<i>In situ</i>muscle power differs without varying<i>in vitro</i>mechanical properties in two insect leg muscles innervated by the same motor neuron

Ahn, Anna; Meijer, Kenneth

doi:10.1242/jeb.02392

Cited by 38 publications

(78 citation statements)

References 40 publications

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“…A3 VIL, in contrast, dissipates most of the energy used to extend it, whether in sinusoidal strain cycling (Figs·4, 6) or during simulated natural crawling (Figs·11, 12), a property associated in locomotory structures of other organisms with maintenance of stability (Biewener and Roberts, 2000;Dudek and Full, 2006;Hof, 2003;Jindrich and Full, 2002;Marsh, 1999), by means of preflex rather than CNS-dependent reflex (Campbell and Kirkpatrick, 2001;Cham et al, 2000;Chen et al, 2006;Dickinson et al, 2000;Seipel et al, 2004). Although muscles of like mechanical qualities in vitro can have markedly different mechanical outputs in vivo (Ahn et al, 2006), the visual similarity of fibers in all M. sexta larval muscles at least raises the possibility that this low resilience may be a general characteristic of caterpillar muscles. Efficiency of caterpillar locomotion is very low (Casey, 1991), but given the growth-oriented role of the larval stage, locomotory efficiency may be unimportant; caterpillars allocate far more of their energy uptake to tissue production than to activity (Schowalter et al, 1977;Scriber, 1977).…”

Section: Mechanical Properties and Dynamic Functionmentioning

confidence: 99%

Dynamic properties of a locomotory muscle of the tobacco hornwormManduca sextaduring strain cycling and simulated natural crawling

Woods

Fusillo

Trimmer

2008

Journal of Experimental Biology

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SUMMARYCaterpillars are soft-bodied terrestrial climbers that perform a wide variety of complex movements with several hundred muscles and a relatively small number of neurons. Control of movements is therefore expected to place unusual demands on the mechanical properties of the muscles. The muscles develop force slowly (1-6·s to peak) yet over a strain range extending from under 60% to more than 160% of resting length, with a length-tension relationship resembling that of supercontracting or cross-striated muscle. In passive and active sinusoidal strain cycling, muscles displayed viscoelastic qualities, with very low and stretch-velocity dependent resilience; there was a positive linear relationship between stretch velocity and the fraction of work dissipation attributable to passive muscle properties (20-80%). In linear stretches of unstimulated muscles at velocities bracketing those encountered in natural crawling, the rise in tension showed a distinct transition to a lower rate of increase, with transition tension dependent upon stretch velocity; peak force was exponentially related to stretch velocity. When stretching ceased, force decayed exponentially, with slower decay associated with lower stretch velocities; the decay time constant was exponentially related to stretch velocity. From the kinematics of caterpillars crawling horizontally we determined that the ventral interior lateral muscle (VIL) of the third abdominal segment (A3) is at or near resting length for most of the crawl cycle, with a fairly linear shortening by 25-30% and re-lengthening occupying about 45% of cycle duration. Synchronized kinematic and EMG recordings showed that during horizontal crawling A3 VIL is stimulated as the muscle shortens from about 95% to 75% of its resting length. We subjected in vitro VIL preparations to strain cycling and stimulus phase and duration similar to that of natural crawling. The resulting work loops were figure-eight shaped, with the muscle performing work during the shortest 45-65% of the strain cycle but dissipating work during the rest of the cycle. The muscle remained in the ascending limb of its length-tension relationship throughout the crawl cycle. Peak force occurred at the end of re-lengthening, nearly a full second after stimulation ceased, underscoring the importance of understanding passive muscle properties to explain caterpillar locomotion. Whether A3 VIL functions as an actuator at all during simulated natural strain cycling is highly sensitive to stimulus timing but far less so to stimulus duration. The muscleʼs elastomer-like properties appear to play a major role in its function.

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Section: Mechanical Properties and Dynamic Functionmentioning

confidence: 99%

Dynamic properties of a locomotory muscle of the tobacco hornwormManduca sextaduring strain cycling and simulated natural crawling

Woods

Fusillo

Trimmer

2008

Journal of Experimental Biology

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“…The cockroach Blaberus discoidalis possesses a pair of dorsal/ventral femoral extensors 1 (178 and 179) (Carbonell, 1947) that are putative control muscles and innervated only by a single fast motor neuron (Df) (Pearson and Iles, 1971;Pipa and Cook, 1959). A single action potential in Df produces one, relatively large MAP in its target muscles, resulting in nearly identical patterns of activation in both extensors muscles (Ahn et al, 2006;Full et al, 1998;Watson and Ritzmann, 1995). When first recruited during running, these femoral extensors have been hypothesized to shorten the transition from flexion to extension and possibly increase joint angular velocity at higher speeds (Levi and Camhi, 1996;Watson and Ritzmann, 1998b).…”

Section: Introductionmentioning

confidence: 99%

Neuromechanical response of musculo-skeletal structures in cockroaches during rapid running on rough terrain

Sponberg

Full

2008

Journal of Experimental Biology

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188

243

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SUMMARYA musculo-skeletal structure can stabilize rapid locomotion using neural and/or mechanical feedback. Neural feedback results in an altered feedforward activation pattern, whereas mechanical feedback using visco-elastic structures does not require a change in the neural motor code. We selected musculo-skeletal structures in the cockroach (Blaberus discoidalis) because their single motor neuron innervation allows the simplest possible characterization of activation. We ran cockroaches over a track with randomized blocks of heights up to three times the animalʼs ʻhipʼ (1.5·cm), while recording muscle action potentials (MAPs) from a set of putative control musculo-skeletal structures (femoral extensors 178 and 179). Animals experienced significant perturbations in body pitch, roll and yaw, but reduced speed by less than 20%. Surprisingly, we discovered no significant difference in the distribution of the number of MAPs, the interspike interval, burst phase or interburst period between flat and rough terrain trials. During a few very large perturbations or when a single leg failed to make contact throughout stance, neural feedback was detectable as a phase shift of the central rhythm and alteration of MAP number. System level responses of appendages were consistent with a dominant role of mechanical feedback. Duty factors and gait phases did not change for cockroaches running on flat versus rough terrain. Cockroaches did not use a follow-the-leader gait requiring compensatory corrections on a step-by-step basis. Arthropods appear to simplify control on rough terrain by rapid running that uses kinetic energy to bridge gaps between footholds and distributed mechanical feedback to stabilize the body.

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“…While correlating muscle activation changes and dynamics across a variety of perturbations can suggest causal relationships, and careful biomechanical models can offer potential explanations [25,[29][30][31], it is necessary to test these hypotheses with direct experimentation in the intact, behaving animal. This is especially true during dynamic behaviours where it is difficult to predict a muscle's function from anatomy alone or even a careful examination of its in situ physiological properties [16,32,33].…”

Section: Introductionmentioning

confidence: 99%

A single muscle's multifunctional control potential of body dynamics for postural control and running

Sponberg

Spence

Mullens

et al. 2011

Phil. Trans. R. Soc. B

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A neuromechanical approach to control requires understanding how mechanics alters the potential of neural feedback to control body dynamics. Here, we rewrite activation of individual motor units of a behaving animal to mimic the effects of neural feedback without concomitant changes in other muscles. We target a putative control muscle in the cockroach, Blaberus discoidalis (L.), and simultaneously capture limb and body dynamics through high-speed videography and a microaccelerometer backpack. We test four neuromechanical control hypotheses. We supported the hypothesis that mechanics linearly translates neural feedback into accelerations and rotations during static postural control. However, during running, the same neural feedback produced a nonlinear acceleration control potential restricted to the vertical plane. Using this, we reject the hypothesis from previous work that this muscle acts primarily to absorb energy from the body. The conversion of the control potential is paralleled by nonlinear changes in limb kinematics, supporting the hypothesis that significant mechanical feedback filters the graded neural feedback for running control. Finally, we insert the same neural feedback signal but at different phases in the dynamics. In this context, mechanical feedback enables turning by changing the timing and direction of the accelerations produced by the graded neural feedback.

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In situmuscle power differs without varyingin vitromechanical properties in two insect leg muscles innervated by the same motor neuron

Cited by 38 publications

References 40 publications

Dynamic properties of a locomotory muscle of the tobacco hornwormManduca sextaduring strain cycling and simulated natural crawling

Dynamic properties of a locomotory muscle of the tobacco hornwormManduca sextaduring strain cycling and simulated natural crawling

Neuromechanical response of musculo-skeletal structures in cockroaches during rapid running on rough terrain

A single muscle's multifunctional control potential of body dynamics for postural control and running

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