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DOI: 10.1111/bjd.12843

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Topical PDT following excisional wounding of human skin increases production of TGF-b3, MMP-1 and MMP-9 with associated improvement in dermal matrix organisation

Mills SJ, Farrar MD, Ashcroft GS, Griffiths CEM, Rhodes LE

British Journal of Dermatology. 2014;171:55-62.

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Abstract

Animal studies report photodynamic therapy (PDT) to improve healing of excisional wounds but the mechanism is uncertain and equivalent human studies are lacking. To explore the impact of methyl aminolaevulinate (MAL)-PDT on clinical and microscopic parameters of human cutaneous excisional wound healing, examining for potential modulation through production of transforming growth factor (TGF)-Î² isoforms. In healthy older men (60-77 years; n=27), a 4 mm punch biopsy wound was created in skin of the upper inner arm and treated with MAL-PDT three times over five days. An identical control wound to the contralateral arm was untreated and both wounds left to heal by secondary intention. Wounds were re-excised at time points examining the inflammatory phase (7 days, n=10), matrix remodelling (3 weeks, n=8) and cosmetic outcome/dermal structure (9 months, n=9). Production of TGF-Î²1, TGF-Î²3 and matrix metalloproteinases (MMPs), key mediators of matrix deposition and remodelling, was assessed by immunohistochemistry alongside microscopic measurement of wound size/area and clinical assessment of wound appearance. MAL-PDT delayed re-epithelialisation at 7 days, associated with increased inflammation. However, 3 weeks post-wounding, treated wounds were smaller with higher production of MMP-1 (P=0.01), MMP-9 (P=0.04) and the anti-scarring cytokine, TGF-Î²3 (P=0.03). TGF-Î²1 was lower than control at 7 days and higher at 3 weeks (both P=0.03). At 9 months MAL-PDT treated wounds showed greater, more ordered deposition of collagen I, collagen III and elastin (all P<0.05). MAL-PDT increases MMP-1, MMP-9, and TGF-Î²3 production during matrix remodelling, ultimately producing scars with improved dermal matrix architecture. This article is protected by copyright. All rights reserved.

Bibliographic metadata

Type of resource:

text

Content type:

Journal article

Publication status:

Published

Publication type:

Original research

Publication form:

Academic journal article

Author list:

Mills SJ, Farrar MD, Ashcroft GS, Griffiths CEM, Rhodes LE

Published date:

2014-07

Article title:

Topical PDT following excisional wounding of human skin increases production of TGF-b3, MMP-1 and MMP-9 with associated improvement in dermal matrix organisation

Language:

eng

Journal title:

British Journal of Dermatology

Abbreviated journal title:

B J D

ISSN:

0007-0963

Publisher:

Wiley-Blackwell Publishing Ltd.

Volume:

171

Start page:

End page:

Total:

Pagination:

55-62

Digital Object Identifier:

10.1111/bjd.12843

Attached files embargo period:

Immediate release

Attached files release date:

27th January, 2014

Access state:

Active

Institutional metadata

University researcher(s):

Farrar, Mark

Academic department(s):

Record metadata

Manchester eScholar ID:

uk-ac-man-scw:218162

Created by:

Farrar, Mark

Created:

27th January, 2014, 12:43:23

Last modified by:

Farrar, Mark

Last modified:

26th March, 2015, 13:34:04