The comparative hydrodynamics of rapid rotation by predatory appendages

McHenry, Matthew J.; Anderson, Philip S. L.; Wassenbergh, Sam Van; Matthews, David G.; Summers, Adam P.; Patek, S. N.

doi:10.1242/jeb.140590

Cited by 34 publications

(36 citation statements)

References 50 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…These sampling and acquisition rates are not sufficient to resolve a single meral-V unloading event. Such tests are also challenged by imposing realistic forces on the elastic mechanism that would occur in the natural contexts for the movement, such as fluid dynamic forces on rotating appendages of mantis shrimp (McHenry et al, 2012(McHenry et al, , 2016.…”

Section: Spring Actuationmentioning

confidence: 99%

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

103

View full text Add to dashboard Cite

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.

show abstract

Section: Spring Actuationmentioning

confidence: 99%

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

103

View full text Add to dashboard Cite

show abstract

“…We measured strike energy during contests and feeding through a combination of kinematic measurements and a previously published mathematical model of the mantis shrimp strikes (McHenry et al, 2012). This model equates the elastic potential energy of the raptorial appendage prior to a strike (as determined by spring energy storage and linkage mechanics; McHenry et al, 2012;Patek et al, 2013;Zack et al, 2009) with the kinetic energy of the strike (determined by fluid mechanics; McHenry et al, 2016). We begin this section with a brief overview of the mathematical model (see also Fig.…”

Section: Measurement and Modeling Of Strike Energeticsmentioning

confidence: 99%

“…We begin this section with a brief overview of the mathematical model (see also Fig. 3) and advise the reader to consult McHenry et al (2012McHenry et al ( , 2016 for the full expression of and rationale for the mathematical model.…”

Section: Measurement and Modeling Of Strike Energeticsmentioning

confidence: 99%

“…Simultaneously, merus flexor muscles engage latches (modified apodemes) that prevent distal rotation of the striking body (defined as the combined propodus and dactyl segments that serve as a hammer) while the spring is loaded. Upon latch release, the spring's elastic potential energy transitions to kinetic energy, such that work is performed to rotate the striking body toward its target and to resist drag forces (for detailed descriptions of the strike mechanism, see Burrows, 1969;Burrows and Hoyle, 1972;Cox et al, 2014;McHenry et al, 2012McHenry et al, , 2016McNeill et al, 1972;Patek et al, 2004Patek et al, , 2007Patek et al, , 2013Rosario and Patek, 2015;Zack et al, 2009). Strike duration is so short that smashing mantis shrimp must use open loop control: in order to vary kinematic output, they adjust elastic energy storage prior to striking by compressing the spring to different displacements (Kagaya and Patek, 2016).…”

Section: Introductionmentioning

confidence: 99%

“…Increased extensor muscle activity causes greater shortening of the compression spring, thereby storing more elastic energy and resulting in a higher angular velocity of the strike (Kagaya and Patek, 2016). These studies, along with the development of a vetted mathematical model of strike energetics (McHenry et al, 2016(McHenry et al, , 2012, allow for measurements of strike kinematics to be connected with two types of energy: elastic energy storage (input) and combined strike kinetic and drag energy (output).…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Context-dependent scaling of kinematics and energetics during contests and feeding in mantis shrimp

Green

McHenry

Patek

2019

Journal of Experimental Biology

Self Cite

View full text Add to dashboard Cite

Measurements of energy use, and its scaling with size, are critical to understanding how organisms accomplish myriad tasks. For example, energy budgets are central to game theory models of assessment during contests and underlie patterns of feeding behavior. Clear tests connecting energy to behavioral theory require measurements of the energy use of single individuals for particular behaviors. Many species of mantis shrimp (Stomatopoda: Crustacea) use elastic energy storage to power high-speed strikes that they deliver to opponents during territorial contests and to hardshelled prey while feeding. We compared the scaling of strike kinematics and energetics between feeding and contests in the mantis shrimp Neogonodactylus bredini. We filmed strikes with highspeed video, measured strike velocity and used a mathematical model to calculate strike energy. During contests, strike velocity did not scale with body size but strike energy scaled positively with size. Conversely, while feeding, strike velocity decreased with increasing size and strike energy did not vary according to body size. Individuals most likely achieved this strike variation through differential compression of their exoskeletal spring prior to the strike. Post hoc analyses found that N. bredini used greater velocity and energy when striking larger opponents, yet variation in prey size was not accompanied by varying strike velocity or energetics. Our estimates of energetics inform prior tests of contest and feeding behavior in this species. More broadly, our findings elucidate the role behavioral context plays in measurements of animal performance.

show abstract

Braking slows passive flexion during goal-directed movements of a small limb

Rossoni

Niven

2022

Current Biology

View full text Add to dashboard Cite

The comparative hydrodynamics of rapid rotation by predatory appendages

Cited by 34 publications

References 50 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

Context-dependent scaling of kinematics and energetics during contests and feeding in mantis shrimp

Braking slows passive flexion during goal-directed movements of a small limb

Contact Info

Product

Resources

About