Abstract
Stop and start of stepping are two basic actions of the musculo-skeletal system of a leg. Although they are basic phenomena, they require the coordinated activities of the leg muscles. However, little is known of the details of how these activities are generated by the interactions between the local neuronal networks controlling the fast and slow muscle fibres at the individual leg joints. In the present work, we aim at uncovering some of those details using a suitable neuro-mechanical model. It is an extension of the model in the accompanying paper and now includes all three antagonistic muscle pairs of the main joints of an insect leg, together with their dedicated neuronal control, as well as common inhibitory motoneurons and the residual stiffness of the slow muscles. This model enabled us to study putative processes of intra-leg coordination during stop and start of stepping. We also made use of the effects of sensory signals encoding the position and velocity of the leg joints. Where experimental observations are available, the corresponding simulation results are in good agreement with them. Our model makes detailed predictions as to the coordination processes of the individual muscle systems both at stop and start of stepping. In particular, it reveals a possible role of the slow muscle fibres at stop in accelerating the convergence of the leg to its steady-state position. These findings lend our model physiological relevance and can therefore be used to elucidate details of the stop and start of stepping in insects, and perhaps in other animals, too.
Highlights
When legged animals stop or start stepping, a transition between posture and locomotion takes place
This is presumably achieved by the interactions of the local neuronal networks that control the activity of the leg muscles
We assumed that sensory signals reflecting the positions and the velocities of the joints of the middle leg were used to coordinate the movements of the femur and tibia both at stopping and starting the locomotion
Summary
When legged animals stop or start stepping, a transition between posture and locomotion takes place. There is experimental evidence [1] that a leg does not stop randomly during its step cycle. It is reasonable to assume that both processes require coordinated actions of the leg muscles. For a deeper understanding of the underlying neurophysiological mechanisms of locomotion in insects, it is quite important to study and analyze its elementary processes such as stop and start of stepping. This may open up the way for tackling more complex processes of walking in various conditions
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