Abstract
Insects alter their walking pattern in order to respond to demands of an ever-changing environment, such as varying ground surface textures. They also exhibit resilient and flexible ability to retain the capacity to walk even after substantial changes in their body properties, e.g. leg amputation. While the motor control paradigm governing the inter-leg coordination in such adaptive walking has been extensively described in past studies, the mechanism remains unknown. Here, we examined this question by using the cricket (Gryllus bimaculatus), which shows a tetrapod/tripod gait on a flat surfaces, like many other insects. We performed leg amputation experiments to investigate modifications of leg movements and coordination of muscle activities. We simultaneously recorded (1) the leg movements, locomotion velocity, and body rotation and (2) the leg movements and leg muscles activities before and after leg amputation. Crickets displayed adaptive coordination of leg movement patterns in response to amputations. The activation timings of levator muscles in both middle legs tended to synchronize in phase when both legs were amputated at the coxatrochanteral joint. This supports the hypothesis that an intrinsic contralateral connection within the mesothoracic ganglion exists, and that mechanosensory feedback from the legs override this connection, resulting in the anti-phase movement of a normal gait.
Highlights
Insects alter their walking pattern in order to respond to demands of an ever-changing environment, such as varying ground surface textures
We investigated changes in leg coordination patterns of the cricket (G. bimaculatus) using two experimental setups: (1) simultaneous recordings of leg movements, walking velocity and body rotation, and (2) simultaneous recordings of muscle activations and leg movements
The gait analysis for remaining leg coordination indicated that phase difference of the foot contact timing between fore and hind legs were changed from almost in-phase (0.25 π ) to anti-phase ( π ) synchronization before and after amputations, resulting in the change from a tetrapod/ tripod gait to a four legged trot gait
Summary
Insects alter their walking pattern in order to respond to demands of an ever-changing environment, such as varying ground surface textures. Simultaneous recordings of EMG signals and leg movements during walking both before and after leg amputation showed that the activation timing of levator muscles in both midleg muscles synchronised in phase when the legs were amputated at coxatrochanteral (CTr) joint, whereas the timing showed both anti-phase and in-phase synchronisation when only one leg or one leg and a femur remained These results suggest that an intrinsic contralateral connection exists within the mesothoracic ganglion[21,32,33,34], and mechanoreceptive informational feedback from the campaniform s ensilla[26,35,36,37] of the legs overrides the centrally generated patterns, resulting in the anti-phase leg movements of a normal gait
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