Protein-based underwater adhesives of marine organisms exhibit extraordinary binding strength in high salinity based on utilizing a variety of molecular interaction mechanisms. These include acid-base interactions, bidentate bindings or complex hydrogen bonding interactions, and electrochemical manipulation of interfacial bonding. In this Perspective, we briefly review recent progress in the field, and we discuss how interfacial electrochemistry can vary interfacial forces by concerted tuning of surface charging, hydration forces, and tuning of the interfacial ion concentration. We further discuss open questions, controversial findings, and new paths into understanding and utilizing redox-proteins and derived polymers for enhancing underwater adhesion in a complex salt environment.
Catechol reaction mechanisms form the basis of marine mussel adhesion, allowing for bond formation and cross-linking in wet saline environments. To mimic mussel foot adhesion and develop new bioadhesive underwater glues, it is essential to understand and learn to control their redox activity as well as their chemical reactivity. Here, we study the electrochemical characteristics of functionalized catechols to further understand their reaction mechanisms and find a stable and controllable molecule that we subsequently integrate into a polymer to form a highly adhesive hydrogel. Contradictory to previous hypotheses, 3,4-dihydroxy-L-phenylalanine is shown to follow a Schiff-base reaction whereas dopamine shows an intramolecular ring formation. Dihydrocaffeic acid proved to be stable and was substituted onto a poly(allylamine) backbone and electrochemically cross-linked to form an adhesive hydrogel that was tested using a surface forces apparatus. The hydrogel’s compression and dehydration dependent adhesive strength have proven to be higher than in mussel foot proteins (mfp-3 and mfp-5). Controlling catechol reaction mechanisms and integrating them into stable electrochemically depositable macroscopic structures is an important step in designing new biological coatings and underwater and biomedical adhesives.
Function and properties
at biologic as well as technological interfaces
are controlled by a complex and concerted competition of specific
and unspecific binding with ions and water in the electrolyte. It
is not possible to date to directly estimate by experiment the interfacial
binding energies of involved species in a consistent approach, thus
limiting our understanding of how interactions in complex (physiologic)
media are moderated. Here, we employ a model system utilizing polymers
with end grafted amines interacting with a negatively charged mica
surface. We measure interaction forces as a function of the molecule
density and ion concentration in NaCl solutions. The measured adhesion
decreases by about 90%, from 0.01 to 1 M electrolyte concentration.
We further demonstrate by molecular resolution imaging how ions increasingly
populate the binding surface at elevated concentrations, and are effectively
competing with the functional group for a binding site. We demonstrate
that a competing Langmuir isotherm model can describe this concentration-dependent
competition. Further, based on this model we can quantitatively estimate
ion binding energies, as well as binding energy relationships at a
complex solid|liquid interface. Our approach enables the extraction
of thermodynamic interaction energies and kinetic parameters of ionic
species during monolayer level interactions at a solid|liquid interface,
which to-date is impossible with other techniques.
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