Abstract
Despite the high availability of surface electromyography (sEMG), it is not widely used for testing the effectiveness of exercises that activate intrinsic muscles of foot in people with hallux valgus. The aim of this study was to assess the effect of the toe-spread-out (TSO) exercise on the outcomes of sEMG recorded from the abductor hallucis muscle (AbdH). An additional objective was the assessment of nerve conduction in electroneurography. The study involved 21 patients with a diagnosed hallux valgus (research group A) and 20 people without the deformation (research group B) who performed a TSO exercise and were examined twice: before and after therapy. The statistical analysis showed significant differences in the third, most important phase of TSO. After the exercises, the frequency of motor units recruitment increased in both groups. There were no significant differences in electroneurography outcomes between the two examinations in both research groups. The TSO exercise helps in the better activation of the AbdH muscle and contributes to the recruitment of a larger number of motor units of this muscle. The TSO exercises did not cause changes in nerve conduction. The sEMG and ENG are good methods for assessing this exercise but a comprehensive assessment should include other tests as well.
Highlights
Surface electromyography is, next to dynamometry, ultrasound and magnetic resonance imaging, a commonly used research tool for assessing muscles
The TSO exercise helps in the better activation of the abductor hallucis muscle (AbdH) muscle and contributes to the recruitment of a larger number of motor units of this muscle
The AbdH muscle activity during the three phases of the TSO exercise was analyzed in each group, taking into account the amplitude and the frequency pattern
Summary
Surface electromyography (sEMG) is, next to dynamometry, ultrasound and magnetic resonance imaging, a commonly used research tool for assessing muscles. The benefits of this type of muscle evaluation using surface sensors have been implemented in many research fields such as medicine, rehabilitation, sport, human-computer interactions, prosthetics and ergonomics. Modern technology and the minimization of surface electromyography devices have allowed the use of this method in biofeedback training. It is a method of training muscles by creating new feedback systems as a result of the conversion of myoelectrical signals in muscles into visual and auditory signals [5].
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