Your search keyword '"Wilker, Jonathan J."' showing total 10 results

1. Biocompatibility of mussel-inspired water-soluble tissue adhesives.

Author

Menon AV, Putnam-Neeb AA, Brown CE, Crain CJ, Breur GJ, Narayanan SK, Wilker JJ, and Liu JC

Subjects

Animals, Mice, Solubility, Catechols chemistry, Catechols pharmacology, Tissue Adhesives chemistry, Tissue Adhesives pharmacology, Bivalvia chemistry, Materials Testing, Water chemistry, Biocompatible Materials chemistry

Abstract

Wound closure in surgeries is traditionally achieved using invasive methods such as sutures and staples. Adhesion-based wound closure methods such as tissue adhesives, sealants, and hemostats are slowly replacing these methods due to their ease of application. Although several chemistries have been developed and used commercially for wound closure, there is still a need for better tissue adhesives from the point of view of toxicity, wet-adhesion strength, and long-term bonding. Catechol chemistry has shown great promise in developing wet-set adhesives that meet these criteria. Herein, we have studied the biocompatibility of a catechol-based copolymer adhesive, poly([dopamine methacrylamide]-co-[methyl methacrylate]-co-[poly(ethylene glycol) methyl ether methacrylate]) or poly(catechol-MMA-OEG), which is soluble in water. The adhesive was injected subcutaneously in a mouse model on its own and in combination with a sodium periodate crosslinker. After 72 h, 4 weeks, and 12 weeks, the mice were euthanized and subjected to histopathological analysis. Both adhesives were present and still palpable at the end of 12 weeks. The moderate inflammation observed for the poly(catechol-MMA-OEG) cohort at 72 h had reduced to mild inflammation at the end of 12 weeks. However, the moderate inflammatory response observed for the poly(catechol-MMA-OEG) + crosslinker cohort at 72 h had not subsided at 12 weeks., (© 2024 The Author(s). Journal of Biomedical Materials Research Part A published by Wiley Periodicals LLC.)

Published

2024

2. Cytocompatibility of a mussel-inspired poly(lactic acid)-based adhesive.

Author

Hollingshead S, Siebert H, Wilker JJ, and Liu JC

Subjects

Animals, Ferric Compounds, Polyesters pharmacology, Adhesives chemistry, Bivalvia chemistry

Abstract

Incorporating catechols into polymers can provide strong adhesion even in moist environments, and these polymers show promise for use in several biomedical applications. Surgical adhesives must have strong bonds, be biocompatible, and function in a moist environment. Poly(lactic acid) (PLA) has a long history as a biocompatible material for hard tissue device fixation. By combining these concepts, catechol-containing poly(lactic acid) (cPLA) polymers are created that are strongly adhesive and degrade in physiological environments. Here, we evaluated the cytocompatibility of cPLA with iron(III) or periodate (IO 4 - ) cross-linkers. Fibroblasts cultured in cPLA leachate or on cPLA films generally had slower growth and lower metabolism compared with PLA controls but no differences in viability. These results demonstrated that cPLA was not cytotoxic but that including catechols reduced cell health. When cPLA was cross-linked with periodate, cells generally had reduced metabolism, slower cell growth, and poor actin fiber formation compared with PLA. These results are attributed to the cytotoxicity of periodate since cells cultured with periodate leachate had extremely low viability. Cells grown on the films of iron-cross-linked cPLA generally had high viability and metabolism but slower proliferation than PLA controls. These results indicate that the cPLA and iron-cross-linked cPLA systems are promising materials for biomedical adhesive applications., (© 2021 Wiley Periodicals LLC.)

Published

2022

3. Sum frequency generation vibrational spectroscopic studies on buried heterogeneous biointerfaces.

Author

Zhang C, Jasensky J, Leng C, Del Grosso C, Smith GD, Wilker JJ, and Chen Z

Subjects

Animals, Cells, Cultured, Equipment Design, Equipment Failure Analysis, Feasibility Studies, Immersion, Mice, Oocytes cytology, Vibration, Adhesives chemistry, Bivalvia chemistry, Body Water chemistry, Oocytes chemistry, Spectrum Analysis instrumentation

Abstract

A sum frequency generation (SFG) vibrational micro-spectroscopy system was developed to examine buried heterogeneous biointerfaces. A compact optical microscope was constructed with total-internal reflection (TIR) SFG geometry to monitor the tightly focused SFG laser spots on interfaces, providing the capability of selectively probing different regions on heterogeneous biointerfaces. The TIR configuration ensures and enhances the SFG signal generated only from the sample/substrate interfacial area. As an example for possible applications in biointerfaces studies, the system was used to probe and compare buried interfacial structures of different biological samples attached to underwater surfaces. We studied the interface of a single mouse oocyte on a silica prism to demonstrate the feasibility of tracing and studying a single live cell and substrate interface using SFG. We also examined the interface between a marine mussel adhesive plaque and a CaF2 substrate, showing the removal of interface-bonded water molecules. This work also paves the way for future integration of other microscopic techniques such as TIR-fluorescence microscopy or nonlinear optical imaging with SFG spectroscopy for multimodal surface or interface studies.

Published

2014

4. Molecular weight effects upon the adhesive bonding of a mussel mimetic polymer.

Author

Jenkins CL, Meredith HJ, and Wilker JJ

Subjects

Adhesiveness, Animals, Catechols chemistry, Cross-Linking Reagents chemistry, Dihydroxyphenylalanine chemistry, Molecular Weight, Proteins chemistry, Water chemistry, Adhesives chemistry, Biomimetic Materials chemistry, Biomimetics methods, Bivalvia chemistry, Polymers chemistry

Abstract

Characterization of marine biological adhesives are teaching us how nature makes materials and providing new ideas for synthetic systems. One of the most widely studied adhering animals is the marine mussel. This mollusk bonds to wet rocks by producing an adhesive from cross-linked proteins. Several laboratories are now making synthetic mimics of mussel adhesive proteins, with 3,4-dihydroxyphenylalanine (DOPA) or similar molecules pendant from polymer chains. In select cases, appreciable bulk bonding results, with strengths as high as commercial glues. Polymer molecular weight is amongst several parameters that need to be examined in order to both understand biomimetic adhesion as well as to maximize performance. Experiments presented here explore how the bulk adhesion of a mussel mimetic polymer varies as a function of molecular weight. Systematic structure-function studies were carried out both with and without the presence of an oxidative cross-linker. Without cross-linking, higher molecular weights generally afforded higher adhesion. When a [N(C4H9)4](IO4) cross-linker was added, adhesion peaked at molecular weights of ~50,000-65,000 g/mol. These data help to illustrate how changes to the balance of cohesion versus adhesion influence bulk bonding. Mussel adhesive plaques achieve this balance by incorporating several proteins with molecular weights ranging from 6000 to 110,000 g/mol. To mimic these varied proteins we made a blend of polymers containing a range of molecular weights. Interestingly, this blend adhered more strongly than any of the individual polymers when cross-linked with [N(C4H9)4](IO4). These results are helping us to both understand the origins of biological materials as well as design high performance polymers.

Published

2013

5. The iron-fortified adhesive system of marine mussels.

Author

Wilker JJ

Subjects

Animals, Bivalvia physiology, Iron physiology, Tissue Adhesives

Published

2010

6. Marine bioinorganic materials: mussels pumping iron.

Author

Wilker JJ

Subjects

Animals, Biomimetics, Dihydroxyphenylalanine metabolism, Proteins metabolism, Adhesives metabolism, Bivalvia metabolism, Iron metabolism

Abstract

The oceans are filled with an amazing variety of biological materials including the glues and cements of mussels, barnacles, tube worms, algae, and starfish. Recent studies on mussel adhesive are providing increasing evidence for a unique mechanism of material generation involving iron-induced protein oxidation and cross-linking chemistry. Insights are also being gathered on many of the other marine creatures producing adhesives. Beyond understanding biology, this growing knowledge is inspiring application development. New classes of biomimetic polymers are poised to provide the next generation of surgical adhesives and orthopedic cements., (Copyright 2009 Elsevier Ltd. All rights reserved.)

Published

2010

7. Inkjet printing of bioadhesives.

Author

Doraiswamy A, Dunaway TM, Wilker JJ, and Narayan RJ

Subjects

Animals, Humans, Materials Testing, Proteins metabolism, Spectroscopy, Fourier Transform Infrared, Surface Properties, Adhesives chemistry, Biocompatible Materials chemistry, Bivalvia, Printing instrumentation, Printing methods, Proteins chemistry

Abstract

Over the past century, synthetic adhesives have largely displaced their natural counterparts in medical applications. However, rising concerns over the environmental and toxicological effects of the solvents, monomers, and additives used in synthetic adhesives have recently led the scientific community to seek natural substitutes. Marine mussel adhesive protein is a formaldehyde-free natural adhesive that demonstrates excellent adhesion to several classes of materials, including glasses, metals, metal oxides, and polymers. In this study, we have demonstrated computer aided design (CAD) patterning of various biological adhesives using piezoelectric inkjet technology. A MEMS-based piezoelectric actuator was used to control the flow of the mussel adhesive protein solution through the ink jet nozzles. Fourier transform infrared spectroscopy (FTIR), microscopy, and adhesion studies were performed to examine the chemical, structural, and functional properties of these patterns, respectively. FTIR revealed the piezoelectric inkjet technology technique to be nondestructive. Atomic force microscopy was used to determine the extent of chelation caused by Fe(III). The adhesive strength in these materials was correlated with the extent of chelation by Fe(III). Piezoelectric inkjet printing of naturally-derived biological adhesives may overcome several problems associated with conventional tissue bonding materials. This technique may significantly improve wound repair in next generation eye repair, fracture fixation, wound closure, and drug delivery devices.

Published

2009

8. Cross-linking the protein precursor of marine mussel adhesives: bulk measurements and reagents for curing.

Author

Monahan J and Wilker JJ

Subjects

Adhesiveness drug effects, Adhesiveness radiation effects, Animals, Cations chemistry, Hydrogen-Ion Concentration, Lactase metabolism, Maine, Metals, Heavy chemistry, Metals, Heavy pharmacology, Monophenol Monooxygenase metabolism, Oxidants pharmacology, Oxidation-Reduction drug effects, Ultraviolet Rays, Bivalvia chemistry, Bivalvia physiology, Cross-Linking Reagents chemistry, Protein Precursors chemistry

Abstract

Marine mussels affix themselves to surfaces by use of a highly cross-linked, protein-based adhesive. Metal levels (e.g., Fe, Zn, Cu, Mn) of the cured glue are significantly concentrated relative to surrounding waters. Specific details on the reagents used by mussels to induce protein cross-linking are not known at this time. To provide insight on the cross-linking agents and reactions taking place while curing mussel glues, we performed a study in which various compounds were tested for the ability to bring about protein curing. A precursor to adhesion, with proteins containing the unusual amino acid 3,4-dihydroxyphenylalanine, was extracted from mussel feet. Potential cross-linking agents were mixed with this gelatinous pellet. The compressibility and shear properties of the resulting material were investigated by use of a penetration test. The reagents examined included simple metal ions (e.g., Na+, Zn2+), oxidizing transition metals (e.g., Fe3+, Cr2O7(2-)), nonmetallic oxidants (e.g., H2O2,IO4-), and oxidizing enzymes (e.g., tyrosinase). We found that protein curing was brought about by simple oxidants and transition metal ions. The results show that optimal curing occurs when the reagent is an oxidizing metal ion (e.g., MnO4-, Fe3+). We conclude that marine mussels are likely to employ Mn3+ and Fe3+ for protein cross-linking and adhesive synthesis.

Published

2004

9. Metal-mediated cross-linking in the generation of a marine-mussel adhesive.

Author

Sever MJ, Weisser JT, Monahan J, Srinivasan S, and Wilker JJ

Subjects

Adhesives chemistry, Adhesives isolation & purification, Adhesives metabolism, Animals, Bivalvia physiology, Cross-Linking Reagents metabolism, Dihydroxyphenylalanine analysis, Dihydroxyphenylalanine chemistry, Dihydroxyphenylalanine metabolism, Electron Spin Resonance Spectroscopy, Ferric Compounds chemistry, Iron analysis, Iron metabolism, Ligands, Metals analysis, Metals chemistry, Metals metabolism, Models, Molecular, Nitrates chemistry, Oxidation-Reduction, Oxygen chemistry, Oxygen metabolism, Peptides chemistry, Protein Binding, Proteins isolation & purification, Proteins metabolism, Spectrophotometry, Bivalvia chemistry, Cross-Linking Reagents chemistry, Iron chemistry, Proteins chemistry

Published

2004

10. Specificity of metal ion cross-linking in marine mussel adhesives.

Author

Monahan J and Wilker JJ

Subjects

Adhesives isolation & purification, Animals, Cross-Linking Reagents isolation & purification, Ions, Metals isolation & purification, Proteins isolation & purification, Adhesives chemistry, Bivalvia chemistry, Cross-Linking Reagents chemistry, Metals chemistry, Proteins chemistry

Abstract

In an effort to understand the formation of marine bioadhesives, mussel protein extracts were cured with various reagents and the enhanced cross-linking ability of Fe3+ was found.

Published

2003