pH-dependent cross-linking of catechols through oxidation via Fe<sup>3+</sup>and potential implications for mussel adhesion

Fullenkamp, Dominic E; Barrett, Devin G.; Miller, Dusty R.; Kurutz, Josh W.; Messersmith, Phillip B.

doi:10.1039/c4ra03178d

Cited by 103 publications

(108 citation statements)

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“…Fe(III)-dependent dimer formation decreases with increasing pH. Dimerization occurs most readily at pH 2, can be detected at pH 5, and is absent at pH 7 and 9, where Fe(III) coordination is favored over Fe(III) induced oxidation [86]. A Dopa autoxidation product was observed at pH 9 in the absence of Fe(III) and this product is not detected in the presence of Fe(III), demonstrating that Fe(III) coordination protects Dopa against autoxidation [86].…”

Section: Oxidation Of Catechols By Fe(iii) In Mussel Plaquesmentioning

confidence: 96%

“…. Dopa-containing small molecules and model peptides also form covalently crosslinked aryl dimers at pH 2 in the presence of Fe(III) [86]. Fe(III)-dependent dimer formation decreases with increasing pH.…”

Section: Oxidation Of Catechols By Fe(iii) In Mussel Plaquesmentioning

confidence: 99%

“…Dimerization occurs most readily at pH 2, can be detected at pH 5, and is absent at pH 7 and 9, where Fe(III) coordination is favored over Fe(III) induced oxidation [86]. A Dopa autoxidation product was observed at pH 9 in the absence of Fe(III) and this product is not detected in the presence of Fe(III), demonstrating that Fe(III) coordination protects Dopa against autoxidation [86]. 24 Collectively, these results imply that a significant number of Fe(III)-induced covalent crosslinks may initially form within the mfps in the plaque in the low pH environment of the distal depression before mussel foot removal allows equilibration to oceanic pH.…”

Section: Oxidation Of Catechols By Fe(iii) In Mussel Plaquesmentioning

confidence: 99%

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Siderophores and mussel foot proteins: the role of catechol, cations, and metal coordination in surface adhesion

Maier

Butler

2017

J Biol Inorg Chem

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Metal coordination, hydrogen bonding, redox reactions, and covalent crosslinking are seemingly disparate chemical and physicochemical processes that are all accomplished in natural materials by the catechol functional group. This review focuses on the reactivity of catechols in tris-2,3-dihydroxybenzoyl-containing microbial siderophores and synthetic analogs, as well as Dopa-(3,4-dihydroxyphenylalanine)-containing mussel foot proteins that adhere to surfaces in aqueous conditions.Mussel foot proteins with a high content of Dopa and cationic amino acids, Lys and Arg, adhere strongly to mica, an aluminosilicate mineral, in aqueous conditions. The siderophore cyclic trichrysobactin, tris-(2,3-dihydroxybenzoyl-D-Lys-L-Ser) and related synthetic analogs in which the tri-Ser macrolactone is replaced by Tren, tris-(2-aminoethyl)amine, also adheres strongly to mica. Variation in the nature of the catechol and cationic groups in synthetic analogs reveals a synergism between the cationic amino acid and the catechol, required for strong aqueous adhesion. Autoxidation and iron(III)-catalyzed oxidation of 2,3-dihydroxy and 3,4-dihydroxy catechols is also considered. These siderophore analogs provide a platform to understand catechol interactions and reactivity on surfaces, which may ultimately improve the design of synthetic materials that address diverse challenges in medicine, materials science, as well as other disciplines, in which surface adhesion in aqueous conditions is important.

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Section: Oxidation Of Catechols By Fe(iii) In Mussel Plaquesmentioning

confidence: 96%

Section: Oxidation Of Catechols By Fe(iii) In Mussel Plaquesmentioning

confidence: 99%

Section: Oxidation Of Catechols By Fe(iii) In Mussel Plaquesmentioning

confidence: 99%

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Siderophores and mussel foot proteins: the role of catechol, cations, and metal coordination in surface adhesion

Maier

Butler

2017

J Biol Inorg Chem

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“…However, spectroscopic evidence has linked the presence of Fe 3+ to catechol oxidation for decades [16] [17] [18]. It has been reported that catecholmodified polyethylene glycol (PEG) polymers could be covalently cross-linked under acidic pH conditions in the presence of Fe 3+ [19] [20]. Therefore, the mechanism of interactions between Fe 3+ and catechols must be extensively investigated.…”

Section: Introductionmentioning

confidence: 99%

The Effects of Oxidation States, Spin States and Solvents on Molecular Structure, Stability and Spectroscopic Properties of Fe-Catechol Complexes: A Theoretical Study

Matin¹,

Islam²,

Bredow³

et al. 2017

ACES

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“…An inexpensive and biocompatible self-healing hydrogel for injectable cell therapy carrier was also investigated by Yang et al [14]. Recently, some significant work has focused on non-covalent hydrogels, which are cross-linked by reversible interactions based on metal-ligand coordination in the polymer chains; these can provide stimuli responsiveness, magnetic self-healing and good mechanical properties [8][9][10][15][16][17][18][19][20]. Because of the thermodynamics and kinetic properties of metal-ligand coordination bonds, metal-ligand interactions can provide stable, reversible crosslinking points between polymers [21].…”

Section: Introductionmentioning

confidence: 99%

Mussel-mimetic self-healing polyaspartamide derivative gel via boron-catechol interactions

Wang¹,

Jeon²,

Park³

et al. 2015

Express Polym. Lett.

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Abstract. The catechol group from catechol of 3,4-dihydroxyphenethylamine (DOP, dopamine) has the ability to interact with metal ions to form non-covalent bonds in polymer chains. In this study, a novel kind of mussel-inspired copolymer, dopamine-conjugated poly(hydroxyethyl aspartamide), polyAspAm(DOP/EA), was synthesized and its interaction with boric acid (H 3 BO 3 ) to form a cross-linked gel via boron-catechol coordinative binding was investigated. The copolymer was designed to contain a pH responsive adhesive catechol group, which reversibly underwent gelation through the metalcatechol binding, as proved by UV-Vis spectroscopy. When the pH is increased from acidic conditions to a specified pH (pH > 9), the B(OH) 3 is considered to have a functionality of two to bind catechols, leading to bis-complexes. In addition, the reversibility of the boron-catechol bonds provides self-healing characteristics to the polyAspAm gels. The rheological results showed that boron-catechol coordination could lead to quick and full recovery after the fracture of a gel specimen. This novel pH-responsive and self-healing gel system has potential in various applications including smart hydrogels, medical adhesives, and sealants.

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pH-dependent cross-linking of catechols through oxidation via Fe³⁺and potential implications for mussel adhesion

Cited by 103 publications

References 45 publications

Siderophores and mussel foot proteins: the role of catechol, cations, and metal coordination in surface adhesion

Siderophores and mussel foot proteins: the role of catechol, cations, and metal coordination in surface adhesion

The Effects of Oxidation States, Spin States and Solvents on Molecular Structure, Stability and Spectroscopic Properties of Fe-Catechol Complexes: A Theoretical Study

Mussel-mimetic self-healing polyaspartamide derivative gel via boron-catechol interactions

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pH-dependent cross-linking of catechols through oxidation via Fe3+and potential implications for mussel adhesion

Cited by 103 publications

References 45 publications

Siderophores and mussel foot proteins: the role of catechol, cations, and metal coordination in surface adhesion

Siderophores and mussel foot proteins: the role of catechol, cations, and metal coordination in surface adhesion

The Effects of Oxidation States, Spin States and Solvents on Molecular Structure, Stability and Spectroscopic Properties of Fe-Catechol Complexes: A Theoretical Study

Mussel-mimetic self-healing polyaspartamide derivative gel via boron-catechol interactions

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Product

Resources

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pH-dependent cross-linking of catechols through oxidation via Fe³⁺and potential implications for mussel adhesion