Extremely fast feeding strikes are powered by elastic recoil in a seahorse relative, the snipefish,<i>Macroramphosus scolopax</i>

Longo, Sarah J.; Goodearly, Tyler; Wainwright, Peter C.

doi:10.1098/rspb.2018.1078

Cited by 24 publications

(41 citation statements)

References 35 publications

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“…In the latched conformation during spring loading, the head cannot be raised. With a slight shift in geometric conformation, the torque reverses on the lower linkages, and enables the release of stored elastic energy to drive rapid head elevation (Longo et al, 2018). with high force, not with high power.…”

Section: ) Power Amplificationmentioning

confidence: 99%

“…As with springs, initial hypotheses for latch mechanisms emerge from direct observations of moving structures in or on the organism. This is often coupled with morphological descriptions, ranging from dissections to micro-computed tomography (Evans, 1972;Patek et al, 2007;Larabee et al, 2017;Longo et al, 2018). While these descriptive approaches can be compelling, additional evidence is required to discriminate among hypothesized latch mechanisms.…”

Section: Latch Mediationmentioning

confidence: 99%

“…Some fluidic latches can be detected as a pressure increase prior to movement followed by a rapid decrease once movement begins (Singh et al, 2011). Geometric latches can be inferred by demonstrating shifts in mechanical advantage or the direction of torques that occur during different phases of movement (Astley and Roberts, 2014;Kaji et al, 2018;Longo et al, 2018).…”

Section: Latch Mediationmentioning

confidence: 99%

“…With a contact latch, the shape and removal speed of the latch strongly influence system output (Ilton et al, 2018;Bolmin et al, 2019); however, tribological analyses of contact latches are still needed. Parameters such as droplet surface separation or rupture force are relevant for fluidic latches (Noblin et al, 2009;Liu et al, 2017), whereas linkage lengths and mechanical advantage are important for geometric latches (Koh et al, 2013;Longo et al, 2018;Olberding et al, 2019). It is as yet unknown which geometries, materials or dynamic features characterize effective latches and their roles across different situations.…”

Section: Latch Mediationmentioning

confidence: 99%

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Beyond power amplification: latch-mediated spring actuation is an emerging framework for the study of diverse elastic systems

Longo

Cox

Azizi

et al. 2019

Journal of Experimental Biology

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108

118

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Rapid biological movements, such as the extraordinary strikes of mantis shrimp and accelerations of jumping insects, have captivated generations of scientists and engineers. These organisms store energy in elastic structures (e.g. springs) and then rapidly release it using latches, such that movement is driven by the rapid conversion of stored elastic to kinetic energy using springs, with the dynamics of this conversion mediated by latches. Initially drawn to these systems by an interest in the muscle power limits of small jumping insects, biologists established the idea of power amplification, which refers both to a measurement technique and to a conceptual framework defined by the mechanical power output of a system exceeding muscle limits. However, the field of fast elastically driven movements has expanded to encompass diverse biological and synthetic systems that do not have musclessuch as the surface tension catapults of fungal spores and launches of plant seeds. Furthermore, while latches have been recognized as an essential part of many elastic systems, their role in mediating the storage and release of elastic energy from the spring is only now being elucidated. Here, we critically examine the metrics and concepts of power amplification and encourage a framework centered on latch-mediated spring actuation (LaMSA). We emphasize approaches and metrics of LaMSA systems that will forge a pathway toward a principled, interdisciplinary field.

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Section: ) Power Amplificationmentioning

confidence: 99%

Section: Latch Mediationmentioning

confidence: 99%

Section: Latch Mediationmentioning

confidence: 99%

Section: Latch Mediationmentioning

confidence: 99%

See 2 more Smart Citations

Beyond power amplification: latch-mediated spring actuation is an emerging framework for the study of diverse elastic systems

Longo

Cox

Azizi

et al. 2019

Journal of Experimental Biology

Self Cite

108

118

View full text Add to dashboard Cite

show abstract

“…Many changes accompany adaptation to a novel 55 niche, and previous studies have identified that shifts in behaviors (Bowman and Billeb 1965; Shifts in kinematic traits-particularly those which affect prey capture and feeding-are 61 especially promising, because they can provide biomechanical insights into the origins of novel 62 trophic niches. For example, some species of trap-jaw ants have evolved specialized latch, 63 spring, and trigger structures in their jaws which allow for rapid, power-amplified bites used to 64 capture prey items unavailable to other ant species (Patek et al 2006; Larabee and Suarez 2014); 65 power-amplified jaws in Syngnathiform fishes have evolved two different latch mechanisms for 66 specialization on evasive prey items (Longo et al 2018); and the Pacific leaping blenny (Alticus 67 arnoldorum) uniquely uses axial tail twisting to improve propulsion and stability for greater 68 jumping performance and terrestrial prey capture (Hsieh 2010). 69…”

Section: Introduction 53mentioning

confidence: 99%

Rapid adaptive evolution of scale-eating kinematics to a novel ecological niche

John

Holzman

Martin

2019

Preprint

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31Adaptation to novel ecological niches often includes shifts in behaviors, such as new foraging 32 preferences or changes in kinematics. Investigating prey capture kinematics is an excellent way 33 to understand behavioral mechanisms underlying the origins of novel trophic specialization, in 34 which organisms begin to exploit novel resources. We investigated the contribution of 35 kinematics to the origins of a novel ecological niche for scale-eating within a microendemic 36 adaptive radiation of pupfishes on San Salvador Island, Bahamas. We compared the feeding 37 kinematics of scale-eating, generalist, snail-eating, and F1 hybrid pupfishes while they consumed 38 scales and shrimp in the lab and compared them to scale-eating kinematics observed in situ in the 39 wild. We then connected variation in feeding kinematics to scale-biting performance by 40 measuring the area removed per strike from standardized gelatin cubes. We found that scale-41 eating pupfish exhibited divergent feeding kinematics compared to all other groups and that 42 these differences were consistent across food items. The peak gapes of scale-eaters were twice as 43 large as all other groups, but their gape angles were simultaneously 32% smaller, in both 44 laboratory and in situ wild observations. We also show that this kinematic combination of large 45 peak gape and small gape angle resides on a performance optimum for scale-biting. Finally, F1 46 hybrid kinematics and performance were not additive, and were instead closer to the generalist 47 pupfish. This suggests that impaired hybrid performance in the scale-eating niche may contribute 48 to extrinsic postzygotic reproductive isolation between species. Ultimately, our results suggest 49 that shifts in kinematics (i.e. peak gape and gape angle) are an adaptation to the novel niche of 50 scale-eating and contribute to reproductive isolation between species. 51 52

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Spatial and temporal changes in buccal pressure during prey-capture in the trumpetfish (Aulostomus maculatus)

2019

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Extremely fast feeding strikes are powered by elastic recoil in a seahorse relative, the snipefish,Macroramphosus scolopax

Cited by 24 publications

References 35 publications

Beyond power amplification: latch-mediated spring actuation is an emerging framework for the study of diverse elastic systems

Beyond power amplification: latch-mediated spring actuation is an emerging framework for the study of diverse elastic systems

Rapid adaptive evolution of scale-eating kinematics to a novel ecological niche

Spatial and temporal changes in buccal pressure during prey-capture in the trumpetfish (Aulostomus maculatus)

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