Dynamic properties of a locomotory muscle of the tobacco hornworm<i>Manduca sexta</i>during strain cycling and simulated natural crawling

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SUMMARYSoft-bodied animals lack distinct joints and levers, and so their locomotion is expected to be controlled differently from that of animals with stiff skeletons. Some invertebrates, such as the annelids, use functionally antagonistic muscles (circumferential and longitudinal) acting on constant-volume hydrostatics to produce extension and contraction. These processes form the basis for most theoretical considerations of hydrostatic locomotion in organisms including larval insects. However, caterpillars do not move in this way, and their powerful appendages provide grip independent of their dimensional changes. Here, we show that the anterograde wave of movement seen in the crawling tobacco hornworm, Manduca sexta, is mediated by co-activation of dorsal and ventral muscles within a body segment, rather than by antiphasic activation, as previously believed. Furthermore, two or three abdominal segments are in swing phase simultaneously, and the activities of motor neurons controlling major longitudinal muscles overlap in more than four segments. Recordings of muscle activity during natural crawling show that some are activated during both their shortening and elongation. These results do not support the typical peristaltic model of crawling, but they do support a tension-based model of crawling, in which the substrate is utilized as an anchor to generate propulsion.

Section: A New Model For Neural Control Of Tension-based Crawlingmentioning

confidence: 99%

Motor patterns associated with crawling in a soft-bodied arthropod

Simon

Fusillo

Colman

et al. 2010

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“…Because caterpillars crawl slowly (0.241-0.310 cm s -1 on average in the present study), and forward momentum is small and episodic, there is no sustained acceleration and the effect of gravity is therefore minimized during vertical climbing. Another reason for the high costs of caterpillar locomotion is that muscles and body wall have low resilience, dissipating a large proportion of mechanical work (40-60%) during cycles of strain Dorfmann et al, 2007;Lin et al, 2008;Woods et al, 2008). This inability to store elastic energy makes caterpillar locomotion less efficient.…”

Section: Effects Of Climbing On Movementsmentioning

confidence: 99%

Kinematics of horizontal and vertical caterpillar crawling

Griethuijsen

Trimmer

2009

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SUMMARYUnlike horizontal crawling, vertical crawling involves two counteracting forces: torque rotating the body around its center of mass and gravity resisting forward movement. The influence of these forces on kinematics has been examined in the soft-bodied larval stage of Manduca sexta. We found that crawling and climbing are accomplished using the same movements, with both segment timing and proleg lift indistinguishable in horizontal and vertical locomotion. Minor differences were detected in stride length and in the delay between crawls, which led to a lower crawling speed in the vertical orientation. Although these differences were statistically significant, they were much smaller than the variation in kinematic parameters between animals. The ability of Manduca to crawl and climb using the same movements is best explained by Manduca's relatively small size, slow speed and strong, controlled, passive grip made possible by its proleg/crochets.

“…Although neither SRO length nor change in length explain the time constant of adaptation (Fig. 7C,D), we observe that SRO adaptation is similar to the adaptation of passive Manduca muscle to mechanical stimuli (Woods et al, 2008). It is possible that SRO adaptation arises from the internal mechanical properties of the stretch receptor muscle fiber.…”

Section: A Simon and B A Trimmermentioning

confidence: 60%

Movement encoding by a stretch receptor in the soft-bodied caterpillar,Manduca sexta

Simon

Trimmer

2009

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SUMMARYIn a wide variety of animals, stretch receptors provide proprioceptive feedback for motion control. However, for animals that lack a stiff skeleton, it is unclear what information is being detected and how this is incorporated into behavior. Because such animals can change their body shape from moment-to-moment, information about body configuration could be particularly important for coordination. This study uses larval stage Lepidoptera (Manduca sexta) to examine how the longitudinal stretch receptor organ (SRO) responds to behaviorally appropriate movements. We characterized the responses of the SRO to changes in strain using magnitudes and velocities matching those seen physiologically. We found that the SRO response characteristics are compatible with the regulation of stance and with the defensive response to noxious stimuli. However, we also found that movements during crawling produce SRO responses that are dominated by the interdependence of phasic, tonic and slowly adaptive components. Ablation of stretch receptors in the proleg-bearing, fourth abdominal segment did not have any observable effect on behaviors, which suggests that the SROs are not essential for coordinating overt movements. We discuss the implications of these findings in the context of specific behaviors, and explore how the SRO response might be utilized during animal behavior. Supplementary material available online at