Insects running on elastic surfaces

Spence, Andrew J.; Revzen, Shai; Seipel, Justin; Mullens, Chris; Full, Robert J.

doi:10.1242/jeb.042515

Cited by 74 publications

(69 citation statements)

References 67 publications

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“…The small moment created by the rising arm of the backpack did not produce roll motions outside the range of those reported in previous experiments [5]. Backpacks were calibrated and accelerations were corrected for gravity using the kinematic tracking to define the relative orientation of the backpack with respect to the gravity vector at each point in time [46]. We off-loaded acceleration data from the backpack via an approximately 0.5 m tether of 50 mm wires attached to a data acquisition board (National Instruments, BNC 2090, Austin, TX, USA).…”

Section: Methods (A) Animalsmentioning

confidence: 95%

“…We placed retroreflective markers on five balsa wood arms projecting from the backpack and tracked them with high-speed videography at 500 fps (AOS Technologies AG, Switzerland). Fitting the five digitized points in a two-dimensional camera view to a geometric model of the arms' configuration enabled three-dimensional reconstruction of the animal's pitch, roll and yaw [46]. We report yaw velocity changes instead of yaw, because the cockroach's heading was not fixed within the arena and angular velocity was more comparable across trials.…”

Section: Methods (A) Animalsmentioning

confidence: 99%

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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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Section: Methods (A) Animalsmentioning

confidence: 95%

Section: Methods (A) Animalsmentioning

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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“…However, when startled, even deafferented cockroaches were capable of sustaining a fast tripod trot. In addition, a body of literature shows that running cockroaches do not readily adapt their leg motions to the shape of the substrate (Jindrich and Full, 1999;Jindrich and Full, 2002;Sponberg and Full, 2008;Spence et al, 2010). In particular, it has been suggested that feedback is too slow to be useful to a sprinting animal, at least within a single stride .This distinction between the importance of afferent feedback in coordinating a slower gait and its apparent irrelevance to faster running could provide a simple explanation for our observations, and one that also resolves the dilemma of how a walking insect uses both CPGs and feedback in gait control.…”

Section: Gait Controlmentioning

confidence: 99%

Kinematic and behavioral evidence for a distinction between trotting and ambling gaits in the cockroachBlaberus discoidalis

Bender

Simpson

Tietz

et al. 2011

Journal of Experimental Biology

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SUMMARYEarlier observations had suggested that cockroaches might show multiple patterns of leg coordination, or gaits, but these were not followed by detailed behavioral or kinematic measurements that would allow a definite conclusion. We measured the walking speeds of cockroaches exploring a large arena and found that the body movements tended to cluster at one of two preferred speeds, either very slow (<10cms ). To highlight the neural control of walking leg movements, we experimentally reduced the mechanical coupling among the various legs by tethering the animals and allowing them to walk in place on a lightly oiled glass plate. Under these conditions, the rate of stepping was bimodal, clustering at fast and slow speeds. We next used high-speed videos to extract three-dimensional limb and joint kinematics for each segment of all six legs. The angular excursions and three-dimensional motions of the leg joints over the course of a stride were variable, but had different distributions in each gait. The change in gait occurs at a Froude number of ~0.4, a speed scale at which a wide variety of animals show a transition between walking and trotting. We conclude that cockroaches do have multiple gaits, with corresponding implications for the collection and interpretation of data on the neural control of locomotion. Supplementary material available online at

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“…Although spring-mass-like CoM motion was observed only in some of these studies (Ferris et al, 1998;Moritz and Farley, 2003;Spence et al, 2010), a common finding is that on non-solid surfaces, limbs do not necessarily behave like springs to save energy. In addition, these studies suggest that both the active control of body and limb movement through the nervous system and the passive mechanical responses of viscoelastic limbs and feet with the environment play important roles in the The zebra-tailed lizard [Callisaurus draconoides Blainville 1835; snout-vent length (SVL) ~10cm, mass ~10g; Fig.1A] is an excellent model organism for studying running on natural surfaces because of its high locomotor performance over diverse terrain.…”

Section: Introductionmentioning

confidence: 98%

“…Laboratory experiments have begun to reveal mechanisms of organisms running on non-solid surbstrates, such as elastic (Ferris et al, 1998;Spence et al, 2010), damped (Moritz and Farley, 2003), inclined (Roberts et al, 1997) or uneven (Daley and Biewener, 2006;Sponberg and Full, 2008) surfaces, surfaces with few footholds (Spagna et al, 2007) and the surface of water (Glasheen and McMahon, 1996a;Hsieh, 2003). Although spring-mass-like CoM motion was observed only in some of these studies (Ferris et al, 1998;Moritz and Farley, 2003;Spence et al, 2010), a common finding is that on non-solid surfaces, limbs do not necessarily behave like springs to save energy.…”

Section: Introductionmentioning

confidence: 99%

Multi-functional foot use during running in the zebra-tailed lizard (Callisaurus draconoides)

Hsieh

Goldman

2012

Journal of Experimental Biology

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SUMMARYA diversity of animals that run on solid, level, flat, non-slip surfaces appear to bounce on their legs; elastic elements in the limbs can store and return energy during each step. The mechanics and energetics of running in natural terrain, particularly on surfaces that can yield and flow under stress, is less understood. The zebra-tailed lizard (Callisaurus draconoides), a small desert generalist with a large, elongate, tendinous hind foot, runs rapidly across a variety of natural substrates. We use high-speed video to obtain detailed three-dimensional running kinematics on solid and granular surfaces to reveal how leg, foot and substrate mechanics contribute to its high locomotor performance. Running at ~10bodylengthss -1 (~1ms), the center of mass oscillates like a spring-mass system on both substrates, with only 15% reduction in stride length on the granular surface. On the solid surface, a strut-spring model of the hind limb reveals that the hind foot saves ~40% of the mechanical work needed per step, significant for the lizardʼs small size. On the granular surface, a penetration force model and hypothesized subsurface foot rotation indicates that the hind foot paddles through fluidized granular medium, and that the energy lost per step during irreversible deformation of the substrate does not differ from the reduction in the mechanical energy of the center of mass. The upper hind leg muscles must perform three times as much mechanical work on the granular surface as on the solid surface to compensate for the greater energy lost within the foot and to the substrate. Supplementary material available online at

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Insects running on elastic surfaces

Cited by 74 publications

References 67 publications

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

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

Kinematic and behavioral evidence for a distinction between trotting and ambling gaits in the cockroachBlaberus discoidalis

Multi-functional foot use during running in the zebra-tailed lizard (Callisaurus draconoides)

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