Abstract

BACKGROUND: Chronic wounds are a prominent concern, accounting for $25 billion of healthcare costs annually. Biofilms have been implicated in delayed wound closure, but treatment options continue to be limited and susceptible to developing antibiotic resistance. A novel collagen-rich hydrogel derived from human extracellular matrix presents an avenue for treating chronic wounds by providing appropriate extracellular proteins for healing and promoting neovascularization. Using the hydrogel as a delivery system for localized secretion of therapeutic dosage of antibiotics presents an attractive means of maximizing delivery while minimizing systemic side-effects. We hypothesize that the hydrogel can provide controlled elution of antibiotics leading to inhibition of bacterial growth and disruption of biofilm formation.METHOD: The rate of antibiotic elution from the collagen-rich hydrogel and the efficacy of biofilm disruption was assessed with Pseudomonas aeruginosa Bacterial growth inhibition, biofilm disruption, and mammalian cell cytotoxicity were quantified using in vitro models.RESULTS: The antibiotic-loaded hydrogel showed sustained release of antibiotics for up to 24 hours at therapeutic levels. The treatment inhibited bacterial growth and disrupted biofilm formation at multiple time points. The hydrogel was capable of accommodating various classes of antibiotics and did not result in cytotoxicity in mammalian fibroblasts or adipose stem cellsConclusion: An antibiotic-loaded collagen-rich hydrogel is capable of controlled antibiotic release effective for bacteria cell death without native cell death. A human-derived hydrogel that is capable of eluting therapeutic levels of antibiotic is an exciting prospect in the field of chronic wound healing.

View details for DOI 10.1128/AAC.00136-20

View details for PubMedID 32690648