An insect-inspired asymmetric hinge in a double-layer membrane

Rajabi, Hamed; Eraghi, Sepehr H.; Khaheshi, Ali; Toofani, Arman; Hunt, Cherryl; Wootton, Robin J.

doi:10.1073/pnas.2211861119

Cited by 7 publications

(7 citation statements)

References 48 publications

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“…When we approach nature from an engineering perspective and focus on the mechanical design of natural systems, we uncover collective mechanical behaviours and emergent mechanical properties resulting from their specialized design. For example, observations of snake locomotion systems [9][10][11], fish body armours [12][13][14], gecko adhesive pads [15][16][17][18], insect flight systems [19][20][21][22][23][24], beetle fighting mechanisms [25,26] and many more indicate that natural mechanical systems consist of complicated material composition, nano-and micro-architecture and structural elements. This complicatedness can arise from two underlying design principles:…”

Section: Introductionmentioning

confidence: 99%

Complexity biomechanics: a case study of dragonfly wing design from constituting composite material to higher structural levels

Toofani,

Eraghi,

Basti

et al. 2024

Interface Focus.

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Presenting a novel framework for sustainable and regenerative design and development is a fundamental future need. Here we argue that a new framework, referred to as complexity biomechanics, which can be used for holistic analysis and understanding of natural mechanical systems, is key to fulfilling this need. We also present a roadmap for the design and development of intelligent and complex engineering materials, mechanisms, structures, systems, and processes capable of automatic adaptation and self-organization in response to ever-changing environments. We apply complexity biomechanics to elucidate how the different structural components of a complex biological system as dragonfly wings, from ultrastructure of the cuticle, the constituting bio-composite material of the wing, to higher structural levels, collaboratively contribute to the functionality of the entire wing system. This framework not only proposes a paradigm shift in understanding and drawing inspiration from natural systems but also holds potential applications in various domains, including materials science and engineering, biomechanics, biomimetics, bionics, and engineering biology.

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Section: Introductionmentioning

confidence: 99%

Complexity biomechanics: a case study of dragonfly wing design from constituting composite material to higher structural levels

Toofani,

Eraghi,

Basti

et al. 2024

Interface Focus.

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“…[ 1 ] Understanding the complex morphology of insect wings is not merely an academic pursuit in multiple scientific domains, such as biomechanics, animal behavior, physiology, and ecology, [ 2–7 ] but an inspiration for innovative technologies in the field of engineering. These include the development of robust load‐bearing structures, [ 8–10 ] bioinspired joints, [ 11–14 ] insect‐inspired hinges, [ 15 ] bioinspired wing, [ 16,17 ] insect‐inspired composites, [ 18,19 ] bioinspired attachment strategies, [ 20–22 ] and bioinspired grippers. [ 23 ]…”

Section: Introductionmentioning

confidence: 99%

“…[1] Understanding the complex morphology of insect wings is not merely an academic pursuit in multiple scientific domains, such as biomechanics, animal behavior, physiology, and ecology, [2][3][4][5][6][7] but an inspiration for innovative technologies in the field of engineering. These include the development of robust load-bearing structures, [8][9][10] bioinspired joints, [11][12][13][14] insect-inspired hinges, [15] bioinspired wing, [16,17] insectinspired composites, [18,19] bioinspired attachment strategies, [20][21][22] and bioinspired grippers. [23] As our understanding of the wing structures deepens, manual analysis methods face challenges in accurately capturing the complex geometric features to characterize wing morphology [24,25] comprehensively.…”

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confidence: 99%

WingSegment: A Computer Vision‐Based Hybrid Approach for Insect Wing Image Segmentation and 3D Printing

Eshghi,

Rajabi,

Poser

et al. 2024

Advanced Intelligent Systems

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This article introduces WingSegment, a MATLAB app‐designed tool employing a hybrid approach of computer vision and graph theory for precise insect wing image segmentation. WingSegment detects cells, junctions, Pterostigma, and venation patterns, measuring geometric features and generating Voronoi patterns. The tool utilizes region‐growing, thinning, and Dijkstra's algorithms for boundary detection, junction identification, and vein path extraction. It provides histograms and box plots of geometric features, facilitating comprehensive wing analysis. WingSegment's efficiency is validated through comparisons with established tools and manual measurements, demonstrating accurate results. The tool further enables exporting detected boundaries as FreeCAD macro files for 3D modeling and printing, supporting finite element analysis. Beyond advancing insect wing morphology understanding, WingSegment holds broader implications for diverse planar structures, including leaves and geocells. This tool not only enhances automated geometric analysis and 3D model generation in insect wing studies but also contributes to the broader advancement of analysis, 3D printing, and modeling technologies across various planar structures.

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“…[14][15][16][17][18] Understanding the scaling relationships between these parameters can provide insights into the mechanics of the wing and potentially inspire the development of bio-inspired materials and systems. [19][20][21][22][23] Previous studies have suggested that different Odonata species show different wing length allometries, meaning that the wing size changes at a different rate than the overall body size. [24][25][26] Other studies also suggest that the size of cells in the locust wing relates to the critical crack length, and the cellular structure of the insect wing is a crack resistance strategy to increase durability.…”

Section: Introductionmentioning

confidence: 99%

Allometric Scaling Reveals Evolutionary Constraint on Odonata Wing Cellularity via Critical Crack Length

Eshghi,

Rajabi,

Shafaghi

et al. 2024

Advanced Science

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Scaling in insect wings is a complex phenomenon that seems pivotal in maintaining wing functionality. In this study, the relationship between wing size and the size, location, and shape of wing cells in dragonflies and damselflies (Odonata) is investigated, aiming to address the question of how these factors are interconnected. To this end, WingGram, the recently developed computer‐vision‐based software, is used to extract the geometric features of wing cells of 389 dragonflies and damselfly wings from 197 species and 16 families. It has been found that the cell length of the wings does not depend on the wing size. Despite the wide variation in wing length (8.42 to 56.5 mm) and cell length (0.1 to 8.5 mm), over 80% of the cells had a length ranging from 0.5 to 1.5 mm, which was previously identified as the critical crack length of the membrane of locust wings. An isometric scaling of cells is also observed with maximum size in each wing, which increased as the size increased. Smaller cells tended to be more circular than larger cells. The results have implications for bio‐mimetics, inspiring new materials and designs for artificial wings with potential applications in aerospace engineering and robotics.

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An insect-inspired asymmetric hinge in a double-layer membrane

Cited by 7 publications

References 48 publications

Complexity biomechanics: a case study of dragonfly wing design from constituting composite material to higher structural levels

Complexity biomechanics: a case study of dragonfly wing design from constituting composite material to higher structural levels

WingSegment: A Computer Vision‐Based Hybrid Approach for Insect Wing Image Segmentation and 3D Printing

Allometric Scaling Reveals Evolutionary Constraint on Odonata Wing Cellularity via Critical Crack Length

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