B-H Hu1, P B Messersmith. 1. Biomedical Engineering Department, Northwestern University, Evanston, IL 60208, USA.
Abstract
OBJECTIVES: To design an in-situ gelling hydrogel capable of solidifying rapidly under physiologic conditions into a hydrogel capable of adhering tissue surfaces together. DESIGN: Multifunctional polymers containing covalently bound peptide substrates of transglutaminase were designed. EXPERIMENTAL VARIABLE: Enzyme cross-linked hydrogels were compared with commercial fibrin tissue adhesive. OUTCOME MEASURE: The shear strength between tissue surfaces or type 1 collagen membranes bonded with hydrogel was measured. RESULTS: The shear adhesive strength of transglutaminase cross-linked hydrogels was found to be equal to or better than fibrin sealant for tissue and collagen surfaces, respectively. CONCLUSION: Transglutaminase cross-linked hydrogels are injectable, in-situ formed, biodegradable, and expected to be useful in a variety of applications including sustained drug delivery, medical and dental adhesives, tissue repair and engineering as polymeric scaffolds, and gene therapy.
OBJECTIVES: To design an in-situ gelling hydrogel capable of solidifying rapidly under physiologic conditions into a hydrogel capable of adhering tissue surfaces together. DESIGN: Multifunctional polymers containing covalently bound peptide substrates of transglutaminase were designed. EXPERIMENTAL VARIABLE: Enzyme cross-linked hydrogels were compared with commercial fibrin tissue adhesive. OUTCOME MEASURE: The shear strength between tissue surfaces or type 1 collagen membranes bonded with hydrogel was measured. RESULTS: The shear adhesive strength of transglutaminase cross-linked hydrogels was found to be equal to or better than fibrin sealant for tissue and collagen surfaces, respectively. CONCLUSION: Transglutaminase cross-linked hydrogels are injectable, in-situ formed, biodegradable, and expected to be useful in a variety of applications including sustained drug delivery, medical and dental adhesives, tissue repair and engineering as polymeric scaffolds, and gene therapy.
Authors: Maria Pia Savoca; Elisa Tonoli; Adeola G Atobatele; Elisabetta A M Verderio Journal: Micromachines (Basel) Date: 2018-10-31 Impact factor: 2.891