Towards a nanomechanical basis for temporary adhesion in barnacle cyprids (
            <i>Semibalanus balanoides</i>
            )

Phang, In Yee; Aldred, Nick; Clare, Anthony S.; Vancso, Gyula J.

doi:10.1098/rsif.2007.1209

Cited by 46 publications

(62 citation statements)

References 30 publications

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“…The total surface coverage of an average footprint was 4.1 + 0.6 Â 10 210 m 2 (n ¼ 19). The footprint size roughly corresponded to the diameter of the antennular disc of the cyprid (figure 1c; Phang et al 2008). The microtexture of the footprint was porous in nature with bundles of fibrils (bright features in figure 2b) and individual nanofibrils (indicated by arrows in figure 2c) observable across the contacted surface as shown in figure 2.…”

Section: Morphology Of Balanus Amphitrite Footprintsmentioning

confidence: 99%

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Atomic force microscopy of the morphology and mechanical behaviour of barnacle cyprid footprint proteins at the nanoscale

Phang

Aldred

Ling

et al. 2009

J. R. Soc. Interface.

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Barnacles are a major biofouler of man-made underwater structures. Prior to settlement, cypris larvae explore surfaces by reversible attachment effected by a 'temporary adhesive'. During this exploratory behaviour, cyprids deposit proteinaceous 'footprints' of a putatively adhesive material. In this study, footprints deposited by Balanus amphitrite cyprids were probed by atomic force microscopy (AFM) in artificial sea water (ASW) on silane-modified glass surfaces. AFM images obtained in air yielded better resolution than in ASW and revealed the fibrillar nature of the secretion, suggesting that the deposits were composed of single proteinaceous nanofibrils, or bundles of fibrils. The force curves generated in pulloff force experiments in sea water consisted of regions of gradually increasing force, separated by sharp drops in extension force manifesting a characteristic saw-tooth appearance. Following the relaxation of fibrils stretched to high strains, force -distance curves in reverse stretching experiments could be described by the entropic elasticity model of a polymer chain. When subjected to relaxation exceeding 500 ms, extended footprint proteins refolded, and again showed saw-tooth unfolding peaks in subsequent force cycles. Observed rupture and hysteresis behaviour were explained by the 'sacrificial bond' model. Longer durations of relaxation (.5 s) allowed more sacrificial bond reformation and contributed to enhanced energy dissipation (higher toughness). The persistence length for the protein chains (L P ) was obtained. At high elongation, following repeated stretching up to increasing upper strain limits, footprint proteins detached at total stretched length of 10 mm.

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Section: Morphology Of Balanus Amphitrite Footprintsmentioning

confidence: 99%

“…Using atomic force microscopy (AFM), Phang et al (2008) studied the macro-and micro-morphology of footprints deposited by Semibalanus balanoides. The footprint deposits of S. balanoides were composed of bundles of proteinaceous nanofibrils with heights varying between 7 and 150 nm.…”

Section: Introductionmentioning

confidence: 99%

Atomic force microscopy of the morphology and mechanical behaviour of barnacle cyprid footprint proteins at the nanoscale

Phang

Aldred

Ling

et al. 2009

J. R. Soc. Interface.

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“…4 Neither of these techniques, however, allow for real time observation of the exploratory behavior of the organisms in situ. SEM and SPM are also less suitable for evaluation of larger surface regions.…”

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confidence: 99%

“…The thickness of footprints from S. balanoides has been previously estimated, by atomic force microscopy, to fall between 5 and 19 nm, depending on the surface. 4 In future applications of this technique, we will evaluate the behavior and adhesive interactions of cyprids on a diverse range of substrates with controlled chemistry before continuing with other test species. In time, it is expected that this approach will yield important information regarding the adhesion of such organisms to specific substrates and, thus, inform the development of surfaces to which settlement is impossible.…”

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confidence: 99%

Novel application of imaging surface plasmon resonance for in situ studies of the surface exploration of marine organisms

et al. 2009

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The surface interactions of exploring cyprids of the barnacle Semibalanus balanoides were studied in situ using imaging surface plasmon resonance. It was demonstrated how the deposition of a proteinaceous adhesive could be followed in real time as the cyprids explored and temporarily attached to a surface. Furthermore, the amount of protein left on the surface when the cyprids moved on could be quantified. Clear differences were demonstrated between an oligo(ethyleneglycol) coated surface and a bare gold substrate. It is anticipated that this technique will be a valuable tool in the development of novel surface chemistries that can prevent biofouling.

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“…Mechanisms of barnacle attachment via fluids that undergo curing have garnered scientific interest for applications to control biofouling in industrial (Callow and Callow, 2002;Holm, 2012) and medical contexts (Shivapooja et al, 2013) and bioinspired glues that cure in aqueous environments (Joseph et al, 2011;Kamino, 2013). First, the barnacle cyprid attaches to the substratum via a permanent adhesive, released from cement glands through the two walking appendages, a pair of antennules, embedding them completely, creating an adhesive plaque that anchors them in place (Knight-Jones and Crisp, 1953;Crisp, 1960;Walker, 1971Walker, , 1973Yule and Walker, 1985;Mullineaux and Butman, 1991;Matsumura et al, 1998;Phang et al, 2008;Gohad et al, 2012Gohad et al, , 2014Aldred et al, 2013). The subsequent phases of settlement and metamorphosis for acorn (balanomorph) barnacles involve major changes to the body plan and shape, resulting in a disk-shaped basis parallel to the substratum as a juvenile.…”

Section: Introductionmentioning

confidence: 99%

Barnacle biology before, during and after settlement and metamorphosis: a study of the interface

Essock‐Burns

Gohad

Orihuela

et al. 2016

Journal of Experimental Biology

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Mobile barnacle cypris larvae settle and metamorphose, transitioning to sessile juveniles with morphology and growth similar to that of adults. Because biofilms exist on immersed surfaces on which they attach, barnacles must interact with bacteria during initial attachment and subsequent growth. The objective of this study was to characterize the developing interface of the barnacle and substratum during this key developmental transition to inform potential mechanisms that promote attachment. The interface was characterized using confocal microscopy and fluorescent dyes to identify morphological and chemical changes to the interface and the status of bacteria present as a function of barnacle developmental stage. Staining revealed patchy material containing proteins and nucleic acids, reactive oxygen species amidst developing cuticle, and changes in bacteria viability at the developing interface. We found that as barnacles metamorphose from the cyprid to juvenile stage, proteinaceous materials with the appearance of coagulated liquid were released into and remained at the interface. It stained positive for proteins, including phosphoprotein, as well as nucleic acids. Regions of the developing cuticle and the patchy material itself stained for reactive oxygen species. Bacteria were absent until the cyprid was firmly attached, but populations died as barnacle development progressed. The oxidative environment may contribute to the cytotoxicity observed for bacteria and has the potential for oxidative crosslinking of cuticle and proteinaceous materials at the interface.

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Towards a nanomechanical basis for temporary adhesion in barnacle cyprids ( Semibalanus balanoides )

Cited by 46 publications

References 30 publications

Atomic force microscopy of the morphology and mechanical behaviour of barnacle cyprid footprint proteins at the nanoscale

Atomic force microscopy of the morphology and mechanical behaviour of barnacle cyprid footprint proteins at the nanoscale

Novel application of imaging surface plasmon resonance for in situ studies of the surface exploration of marine organisms

Barnacle biology before, during and after settlement and metamorphosis: a study of the interface

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