Sticking to it: testing passive pull-off forces in waterfall-climbing fishes across challenging substrates

Palecek, Amanda; Schoenfuss, Heiko L.; Blob, Richard W.

doi:10.1242/jeb.228718

Cited by 7 publications

(8 citation statements)

References 56 publications

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“…This exceptional performance is attributed to the hierarchically structured papillae around the edge of disc margin, which interlock with rough asperities and seal the disc as it is pulled [4,13,15]. Similar research has been conducted within different groups, including gobies [5,16], remora [17,18] and loaches [19,20], with each study highlighting the importance of contact area, sealing, and friction for performance on diverse surfaces.…”

Section: Introductionmentioning

confidence: 83%

“…For shear performance, we considered the peak force attained during the shear pull, corresponding to a static load reached as the cup slid (figure 4(a)). Previous shear studies using fish [5] and bioinspired discs [24] used similar methods of considering peak force. Shear stress (kPa) was calculated from the peak force (N) divided by the area of the fully-engaged suction cup (cm 2 ).…”

Section: Robotic Arm Shear Testsmentioning

confidence: 99%

“…Attachment mechanisms such as suction, bioadhesives, and frictional elements can stabilize these organisms against forces introduced through crashing waves, strong directional flows, and predation [1][2][3]. In particular, the use of suction organs for aquatic adhesion has been described in multiple groups including various fish [2,4,5], cephalopods [6,7], and even freshwater insects [8][9][10][11].…”

Section: Introductionmentioning

confidence: 99%

“…Despite the great interest in the adhesive capabilities of these organisms, there are still avenues of research that remain largely unexplored. For example, it is primarily understood that bony elements within the disc provide rigidity, derived from modified structures such as paired pelvic and pectoral girdles (clingfish) [14,15], pelvic fin rays (gobies) [5,21], and dorsal fins (remoras) [17,22]. However, less is known about how the morphological diversity of such structures affects adhesion.…”

Section: Introductionmentioning

confidence: 99%

“…stiffness, shape) may affect adhesive performance. However, comparative studies focusing on these requirements within aquatic adhesion has been somewhat limited, with only more recent studies exploring performance across multiple species [5,14,16].…”

Section: Introductionmentioning

confidence: 99%

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Stickiness in shear: stiffness, shape, and sealing in bioinspired suction cups affect shear performance on diverse surfaces

Hernandez,

Sandoval,

Yuen

et al. 2024

Bioinspir. Biomim.

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Aquatic organisms utilizing attachment often contend with unpredictable environments that can dislodge them from substrates. To counter these forces, many organisms (e.g. fish, cephalopods) have evolved suction-based organs for adhesion. Morphology is diverse, with some disc shapes deviating from a circle to more ovate designs. Inspired by the diversity of multiple aquatic species, we investigated how bioinspired cups with different disc shapes performed in shear loading conditions. These experiments highlighted pertinent physical characteristics found in biological discs (regions of stiffness, flattened margins, a sealing rim), as well as ecologically relevant shearing conditions. Disc shapes of fabricated cups included a standard circle, ellipses, and other bioinspired designs. To consider the effects of sealing, these stiff silicone cups were produced with and without a soft rim. Cups were tested using a force-sensing robotic arm, which directionally sheared them across surfaces of varying roughness and compliance in wet conditions while measuring force. In multiple surface and shearing conditions, elliptical and teardrop shapes outperformed the circle, which suggests that disc shape and distribution of stiffness may play an important role in resisting shear. Additionally, incorporating a soft rim increased cup performance on rougher substrates, highlighting interactions between the cup materials and surfaces asperities. To better understand how these cup designs may resist shear, we also utilized a visualization technique (frustrated total internal reflection; FTIR) to quantify how contact area evolves as the cup is sheared.

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Section: Introductionmentioning

confidence: 83%

Section: Robotic Arm Shear Testsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

Stickiness in shear: stiffness, shape, and sealing in bioinspired suction cups affect shear performance on diverse surfaces

Hernandez,

Sandoval,

Yuen

et al. 2024

Bioinspir. Biomim.

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Sucker Shapes, Skeletons, and Bioinspiration: How Hard and Soft Tissue Morphology Generates Adhesive Performance in Waterfall Climbing Goby Fishes

Palecek

Schoenfuss

Blob

2022

Integrative and Comparative Biology

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Many teleost fishes, such as gobies, have fused their paired pelvic fins into an adhesive disc. Gobies can use their pelvic suckers to generate passive adhesive forces (as in engineered suction cups) and different species exhibit a range of adhesive performance, with some even able to climb waterfalls. Previous studies have documented that, in the Hawaiian Islands, species capable of climbing higher waterfalls produce the highest passive pull-off forces, and species found at higher elevation sites are likely to have more rounded suction discs than those found in the lowest stream segments. Morphology of the pelvic girdle also varies between species, with more robust skeletons in taxa with superior passive adhesion. To investigate what factors impact the passive adhesive performance of waterfall climbing gobies, we tested biomimetic suction cups designed with a range of shapes and embedded bioinspired “skeletons” based on micro-CT scans of goby pelvic girdles. We found that while the presence of an internal skeleton may provide some support against failure, the performance of suction cups may be more strongly affected by their external shape. Nonetheless, factors besides external shape and skeletal morphology may still have a stronger influence on sucker tenacity. Our results suggest that the relationship between suction disc morphology and adhesive performance may be influenced by a variety of physical factors, and live animal performance likely is further complicated by muscle activation and climbing behavior. These results have implications for the evolution of suction disc shape in adhesive fishes and for improving the design of biomimetic suction cups.

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The effects of soft and rough substrates on suction-based adhesion

Huie

Summers

2022

Journal of Experimental Biology

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The Northern clingfish (Gobiesox maeandricus) has a suction-based adhesive disc that can stick to incredibly rough surfaces, a challenge for stiff commercial suction cups. Both clingfish discs and bioinspired suction cups have stiff cores but flexible edges that can deform to overcome surface irregularities. Compliant surfaces are common in nature and technical settings, but performance data for fish and commercial cups is gathered from stiff surfaces. We quantified the interaction between substrate compliance, surface roughness, and suction performance for the Northern clingfish, commercial suction cups, and three biomimetic suction cups with disc rims of varying compliance. We found that all cups stick better on stiffer substrates and worse on more compliant ones, as indicated by peak stress values. On compliant substrates, surface roughness had little effect on adhesion, even for commercial cups that normally fail on hard, rough surfaces. We propose that suction performance on compliant substrates can be explained in part by effective elastic modulus, the combined elastic modulus from a cup-substrate interaction. Of all the tested cups, the biomimetic cups performed the best on compliant surfaces, highlighting their potential to be used in medical and marine geotechnical fields. Lastly, we discuss the overmolding technique used to generate the bioinspired cups and how it is an important tool for studying biology.

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Sticking to it: testing passive pull-off forces in waterfall-climbing fishes across challenging substrates

Cited by 7 publications

References 56 publications

Stickiness in shear: stiffness, shape, and sealing in bioinspired suction cups affect shear performance on diverse surfaces

Stickiness in shear: stiffness, shape, and sealing in bioinspired suction cups affect shear performance on diverse surfaces

Sucker Shapes, Skeletons, and Bioinspiration: How Hard and Soft Tissue Morphology Generates Adhesive Performance in Waterfall Climbing Goby Fishes

The effects of soft and rough substrates on suction-based adhesion

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