Body stiffness and damping depend sensitively on the timing of muscle activation in lampreys

Tytell, Eric D.; Carr, Jennifer A.; Danos, Nicole; Wagenbach, Christopher; Sullivan, Caitlin; Kiemel, Tim; Cowan, Noah J.; Ankaralı, Mustafa Mert

doi:10.1093/icb/icy042

Cited by 35 publications

(24 citation statements)

References 59 publications

(71 reference statements)

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“…Campbell et al, 2011a,b). We generally cannot yet predict mechanical work from steady-state physiological properties, especially during perturbed conditions (Powers et al, 2018;Ahn et al, 2006;Tytell et al, 2018;Libby et al, 2020), but our results link nanometer-scale structural differences with functional differences relevant for locomotion. Under activated conditions, the spacing patterns change in part due to the action of active myosin binding and activation of other proteins, such as titin.…”

Section: Discussionmentioning

confidence: 78%

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Nanometer-scale structure differences in the myofilament lattice spacing of two cockroach leg muscles correspond to their different functions

Tune

Irving

et al. 2020

Journal of Experimental Biology

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Muscle is highly organized across multiple length scales. Consequently, small changes in the arrangement of myofilaments can influence macroscopic mechanical function. Two leg muscles of a cockroach have identical innervation, mass, twitch responses, length-tension curves and force-velocity relationships. However, during running, one muscle is dissipative (a 'brake'), while the other dissipates and produces significant positive mechanical work (bifunctional). Using time-resolved X-ray diffraction in intact, contracting muscle, we simultaneously measured the myofilament lattice spacing, packing structure and macroscopic force production of these muscles to test whether structural differences in the myofilament lattice might correspond to the muscles' different mechanical functions. While the packing patterns are the same, one muscle has 1 nm smaller lattice spacing at rest. Under isometric stimulation, the difference in lattice spacing disappeared, consistent with the two muscles' identical steady-state behavior. During periodic contractions, one muscle undergoes a 1 nm greater change in lattice spacing, which correlates with force. This is the first identified structural feature in the myofilament lattice of these two muscles that shares their whole-muscle dynamic differences and quasi-static similarities.

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Section: Discussionmentioning

confidence: 78%

“…This function versatility enables muscle's diverse roles in animal locomotion and behavior. Muscle's mechanical function can be difficult to predict, especially under perturbed conditions, because of muscle's hierarchical structure across multiple length scales (Powers et al, 2018;Ahn et al, 2006;Tytell et al, 2018).…”

Section: Introductionmentioning

confidence: 99%

Nanometer-scale structure differences in the myofilament lattice spacing of two cockroach leg muscles correspond to their different functions

Tune

Irving

et al. 2020

Journal of Experimental Biology

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“…The recognition that swimming animals create coherent structures in their wakes [7,8] has led to more detailed studies of how particular morphological features, like peduncles in whales [9] and denticles in sharks [10], can play a role in drag reduction and ultimately swimming performance. Many of these findings, including the discovery of resonance matching between body kinematics and fluid dynamics [11,12], which enables completely passive propulsion as demonstrated in dead fish [13], have important implications for the development of engineered systems, such as underwater vehicles.…”

Section: Introductionmentioning

confidence: 99%

A Computational Model for Tail Undulation and Fluid Transport in the Giant Larvacean

Hoover

Daniëls

Nawroth

et al. 2021

Fluids

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Flexible propulsors are ubiquitous in aquatic and flying organisms and are of great interest for bioinspired engineering. However, many animal models, especially those found in the deep sea, remain inaccessible to direct observation in the laboratory. We address this challenge by conducting an integrative study of the giant larvacean, an invertebrate swimmer and “fluid pump” of the mesopelagic zone. We demonstrate a workflow involving deep sea robots, advanced imaging tools, and numerical modeling to assess the kinematics and resulting fluid transport of the larvacean’s beating tail. A computational model of the tail was developed to simulate the local fluid environment and the tail kinematics using embedded passive (elastic) and active (muscular) material properties. The model examines how varying the extent of muscular activation affects the resulting kinematics and fluid transport rates. We find that muscle activation in two-thirds of the tail’s length, which corresponds to the observed kinematics in giant larvaceans, generates a greater average downstream flow speed than other designs with the same power input. Our results suggest that the active and passive material properties of the larvacean tail are tuned to produce efficient fluid transport for swimming and feeding, as well as provide new insight into the role of flexibility in biological propulsors.

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“…Under unsteady conditions, the muscle can dissipate more than 10 times the energy that it does in steady state or convert its function to that of non-linear motor (Sponberg et al, 2011a). It remains challenging to predict function from the quasi-static length-tension and forcevelocity relationships, especially under unsteady conditions (Ahn et al, 2006;Sponberg et al, 2011a;Daley and Biewener, 2011;Tytell et al, 2018). Nonetheless, such conditions likely pose greater performance demands than steady state (Biewener and Daley, 2007).…”

Section: Introductionmentioning

confidence: 99%

“…However, perturbations around dynamic (time periodic or unsteady) conditions can create even more unexpected shifts in muscle performance (Robertson and Sawicki, 2015;Tytell et al, 2018). During running, muscle can experience large and rapid perturbations against a background strain trajectory where history has the potential to alter function Sponberg et al, 2011b).…”

Section: Introductionmentioning

confidence: 99%

History-dependent perturbation response in limb muscle

Libby

Chukwueke

Sponberg

2019

Journal of Experimental Biology

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Muscle mediates movement but movement is typically unsteady and perturbed. Muscle is known to behave non-linearly and with historydependent properties during steady locomotion, but the importance of history dependence in mediating muscle function during perturbations remains less clear. To explore the capacity of muscles to mitigate perturbations during locomotion, we constructed a series of perturbations that varied only in kinematic history, keeping instantaneous position, velocity and time from stimulation constant. We found that the response of muscle to a perturbation is profoundly history dependent, varying 4-fold as baseline frequency changes, and dissipating energy equivalent to ∼6 times the kinetic energy of all the limbs in 5 ms (nearly 2400 W kg −1 ). Muscle energy dissipation during a perturbation is predicted primarily by the force at the onset of the perturbation. This relationship holds across different frequencies and timings of stimulation. This history dependence behaves like a viscoelastic memory producing perturbation responses that vary with the frequency of the underlying movement.

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Body stiffness and damping depend sensitively on the timing of muscle activation in lampreys

Cited by 35 publications

References 59 publications

Nanometer-scale structure differences in the myofilament lattice spacing of two cockroach leg muscles correspond to their different functions

Nanometer-scale structure differences in the myofilament lattice spacing of two cockroach leg muscles correspond to their different functions

A Computational Model for Tail Undulation and Fluid Transport in the Giant Larvacean

History-dependent perturbation response in limb muscle

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