Mussel adhesion – essential footwork

Waite, J. Herbert

doi:10.1242/jeb.134056

Cited by 478 publications

(735 citation statements)

References 114 publications

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“…Each thread is ≈2–5 cm long and further subdivided into three structurally and functionally distinct parts known as the plaque, core and cuticle (Figure A,B). The plaque is a versatile underwater adhesive glue that serves as the interface between the byssal thread and the surface . The core of the thread is a fibrous bio‐polymer anchored into the plaque that provides the energy‐damping function .…”

Section: Structure‐function Relationships In the Byssusmentioning

confidence: 99%

“…The byssus plaque has received the most attention from researchers wishing to replicate its remarkable ability to adhere to almost any surface chemistry in salty seawater environments, which has obvious biomedical and industrial relevance . Bound water, ionic double layers and biofilms present numerous challenges for wet adhesion; yet, mussels have evolved a protein‐based mechanism to circumvent this . Spearheaded by the Waite group, nearly forty years of research have gone into unraveling the complex adhesive mechanism in Mytilus spp .…”

Section: Structure‐function Relationships In the Byssusmentioning

confidence: 99%

“…Spearheaded by the Waite group, nearly forty years of research have gone into unraveling the complex adhesive mechanism in Mytilus spp . mussels, resulting in a very detailed understanding of the biochemistry behind their stickiness . The plaque consists of at least five proteins, although several more putative candidates were recently identified via transcriptomics .…”

Section: Structure‐function Relationships In the Byssusmentioning

confidence: 99%

“…The interaction of mfp‐3 and mfp‐5 with various surfaces has been intensively studied using a technique called surface force apparatus (SFA), which measures work of adhesion for monolayers of biomolecules. Using SFA on different surfaces, it was determined that mfp‐3 and −5 create strong interactions primarily mediated with DOPA, which interact via hydrogen bonds, hydrophobic interactions, metal coordination and covalent cross‐linking depending on the surface chemistry presented and the local conditions (Figure E) . DOPA's known tendency to oxidize at seawater pH to the quinone form, which tends to form covalent cross‐links and is less efficient at adhesion, is counteracted by a cysteine‐rich protein, mfp‐6, which functions as an effective reducing agent .…”

Section: Structure‐function Relationships In the Byssusmentioning

confidence: 99%

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Mussel Byssus Structure‐Function and Fabrication as Inspiration for Biotechnological Production of Advanced Materials

Harrington¹,

Jehle²,

Priemel

2018

Biotechnology Journal

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Biotechnology offers an exciting avenue toward the sustainable production of high performance proteinaceous polymeric materials. In particular, the mussel byssus-a high performance adhesive bio-fiber used by mussels to cling on hard surfaces-has become a veritable archetype for bio-inspired self-healing fibers, tough coatings, and versatile wet adhesives. However, successful translation of mussel-inspired design principles into man-made materials hinges upon elucidating structure-function relationships and biological fabrication processes. This review provides a detailed survey of the state-of-the-art understanding of the biochemical structure-function relationships defining byssus performance with a particular focus on structural hierarchy and metal coordination-based cross-linking. The efforts to mimic the byssus in man-made materials are then discussed. While there has been a strong push to mimic the byssus via synthetic chemistry taking a reductionist approach, herein the focus is specifically on recent progress of biotechnology-based strategies that more closely approximate the biochemical complexity of the natural material. As an outlook, an overview of recent research toward understanding the natural byssus assembly process is provided, as processing remains a critical factor in achieving native-like properties.

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Section: Structure‐function Relationships In the Byssusmentioning

confidence: 99%

Section: Structure‐function Relationships In the Byssusmentioning

confidence: 99%

Section: Structure‐function Relationships In the Byssusmentioning

confidence: 99%

Section: Structure‐function Relationships In the Byssusmentioning

confidence: 99%

See 2 more Smart Citations

Mussel Byssus Structure‐Function and Fabrication as Inspiration for Biotechnological Production of Advanced Materials

Harrington¹,

Jehle²,

Priemel

2018

Biotechnology Journal

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“…Since 1995, adhesion research has emphasized primarily interfacial chemistry, such as the role of DOPA and DOPA-inspired chemical moieties 9 . The relevance of this emphasis was brought into question by the recent discovery that interfacial chemistry provides less than 0.01% of the adhesion energy contributed by plaque geometry and architecture in whole plaques 10,11 .…”

Section: Introductionmentioning

confidence: 99%

Simple peptide coacervates adapted for rapid pressure-sensitive wet adhesion

et al. 2017

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We report here that a dense liquid formed by spontaneous condensation, also known as simple coacervation, of a single-component mussel foot protein-3S-mimicking peptide exhibits properties critical for underwater adhesion. A structurally homogeneous coacervate is deposited on underwater surfaces as micrometer-thick layers, and, after compression, displays orders of magnitude higher underwater adhesion at 2 N/m than that reported from thin films of the most adhesive mussel-foot-derived peptides or their synthetic mimics. The increase in adhesion efficiency does not require nor rely on post-deposition curing or chemical processing, but rather represents an intrinsic physical property of the coacervate. Its wet adhesive and rheological properties correlate with significant dehydration, tight peptide packing and restriction in peptide mobility. We suggest that such dense coacervate liquids represent an essential adaptation for the initial priming stages of mussel adhesive deposition, and provide a hitherto untapped design principle for synthetic underwater adhesives.

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Polymer Adhesion

Kumar,

Patil,

Dhinojwala

2023

Encyclopedia of Polymer Science and Technology

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Polymer adhesives play an important role in industries in the areas of multilayer packaging, structural bonding, wearables, and medical adhesives. The adhesive strength involves two main components. The first component is a function of thermodynamic surface or interfacial energies, and the second component is related to bulk dissipation. The bulk dissipation term can contribute to an almost thousand‐time enhancement in adhesion strength compared to the thermodynamic work of adhesion. In this article, we discuss the basic formulations to calculate the surface and interfacial energies of solids and relate these parameters to the thermodynamic work of adhesion. We also discuss the mechanisms that contribute to the velocity‐dependent adhesive strength. Since almost all practical surfaces are rough, we present the recent theoretical and experimental data on how roughness affects adhesion. The experimental techniques to measure surface structure, thermodynamic work of adhesion, and fracture strength of adhesives are also described in this article. The recent literature on natural adhesive systems has attracted significant interest and provides a brief discussion on how natural systems can be an important source of inspiration for new chemistry and structure to optimize adhesion for various environmental conditions. We end this article with a section summarizing the industrial applications of polymer adhesion.

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Mussel adhesion – essential footwork

Cited by 478 publications

References 114 publications

Mussel Byssus Structure‐Function and Fabrication as Inspiration for Biotechnological Production of Advanced Materials

Mussel Byssus Structure‐Function and Fabrication as Inspiration for Biotechnological Production of Advanced Materials

Simple peptide coacervates adapted for rapid pressure-sensitive wet adhesion

Polymer Adhesion

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