Biological performance of mussel-inspired adhesive in extrahepatic islet transplantation

Brubaker, Carrie E.; Kißler, Hermann; Wang, Ling‐Jia; Kaufman, Dixon B.; Messersmith, Phillip B.

doi:10.1016/j.biomaterials.2009.09.062

Cited by 299 publications

(260 citation statements)

References 38 publications

(35 reference statements)

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“…The structural and mechanical lessons gained by investigating the byssus network could provide us with important design principles that can be applied in the fabrication of interfacial materials that can function effectively under dynamic loadings, such as attachments to ships, submarines, in wind turbines, or for applications in space technologies 4,25,26 . From a slightly different perspective, we have found that the use of about 20% soft material in mussel threads is crucial in light of impact absorption and force reduction for the entire animal.…”

Section: Discussionmentioning

confidence: 99%

Impact tolerance in mussel thread networks by heterogeneous material distribution

Qin

Buehler

2013

Nat Commun

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The Mytilidae, generally known as marine mussels, are known to attach to most substrates including stone, wood, concrete and iron by using a network of byssus threads. Mussels are subjected to severe mechanical impacts caused by waves. However, how the network of byssus threads keeps the mussel attached in this challenging mechanical environment is puzzling, as the dynamical forces far exceed the measured strength of byssus threads and their attachment to the environment. Here we combine experiment and simulation, and show that the heterogeneous material distribution in byssus threads has a critical role in decreasing the effect of impact loading. We find that a combination of stiff and soft materials at an 80:20 ratio enables mussels to rapidly and effectively dissipate impact energy. Notably, this facilitates a significantly enhanced strength under dynamical loading over 900% that of the strength under static loading.

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Section: Discussionmentioning

confidence: 99%

Impact tolerance in mussel thread networks by heterogeneous material distribution

Qin

Buehler

2013

Nat Commun

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“…The extraordinary ability of the byssus to bind to a variety of pristine and bio-fouled surfaces (e.g. glass, metal, plastic) in a matter of minutes while immersed in the high salt and basic pH conditions imposed by seawater has attracted the attention of many researchers and resulted in the creation of biomimetic glues for medical and broader use [2][3][4][5][6].…”

Section: Introductionmentioning

confidence: 99%

The microscopic network structure of mussel ( Mytilus ) adhesive plaques

Filippidi

DeMartini

Molina

et al. 2015

J. R. Soc. Interface.

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Marine mussels of the genus Mytilus live in the hostile intertidal zone, attached to rocks, bio-fouled surfaces and each other via collagen-rich threads ending in adhesive pads, the plaques. Plaques adhere in salty, alkaline seawater, withstanding waves and tidal currents. Each plaque requires a force of several newtons to detach. Although the molecular composition of the plaques has been well studied, a complete understanding of supra-molecular plaque architecture and its role in maintaining adhesive strength remains elusive. Here, electron microscopy and neutron scattering studies of plaques harvested from Mytilus californianus and Mytilus galloprovincialis reveal a complex network structure reminiscent of structural foams. Two characteristic length scales are observed characterizing a dense meshwork (approx. 100 nm) with large interpenetrating pores (approx. 1 mm). The network withstands chemical denaturation, indicating significant cross-linking. Plaques formed at lower temperatures have finer network struts, from which we hypothesize a kinetically controlled formation mechanism. When mussels are induced to create plaques, the resulting structure lacks a well-defined network architecture, showcasing the importance of processing over self-assembly. Together, these new data provide essential insight into plaque structure and formation and set the foundation to understand the role of plaque structure in stress distribution and toughening in natural and biomimetic materials.

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“…In this figure, catechol, [22] dopamine [23] or dopa [24] was coupled to polymer chains ends or as side chains of polymerizable catechol monomers with the linear or branched polymer backbone, which are commonly made of polystyrene, [25] poly(ethylene glycol), [26] poly-(acrylate/methacrylate), [27] or poly(acrylamide/methacrylamide) [28] ( Figure 3). It is demonstrated that both of catechols and cations have a classic synergy for underwater adhesion.…”

Section: Molecular Design Principle Of Musselinspired Polymeric Undermentioning

confidence: 99%

“…[51] Based on the mussels protein, a mimetic biological adhesive was fabricated with a branched poly(ethylene glycol) (PEG) with catechol end groups ( Figure 9A). [22] After adding sodium periodate solution to induce gelation, the branched catechol-functional PEG (cPEG) solutions form hydrogels in less than 1 min ( Figure 9B). Subsequently, the cPEG adhesive elicited minimal acute or chronic inflammatory response in C57BL6 mice, and maintained an intact interface with supporting tissue up to one year.…”

Section: Biological Adhesives Of Catechol-functional Polymermentioning

confidence: 99%

Recent Progress of Mussel‐Inspired Underwater Adhesives

Zhang

Song

et al. 2017

Chin. J. Chem.

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Underwater adhesion is greatly desired in tissue transplantation, medical treatment, ocean transportation, and so on. However, common commercial polymeric adhesives are rather weakened and easily destroyed in water environment. In nature, some marine organisms, such as mussels, barnacles, or tube worms, exhibiting excellent underwater adhesion up to robust bonding on the rock of sea floor, can give exciting solutions to address the problem. Among these marine organisms, mussels exhibit unique underwater adhesion via the foot proteins of byssus. It has been verified that the catechol groups from the side chain of the mussel foot proteins is the main contribution to the unique underwater adhesion. Hence, inspired by the mussels' underwater adhesion, many mussel-mimetic polymers with catechol as end chains or side chains have been developed in the past decades. Here, we review recent progress of mussel-inspired underwater adhesives polymers from their catechol-functional design to their potential applications in intermediates, anti-biofouling, self-healing of hydrogels, biological adhesives, and drug delivery. The review may provide basis and help for the development of the commercial underwater adhesives.

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Biological performance of mussel-inspired adhesive in extrahepatic islet transplantation

Cited by 299 publications

References 38 publications

Impact tolerance in mussel thread networks by heterogeneous material distribution

Impact tolerance in mussel thread networks by heterogeneous material distribution

The microscopic network structure of mussel ( Mytilus ) adhesive plaques

Recent Progress of Mussel‐Inspired Underwater Adhesives

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