Direct evidence of acid-base interactions in gecko adhesion

Singla, Saranshu; Jain, Dharamdeep; Zoltowski, Chelsea M.; Voleti, Sriharsha; Stark, Alyssa Y.; Niewiarowski, Peter H.; Dhinojwala, Ali

doi:10.1126/sciadv.abd9410

Cited by 38 publications

(33 citation statements)

References 60 publications

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“…However, thickness and orientation estimates are very close to what Singla et al . have proposed based on sum frequency generation experiments of setae attached to sapphire [30].…”

Section: Resultsmentioning

confidence: 99%

“…Singla et al . recently proposed that lipids could support adhesion to sapphire surfaces by an acid–base mechanism [30]. The lipid layer may also be involved in keeping the proteins of setae and spatulae hydrated by enclosing the proteinaceous tissue and thereby reducing water evaporation.…”

Section: Discussionmentioning

confidence: 99%

“…Lipids are known to reside in the epidermis of reptiles in a ‘brick and mortar’ pattern [28,31]. Lipids have also been observed in gecko footprints [29], within setae [32] and at the surface of setae tissue [21,28,30]. This led Jain et al .…”

Section: Introductionmentioning

confidence: 99%

“…More recent models of gecko adhesion now indicate that chemistry cannot be ignored and that chemical details matter for gecko surface adhesion. Vibrational surface spectroscopy and nuclear magnetic resonance (NMR) indicate an important role of lipids and acid-base interactions for gecko adhesion [28][29][30]. As in any adhesion phenomenon, the outermost molecular structure of the setae defines the mechanical and chemical contact during adhesion.…”

Section: Introductionmentioning

confidence: 99%

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Evidence that gecko setae are coated with an ordered nanometre-thin lipid film

et al. 2022

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The fascinating adhesion of gecko to virtually any material has been related to surface interactions of myriads of spatula at the tips of gecko feet. Surprisingly, the molecular details of the surface chemistry of gecko adhesion are still largely unknown. Lipids have been identified within gecko adhesive pads. However, the location of the lipids, the extent to which spatula are coated with lipids, and how the lipids are structured are still open questions. Lipids can modulate adhesion properties and surface hydrophobicity and may play an important role in adhesion. We have therefore studied the molecular structure of lipids at spatula surfaces using near-edge X-ray absorption fine structure imaging. We provide evidence that a nanometre-thin layer of lipids is present at the spatula surfaces of the tokay gecko ( Gekko gecko ) and that the lipids form ordered, densely packed layers. Such dense, thin lipid layers can effectively protect the spatula proteins from dehydration by forming a barrier against water evaporation. Lipids can also render surfaces hydrophobic and thereby support the gecko adhesive system by enhancement of hydrophobic–hydrophobic interactions with surfaces.

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“…However, thickness and orientation estimates are very close to what Singla et al . have proposed based on sum frequency generation experiments of setae attached to sapphire [30].…”

Section: Resultsmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Evidence that gecko setae are coated with an ordered nanometre-thin lipid film

et al. 2022

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“…Geckos are thought to rely on van der Waals forces via dry contact with the substrate ( Autumn et al, 2002 ), although observations of phospholipid footprints left behind by walking geckos ( Hsu et al, 2012 ) could change that picture. A recent study has in fact presented evidence for the importance of polar interactions in gecko adhesion mediated by this phospholipid layer ( Singla et al, 2021 ). This calls for a reinterpretation of previously reported gecko adhesion data by considering the influence of the phospholipid layer.…”

Section: Discussionmentioning

confidence: 99%

Wetting of the tarsal adhesive fluid determines underwater adhesion in ladybird beetles

Sudersan

Kappl

Pinchasik

et al. 2021

Journal of Experimental Biology

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Many insects can climb smooth surfaces using hairy adhesive pads on their legs mediated by tarsal fluid secretions. It was previously shown that a terrestrial beetle can even adhere and walk underwater. The naturally hydrophobic hairs trap an air bubble around the pads, allowing the hairs to make contact to the substrate like in air. However, it remained unclear to what extent such an air bubble is necessary for underwater adhesion. To investigate the role of the bubble, we measured the adhesive forces inindividual legs of live but constrained ladybug beetles underwater in the presence and absence of a trapped bubble and compared it with its adhesion in air. Our experiments revealed that on a hydrophobic substrate, even without a bubble, the pads show adhesion comparable to that in air. On a hydrophilic substrate, underwater adhesion is significantly reduced, with or without a trapped bubble. We modelled the adhesion of a hairy pad using capillary forces. Coherent with our experiments, the model demonstrates that the wetting properties of the tarsal fluid alone can determine the ladybugs’ adhesion to smooth surfaces in both air and underwater conditions and that an air bubble is not a prerequisite for their underwater adhesion. The study highlights how such a mediating fluid can serve as a potential strategy to achieve underwater adhesion via capillary forces, which could inspire artificial adhesives for underwater applications.

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Bioinspired Hierarchical Structures for Contact‐Sensible Adhesives

Wang

Tian

et al. 2021

Adv Funct Materials

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Bioinspired structural adhesives that are capable of bonding two objects together have recently found widespread applications in industrial fields, because of their promising reusability and environmental friendliness. However, such adhesives are usually monofunctional and cannot yield real‐time detection on the adhesion status, which is important for both biological systems (e.g., Gecko) and engineered mimics. This study reports a new hierarchical structure with the monolithic integration of adhesion and sensing functions, namely, contact‐sensible adhesive (CSA). The proposed CSA is composed of mushroom‐shaped microstructures on the top layer for providing strong adhesion, and a pillar array sandwiched by a pair of foil electrodes on the bottom layer as a compliant backing and a capacitive sensor. The CSA is not only sensitive to the external pressure, tension, and shear loads, but also shows enhanced adhesion on uneven surfaces, due to the high compliance of the hierarchical system. As a proof of concept, the as‐prepared CSA is applied as a contact interface in a gripper to complete the grasping task.

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Direct evidence of acid-base interactions in gecko adhesion

Cited by 38 publications

References 60 publications

Evidence that gecko setae are coated with an ordered nanometre-thin lipid film

Evidence that gecko setae are coated with an ordered nanometre-thin lipid film

Wetting of the tarsal adhesive fluid determines underwater adhesion in ladybird beetles

Bioinspired Hierarchical Structures for Contact‐Sensible Adhesives

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