Muscular strength is an important component for physical activity and performance of daily living activities. A phenomenon usually observed is that the capacity of generating maximum strength is compromised when the homologous extremities bilaterally contract. This phenomenon is called bilateral deficit. Thus, the aim of this work was to compare the electrical activity of the deltoid muscle, medial portion, during unilateral and bilateral contractions in a converging articulated military press machine, with 90% of maximum voluntary load (MVL), in nine men aged between 20 and 30 years, stature of 174 ± 5cm and body mass of 78 ± 15 kg. The myoelectrical signals were obtained through placement of differential active surface electrodes by EMG System of Brazil, a reference electrode (ground) and a signal conditioner module (electromyograph), which provided numerical data in RMS (root mean square) for results analysis. Each signal collected picked only the concentric phase of the movement and it had duration of three seconds. The results evidenced that during bilateral and unilateral exercise with 90% of MVL, the electric activity of the non-dominant extremity was significantly higher than in the dominant one (p = 0.018). When the values obtained in the work of dominant extremity are summed with the work of non-dominant extremity in the bilateral exercise (2.231 ± 504µv) and compared with the values obtained in the unilateral work (2.663 ± 701µv), bilateral deficit was found (p = 0.018). According to our study, it was verified that the bilateral deficit phenomenon is present in the medium deltoid muscle in the converging multiarticular military press exercise in individuals familiarized with resistance exercises.
The objective of this study was to compare the electrical activity of the deltoid (middle portion), pectoralis major (clavicular portion) and triceps (long head) muscles during bilateral contraction performed in a multi-articulated joint shoulder-press convergent machine with 40% and 80% maximum voluntary load (MVL) in 11 male swimmers (15 to 23 years, 70 ± 4 kg, 183 ± 6 cm and 10 ± 4 years' time of practice in sport), trained in resistance exercise. Electromyographic signals (EMG) were obtained by placing surface active differential electrodes (20 x gain), composed of two parallel rectangular bars (EMG System, Brazil ® ). A data acquisition system (EMG-Alc) which provided numerical data in RMS (Root Mean Square) to analyze the signals composed by a reference electrode (ground) and a signal conditioning module (EMG) with simultaneous acquisition of up to 8 differential channels (band-pass filter 5-20 Hz), adjustable amplifier stage, allowing gains between 100 and 4960 times, channel input impedance 10GΩ in differential modules and CMRR of 93 dB/60 Hz was used. Only the concentric phase (3 seconds duration) in each EMG signal collected was recorded. After the tests (Mann-Whitney U test, Friedman and Wilcoxon) were applied, it was concluded that for prescription and periodization of the neuromuscular training, bilateral contractions performed in the shoulder-press apparatus are efficient at aiming muscular recruitment (80%> 40% ) of middle portion of the deltoid, pectoralis major (clavicular portion), and triceps brachii (long head) muscles, evidencing differences between dominant and non-dominant limbs only for the dominant brachial triceps in 80% of MVL in swimmers trained in resistance exercises.
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