An Electrospun Scaffold Loaded with Anti-androgen Receptor Compound for Accelerating Wound Healing

Overview

Journal Burns Trauma

Publisher Oxford University Press

Date 2016 Aug 31

PMID 27574631

Citations 4

Authors

Cassandra Chong

Yiwei Wang

Peter K M Maitz

Ulla Simanainen

Zhe Li

Affiliations

Soon will be listed here.

Abstract

Current dermal regenerative scafolds provide wound coverage, and structural support and guidance for tissue repair, but usually lack enough bio-signals needed for speeding up skin cell growth, migration, wound closure, and skin regeneration. In this study, an androgen receptor (AR) inhibitor called ASC-J9 is used to demonstrate the concept and feasibility of fabricating drug-loaded scafolds via electrospinning. Inhibition of androgen is known to promote skin wound healing. The novel ASC-J9 - loaded porous scafold was fabricated for skin wound repair using electrospun fibers of collagen and polycaprolactone (PCL) blend. Our preliminary results indicated that ASC-J9 - loaded scafolds facilitated more efficient attachment and ingrowth of dermal fbroblasts, compared to the control collagen-PCL scafold. A signifcant increase of cell proliferation was observed with the drug-loaded scafold over a 28-day period. The drug-loaded scafold also accelerated keratinocyte migration and wound closure in a contraction-inhibited mouse wound model over 21 days. The data indicated a sustained release of ASC-J9 from the scafold and its potential to accelerate wound healing by promoting cell proliferation and migration over an extended period of time. More importantly, our results proved the concept and feasibility of fabricating drug-releasing or bioactive dermal scaffolds for more efective wound healing.

Citing Articles

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Controlled dual release of dihydrotestosterone and flutamide from polycaprolactone electrospun scaffolds accelerate burn wound healing.

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Electrospun Collagen Nanofibers and Their Applications in Skin Tissue Engineering.

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Nanofibrous scaffolds in biomedical applications.

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