Production-scale Fibronectin Nanofibers Promote Wound Closure and Tissue Repair in a Dermal Mouse Model

Overview

Journal Biomaterials

Specialty Biomedical Engineering

Date 2018 Mar 18

PMID 29549768

Citations 35

Authors

Christophe O Chantre

Patrick H Campbell

Holly M Golecki

Adrian T Buganza

Andrew K Capulli

Leila F Deravi

Stephanie Dauth

Sean P Sheehy

Jeffrey A Paten

Karl Gledhill

Yanne S Doucet

Hasan E Abaci

Seungkuk Ahn

Benjamin D Pope

Jeffrey W Ruberti

Simon P Hoerstrup

Angela M Christiano

Kevin Kit Parker

Affiliations

Soon will be listed here.

Abstract

Wounds in the fetus can heal without scarring. Consequently, biomaterials that attempt to recapitulate the biophysical and biochemical properties of fetal skin have emerged as promising pro-regenerative strategies. The extracellular matrix (ECM) protein fibronectin (Fn) in particular is believed to play a crucial role in directing this regenerative phenotype. Accordingly, Fn has been implicated in numerous wound healing studies, yet remains untested in its fibrillar conformation as found in fetal skin. Here, we show that high extensional (∼1.2 ×10 s) and shear (∼3 ×10 s) strain rates in rotary jet spinning (RJS) can drive high throughput Fn fibrillogenesis (∼10 mL/min), thus producing nanofiber scaffolds that are used to effectively enhance wound healing. When tested on a full-thickness wound mouse model, Fn nanofiber dressings not only accelerated wound closure, but also significantly improved tissue restoration, recovering dermal and epidermal structures as well as skin appendages and adipose tissue. Together, these results suggest that bioprotein nanofiber fabrication via RJS could set a new paradigm for enhancing wound healing and may thus find use in a variety of regenerative medicine applications.

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