Abstract
The percentage area of fast twitch fibres of a muscle is a major determinant of muscle mechanical power and, thus, an important biomarker for the evaluation of training processes. However, the invasive character of the assessment (muscle biopsy) limits the wide application of the biomarker in the training praxis. Our purpose was to develop a non-invasive method for the assessment of fast twitch fibre content in human soleus muscle. From a theoretical point of view, the maximum muscle mechanical power depends on the fibre composition, the muscle volume and muscle specific tension. Therefore, we hypothesised that the percentage area of type II fibres would show a correlation with the maximum muscle mechanical power normalised to muscle volume and specific muscle contractile strength (i.e., plantar flexion moment divided by muscle cross-sectional area). In 20 male adults, the percentage area of type II fibres, volume and maximum cross-sectional area of the soleus muscle as well as the maximum plantar flexion moment and the maximum mechanical power were measured using muscle biopsies, magnetic resonance imaging and dynamometry. The maximum mechanical power normalised to muscle volume and specific muscle contractile strength provided a significant relationship (r = 0.654, p = 0.002) with the percentage area of type II fibres. Although the proposed assessment parameter cannot fully replace histological measurements, the predictive power of 43% can provide a relevant contribution to performance diagnostics in the training praxis.
Highlights
Athletic training is a dynamic process that triggers specific adaptions within the human musculoskeletal system resulting in an increase in functional performance
Muscle volume of the soleus muscle correlated moderately to maximum mechanical power (r = 0.459, p = 0.042), but there was no significant correlation between specific contractile strength and maximum mechanical power (r = 0.116, p = 0.626)
The maximum mechanical power did not show any relationship with the percentage area of type II fibres (r = 0.078, p = 0.754), but the maximum mechanical power normalised to muscle volume and muscle contractile strength provided a significant correlation (r = 0.654, p = 0.002) with the percentage area of type II fibres (Figure 3)
Summary
Athletic training is a dynamic process that triggers specific adaptions within the human musculoskeletal system resulting in an increase in functional performance. Resistance exercise can introduce a more pronounced hypertrophy in type II compared to type I fibres (Costill et al, 1979; MacDougall et al, 1980; Aagaard et al, 2001), increasing the percentage area of type II fibres during hypertrophic adaptation without any changes in the numerical fibre distribution within a muscle. In this manner, the percentage area of type II muscle fibres can serve as an important biomarker for the evaluation of training processes. A non-invasive method for the assessment of muscle fibre type composition would be an important diagnostic tool in both athletes and non-athletes
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