Abstract
Skeletal muscle bulges when it contracts. These three-dimensional (3D) dynamic shape changes play an important role in muscle performance by altering the range of fascicle velocities over which a muscle operates. However traditional muscle models are one-dimensional (1D) and cannot fully explain in vivo shape changes. In this study we compared medial gastrocnemius behaviour during human cycling (fascicle length changes and rotations) predicted by a traditional 1D Hill-type model and by models that incorporate two-dimensional (2D) and 3D geometric constraints to in vivo measurements from B-mode ultrasound during a range of mechanical conditions ranging from 14 to 44 N m and 80 to 140 r.p.m. We found that a 1D model predicted fascicle lengths and pennation angles similar to a 2D model that allowed the aponeurosis to stretch, and to a 3D model that allowed for aponeurosis stretch and variable shape changes to occur. This suggests that if the intent of a model is to predict fascicle behaviour alone, then the traditional 1D Hill-type model may be sufficient. Yet, we also caution that 1D models are limited in their ability to infer the mechanisms by which shape changes influence muscle mechanics. To elucidate the mechanisms governing muscle shape change, future efforts should aim to develop imaging techniques able to characterize whole muscle 3D geometry in vivo during active contractions.
Highlights
Observing the bulging biceps of a body builder or the wiry calves of a marathon runner indicates that skeletal muscle undergoes changes in geometry when it contracts
The 1D, 2D and 3D models tested here were able to capture the general features of the ultrasound measurements of fascicle length and pennation angle
We found that a 1D Hill-type model 14 predicted fascicle lengths and pennation angles similar to both 2D and 3D models that allowed either the aponeurosis to stretch (2D) or both the aponeurosis to stretch and variable muscle shape changes to occur (3D)
Summary
Observing the bulging biceps of a body builder or the wiry calves of a marathon runner indicates that skeletal muscle undergoes changes in geometry when it contracts. These three-dimensional (3D) shape changes emerge from muscles’ ability to generate forces in multiple directions during a contraction. Previous studies have shown that dynamic shape changes alter the force output of muscle by enhancing the range of lengths and velocities over which individual fibres operate and is likely a critical aspect of a muscle’s mechanical performance [3,4,5]. The mechanisms underlying in vivo shape changes in both healthy and pathological muscle are not fully understood
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