Mannose-Decorated Co-Polymer Facilitates Controlled Release of Butyrate to Accelerate Chronic Wound Healing

Overview

Journal Adv Healthc Mater

Specialties Biomedical Engineering
Biotechnology

Date 2023 Jul 28

PMID 37503634

Authors

Abigail L Lauterbach

Anna J Slezak

Ruyi Wang

Shijie Cao

Michal M Raczy

Elyse A Watkins

Carlos J Medina Jimenez

Jeffrey A Hubbell

Affiliations

Soon will be listed here.

Abstract

Butyrate is a key bacterial metabolite that plays an important and complex role in modulation of immunity and maintenance of epithelial barriers. Its translation to clinic is limited by poor bioavailability, pungent smell, and the need for high doses, and effective delivery strategies have yet to realize clinical potential. Here, a novel polymeric delivery platform for tunable and sustainable release of butyrate consisting of a methacrylamide backbone with butyryl ester or phenyl ester side chains as well as mannosyl side chains, which is also applicable to other therapeutically relevant metabolites is reported. This platform's utility in the treatment of non-healing diabetic wounds is explored. This butyrate-containing material modulated immune cell activation in vitro and induced striking changes in the milieu of soluble cytokine and chemokine signals present within the diabetic wound microenvironment in vivo. This novel therapy shows efficacy in the treatment of non-healing wounds through the modulation of the soluble signals present within the wound, and importantly accommodates the critical temporal regulation associated with the wound healing process. Currently, the few therapies to address non-healing wounds demonstrate limited efficacy. This novel platform is positioned to address this large unmet clinical need and improve the closure of otherwise non-healing wounds.

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Mannose-Decorated Co-Polymer Facilitates Controlled Release of Butyrate to Accelerate Chronic Wound Healing.

Lauterbach A, Slezak A, Wang R, Cao S, Raczy M, Watkins E Adv Healthc Mater. 2023; 12(26):e2300515.

PMID: 37503634 PMC: 11468131. DOI: 10.1002/adhm.202300515.

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