Add to ORKGMarine mussels secrete proteins rich in residues containing catechols and cationic amines that displace hydration layers and adhere to charged surfaces under water via a cooperative binding effect known as catechol-cation synergy. Mussel-inspired adhesives containing paired catechol and cationic functionalities are a promising class of materials for biomedical applications, but few studies address the molecular adhesion mechanism(s) of these materials. To determine whether intramolecular adjacency of these functionalities is necessary for robust adhesion, a suite of siderophore analog surface primers was synthesized with systematic variations in intramolecular spacing between catechol and cationic functionalities. Adhesion measurements cond...
The adhesion of some marine organisms to almost any kind of surface in wet conditions has aroused in...
Nature provides many outstanding examples of adhesive strategies from which chemists and material sc...
Intensive studies have found that 3,4-dihydroxyphenylalanine (Dopa) is one of the key molecules for ...
Marine mussels secrete proteins rich in residues containing catechols and cationic amines that displ...
In physiological fluids and seawater, adhesion of synthetic polymers to solid surfaces is impaired b...
Marine organisms such as mussels have mastered the challenges in underwater adhesion by incorporatin...
Despite the recent progress in and demand for wet adhesives, practical underwater adhesion remains l...
Mussel underwater adhesion is a model phenomenon important for the understanding of broader biologic...
Marine biology is continually producing materials with properties unmatched by human technology. The...
In aqueous solutions—such as physiological fluids, seawater, or detergent solutions—both adhesion an...
There is currently a need for improved adhesives for medical and marine applications, primarily beca...
Mussel foot proteins (Mfps) exhibit remarkably adaptive adhesion and bridging between polar surfaces...
Nature often serves as a model system for developing new adhesives. In aqueous environments, mussel-...
The rapid and robust adhesion of marine mussels to diverse solid surfaces in wet environments is med...
Catechol reaction mechanisms form the basis of marine mussel adhesion, allowing for bond formation a...
The adhesion of some marine organisms to almost any kind of surface in wet conditions has aroused in...
Nature provides many outstanding examples of adhesive strategies from which chemists and material sc...
Intensive studies have found that 3,4-dihydroxyphenylalanine (Dopa) is one of the key molecules for ...
Marine mussels secrete proteins rich in residues containing catechols and cationic amines that displ...
In physiological fluids and seawater, adhesion of synthetic polymers to solid surfaces is impaired b...
Marine organisms such as mussels have mastered the challenges in underwater adhesion by incorporatin...
Despite the recent progress in and demand for wet adhesives, practical underwater adhesion remains l...
Mussel underwater adhesion is a model phenomenon important for the understanding of broader biologic...
Marine biology is continually producing materials with properties unmatched by human technology. The...
In aqueous solutions—such as physiological fluids, seawater, or detergent solutions—both adhesion an...
There is currently a need for improved adhesives for medical and marine applications, primarily beca...
Mussel foot proteins (Mfps) exhibit remarkably adaptive adhesion and bridging between polar surfaces...
Nature often serves as a model system for developing new adhesives. In aqueous environments, mussel-...
The rapid and robust adhesion of marine mussels to diverse solid surfaces in wet environments is med...
Catechol reaction mechanisms form the basis of marine mussel adhesion, allowing for bond formation a...
The adhesion of some marine organisms to almost any kind of surface in wet conditions has aroused in...
Nature provides many outstanding examples of adhesive strategies from which chemists and material sc...
Intensive studies have found that 3,4-dihydroxyphenylalanine (Dopa) is one of the key molecules for ...
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