A controllable dual-catapult system inspired by the biomechanics of the dragonfly larvae’s predatory strike

Büsse, Sebastian; Koehnsen, Alexander; Rajabi, Hamed; Gorb, Stanislav N.

doi:10.1126/scirobotics.abc8170

Cited by 21 publications

(37 citation statements)

References 52 publications

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“…This catapult mechanism is proposed here for mantis lacewings for the first time. Catapult systems are well known to operate ultra-fast predatory strikes, for example in dragonfly larvae (Büsse et al 2021), or mantis shrimps (Patek et al 2004). Here, it is functioning comparable to the described catapult systems in cicadas (Gorb 2004) or trap-jaw ants (Gronenberg 1999).…”

Section: Discussionmentioning

confidence: 99%

Functional morphology of the raptorial forelegs in Mantispa styriaca (Insecta: Neuroptera)

2021

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The insect leg is a multifunctional device, varying tremendously in form and function within Insecta: from a common walking leg, to burrowing, swimming or jumping devices, up to spinning apparatuses or tools for prey capturing. Raptorial forelegs, as predatory striking and grasping devices, represent a prominent example for convergent evolution within insects showing strong morphological and behavioural adaptations for a lifestyle as an ambush predator. However, apart from praying mantises (Mantodea)—the most prominent example of this lifestyle—the knowledge on morphology, anatomy, and the functionality of insect raptorial forelegs, in general, is scarce. Here, we show a detailed morphological description of raptorial forelegs of Mantispa styriaca (Neuroptera), including musculature and the material composition in their cuticle; further, we will discuss the mechanism of the predatory strike. We could confirm all 15 muscles previously described for mantis lacewings, regarding extrinsic and intrinsic musculature, expanding it for one important new muscle—M24c. Combining the information from all of our results, we were able to identify a possible catapult mechanism (latch-mediated spring actuation system) as a driving force of the predatory strike, never proposed for mantis lacewings before. Our results lead to a better understanding of the biomechanical aspects of the predatory strike in Mantispidae. This study further represents a starting point for a comprehensive biomechanical investigation of the convergently evolved raptorial forelegs in insects.

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Section: Discussionmentioning

confidence: 99%

Functional morphology of the raptorial forelegs in Mantispa styriaca (Insecta: Neuroptera)

2021

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“…In the larvae of damselflies and dragonflies (Insecta: Odonata), a unique prey capturing mechanism has evolved: one mouthpart, the labium, is modified into a prehensile mask (PLM) (see figure 1); capable of rapid projection for prey capturing (Corbet, 1957;Pritchard, 1965;Olesen, 1979;Büsse et al 2021). The prey spectra between larvae with these two different ecotypes of PLM differ significantly.…”

Section: Introductionmentioning

confidence: 99%

“…The PLM in general is capable of rapid protraction (Pritchard 1965;Olesen 1979;Tanaka and Hisada 1980). Powered by a dual catapult mechanism, maximum accelerations of 20g and maximum velocities of around 1 m/s have been measured (Büsse et al 2021). At high speeds, the influence of hydrodynamic forces on the movement becomes increasingly important, as substantial amounts of drag incur (Vogel 1997;McHenry et al 2016;).…”

Section: Introductionmentioning

confidence: 99%

Computational fluid dynamics provide evidence for a compensatory suction feeding like effect in the predatory strike of dragonfly larvae

Koehnsen

Brede

Gorb

et al. 2021

Preprint

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Most fast-moving aquatic predators face the challenge of bow wave formation. Water in front of predator alarms or even displaces the prey. To mitigate the formation of such a bow wave, a strategy aiming at pressure reduction via suction has evolved convergently in several animal groups: compensatory suction feeding. The aquatic larvae of dragonflies and damselflies (Insecta: Odonata) are likely to face this challenge as well. They capture prey underwater using a fast-moving raptorial appendage, the so-called prehensile labial mask. Within dragonflies (Odonata: Anisoptera) two basic shapes of the prehensile labial mask have evolved, with an either flat and slender or concave distal segment. While the former is a pure grasping device, the latter is also capable of scooping up smaller prey and retaining it inside the cavity by arrays of bristle-like structures. The hydrodynamics of the prehensile labial mask was previously unknown. We used computational fluid dynamic (CFD) simulations of the distal segment of the mask, to investigate for the first time how different shapes of the mask impact their function. Our results suggest that both shapes are highly streamlined and generate a low-pressure area, likely leading to an effect analogous to the compensatory suction feeding. This might be an interesting concept for technical application in small scale grasping devices, e.g. for simple sampling mechanisms in small-sized autonomous underwater vehicles (μAUVs).

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“…Our approach also includes non-linear and time-dependent material properties. Additionally, we provide a generalized treatment of the latch that includes friction, allows for different latch shapes, and includes an unlatching motor that drives the latch removal of the system, similar to the one recently hypothesized to occur in some biological systems [13].…”

Section: Introductionmentioning

confidence: 99%

“…Models have been developed to understand the extreme biomechanics of latch-mediated spring actuated organisms. Organism-specific models, including both continuum mechanics-based models [2][3][4][5][6][7][8][9][10] and physical modeling with biomimetic devices [2,[10][11][12][13][14], have been used to test hypotheses about the movement of specific organisms (Table I summarizes examples of recent work).…”

Section: Introductionmentioning

confidence: 99%

A Tunable, Simplified Model for Biological Latch Mediated Spring Actuated Systems

Cook

Pandhigunta

Acevedo

et al. 2020

Preprint

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We develop a model of latch-mediated spring actuated (LaMSA) systems relevant to comparative biomechanics. The model contains five components: two motors (muscles), a spring, a latch, and a load mass. One motor loads the spring to store elastic energy, and the second motor subsequently removes the latch, which releases the spring and causes movement of the load mass. We develop open-source software to accompany the model, which provides an extensible framework for simulating biological LaMSA systems. Output from the simulation includes information from the loading and release phases of motion, which can be used to calculate kinematic performance metrics that are important for biological function. By rapidly iterating through biologically relevant input parameters to the model, simulated changes in kinematic performance can be used to explore the evolutionary dynamics of biological LaMSA systems.SIGNIFICANCEIn this work, we provide an example of a simple and extensible modeling framework that is grounded in physical principles. This framework enables both the rapid testing of ideas and the flexibility of tuning the model to a specific biological system. The model and open-source software can be used to explore questions in comparative biomechanics related to spring actuated movements.

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A controllable dual-catapult system inspired by the biomechanics of the dragonfly larvae’s predatory strike

Cited by 21 publications

References 52 publications

Functional morphology of the raptorial forelegs in Mantispa styriaca (Insecta: Neuroptera)

Functional morphology of the raptorial forelegs in Mantispa styriaca (Insecta: Neuroptera)

Computational fluid dynamics provide evidence for a compensatory suction feeding like effect in the predatory strike of dragonfly larvae

A Tunable, Simplified Model for Biological Latch Mediated Spring Actuated Systems

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