opportunity to exercise at a fitness center.

An alternative way of performing resistance training is by using elastic bands, which require little space and are light and portable. When barbells, dumbbells or conventional training machines are used, external resistance does not change during the range of motion, while elastic resistance provided by elastic bands will increase with elongation of the band (Patterson et al., 2001).

Several studies have used surface electromyography (EMG) to compare muscle activation in resistance exercises using both elastic and conventional resistance. Some of these suggest that when relative resistance is matched – the same percentage of one-repetition maximum - similar levels of muscle activation can be achieved for the prime movers (Aboodarda et al., 2011; Andersen et al., 2010; Brandt et al., 2013; Calatayud et al., 2014; Jakobsen et al., 2012; Jakobsen et al., 2014), whereas others have found conventional resistance to be the favorable modality (Sundstrup et al., 2014; Vinstrup et al., 2015; Vinstrup et al., 2015).

The muscular activation patterns have been found to differ between elastic bands and conventional resistance training exercises, with higher muscle activity for conventional and elastic resistance in different phases of the contraction. Generally, muscle activity induced by conventional equipment is higher than from elastic resistance early in the concentric phase of the contraction, while towards the end – when the band is elongated - muscle activity levels are more similar. However, this is affected by the “sticking point” of the exercise in question. The sticking point is commonly known as the point in the range-of-motion (ROM) where one experiences a disproportionally large increase in the difficulty to complete the movement (van den Tillaar and Ettema, 2009), and is the performance bottleneck in a resistance exercise (Kompf and Arandjelovic, 2016). In movements where the sticking point occurs in the early phase of the concentric ROM with conventional resistance one might assume that the sticking point occurs later in the movement phase with elastic bands, due to the gradually increasing external resistance, but to our knowledge this has not been experimentally verified.

This study compares the single-joint flyes and reverse flyes exercises using dumbbells versus elastic bands. The fly primarily targets muscles in the chest, while reverse flyes primarily targets the posterior shoulder muscles. Furthermore, the fly is an exercise where the sticking point is early in the concentric phase with dumbbells, due to the high leverage created by the arms in this position. For reverse flyes the sticking point will occur towards the end of the concentric ROM for both dumbbells and the elastic band, as the leverage will be highest here. Thus, we hypothesized that overall EMG levels would be comparable between the modalities, yet higher EMG levels would be induced by elastic bands than dumbbells in the late concentric and early eccentric phase in flyes, but not in reverse flyes where we expected similar activation for dumbbells and elastic bands throughout the movement.

For flyes, there were significant main effects of the exercise modality on muscle activity levels for all muscles (p ≤ 0.026 for all comparisons) and also significant interactions between muscle activity and the exercise modality in both the concentric and eccentric phases (p ≤ 0.001 for all comparisons). For the pectoralis major, muscle activity was highest when using dumbbells, whereas for the deltoideus anterior, biceps brachii and latissimus dorsi, elastic bands induced the highest levels of muscle activity. Figure 3 shows results of post hoc comparisons for muscle activity in the different contraction phases of flyes with elastic bands versus dumbbells.

Figure 1

Figure 2

Figure 3

For reverse flyes, there were significant main effects of the exercise modality on muscle activity levels for all muscles (p ≤ 0.001 for all comparisons). Significant interactions were found for the deltoideus medius and trapezius descendens in both the concentric and eccentric phase (p ≤ 0.011 for both comparisons). Higher muscle activity was observed when using elastic resistance compared to free-weight resistance for the trapezius and deltoideus medius. In contrast, the deltoideus posterior and latissimus dorsi displayed higher muscle activity when using free-weight resistance. Figure 4 shows results of post hoc comparisons for muscle activity in the different contraction phases of reverse flyes with elastic bands versus dumbbells.

Figure 4

Table 1 shows the perceived exertion rated on the Borg CR10 scale after performing the 10-RM tests with elastic bands and dumbbells. Elastic bands were rated heavier compared to dumbbells for both flyes and reverse flyes; yet statistical significance was only reached for reverse flyes.

Table 1

Perceived exertion rated on the Borg CR10 scale after performing the 10-RM tests with elastic and free-weight resistance. Values are mean (SD).

The main objective of this study was to assess differences in muscle activity levels induced by elastic bands and dumbbells in flyes and reverse flyes. In flyes, elastic bands generally induced lower levels of muscle activation for the pectoralis major than dumbbells, but higher for the deltoideus anterior. In reverse flyes, elastic bands generally induced lower levels of muscle activation for the deltoideus posterior, but higher for the deltoideus medius and trapezius descendens.

Flyes are primarily used to target chest muscles. Overall, dumbbells were slightly more effective for this muscle group. However, the results showed that elastic bands activated the deltoideus anterior substantially more, and that flyes, performed with elastic bands in particular, could be effectively used to train the deltoideus anterior as well.

Partly in accordance with our expectation that higher EMG levels would be induced during exercises with elastic bands than dumbbells in the end ranges in flyes, muscle activity for the pectoralis major in flyes was lower with elastic bands in CON1 and ECC2, but higher in CON2, and similar in ECC1. This may be explained by the very high leverage provided by dumbbells in the beginning of the concentric phase. When the sticking point is passed, a pronounced decline in muscle activity is seen for dumbbells. In contrast, muscle activity induced during exercises with elastic bands increases from the beginning towards the end of the range of motion, mirroring the increasing external resistance caused by elongation of the band. In ECC1 there was no difference between the modalities, whereas when the dumbbells were lowered out to the sides in ECC2, the dumbbells again induced a higher pectoralis major activation level.

Reverse flyes are primarily utilized for deltoideus posterior training. Overall, dumbbells were slightly more effective in activating this muscle, more or less in all phases of the contraction. However, the activation level of the deltoideus medius and trapezius descendens during exercises with elastic bands was substantially higher than with dumbbells, and reverse flyes with elastic bands appear to be a very effective exercise for these muscles. As expected, when the sticking point occurred at the end of the concentric range of motion for both elastic bands and dumbbells, we did not observe the differential development in reverse flyes for the deltoideus posterior that we observed in flyes for the pectoralis major, in which the sticking point was in the early concentric phase (Figure 3A and 4A).

A similar pattern was observed from both single-joint exercises in the sense that elastic bands were slightly less effective in activating the muscles usually perceived to be the prime movers (i.e. pectoralis major for flyes and deltoideus posterior for reverse flyes). However, elastic bands induced substantially higher activation levels in muscles perceived to be ancillary. It could be that performing these exercises with elastic bands instead of dumbbells made them more unstable. Increased stability requirement could possibly elicit higher neural drive to stabilize the shoulder joint, which had been suggested previously for dumbbells versus the barbell chest press (Saeterbakken et al., 2011). However, it is also possible that the different postures contributed to these effects, as participants were lying on a bench when the exercises with dumbbells were performed, but standing during execution with elastic bands, which is another way of inducing higher instability and to increase muscle activation of the deltoideus anterior (Saeterbakken and Fimland, 2013)

The increased stability requirement possibly induced by a standing posture, involving more stabilizing muscles, could also explain why higher ratings of perceived effort on the Borg CR10 scale were reported for elastic bands compared to dumbbells. Partly in agreement with our finding, Jakobsen and coworkers found a higher rating of perceived effort when performing knee flexions with elastic bands versus a conventional training machine (Jakobsen et al., 2014).

A limitation of this study is the use of EMG to measure dynamic contractions. The interpretation of the EMG signal during movement can be complicated by issues such as signal nonstationarity, the relative shift of the electrodes, and fluctuations in conductivity properties of the skin (Farina, 2006). Importantly, the EMG measurements were performed in the same session, thus there was no need to replace electrodes. Furthermore, we measured EMG on one side of the body only. In our study, we used an 8-channel EMG system, so measuring on one side only allowed us to measure more muscles at the same time. The decision to measure the dominant vs. non-dominant side was arbitrary. However, we do not expect that the activation patterns would be different on the non-dominant side.

Another limitation is the 10-RM protocol used for matching the loads between the modalities. It is challenging to find the true 10- RM, particularly with elastic bands. However, the test leader was experienced in resistance training, ensuring that 10-RM could be identified within 5 attempts and we are unaware of a better procedure to match relative resistance. Furthermore, to fine-tune resistance with elastic bands, it was necessary to change the distance between the participant and the anchor point individually. Hence, we are unable to report a standardized pre-stretch of the elastic bands for each exercise.

In conclusion, elastic resistance bands induced slightly lower muscle activity in the muscles most people aim to activate during flyes and reverse flyes, i.e., pectoralis major and deltoideus posterior, respectively. However, elastic resistance bands increased the muscle activation level substantially in the deltoideus anterior in flyes, and deltoideus medius and trapezius descendens in reverse flyes, possibly due to elastic bands being a more unstable resistance modality.