A Marine-Derived Anti-Inflammatory Scaffold for Accelerating Skin Repair in Diabetic Mice

A Marine-Derived Anti-Inflammatory Scaffold for Accelerating Skin Repair in Diabetic Mice

Reconstructing the typical analogue of extracellular matrix (ECM) in engineered biomaterials is essential for promoting tissue repair. Here, we report an ECM-mimetic scaffold that successfully accelerated wound healing through enhancing vascularization and regulating inflammation. We prepared an ele...

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Bibliographic Details
Main Authors: Xiaoli Huang, Na Guan, Qiu Li
Format: Article
Language:English
Published: MDPI AG 2021-08-01
Series:Marine Drugs
Subjects:
brown alga polysaccharide
inflammatory
diabetic wound healing
Online Access:https://www.mdpi.com/1660-3397/19/9/496
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spelling doaj-f10f9b57e1e74170ba04ef60b27df6f72021-09-26T00:35:29ZengMDPI AGMarine Drugs1660-33972021-08-011949649610.3390/md19090496A Marine-Derived Anti-Inflammatory Scaffold for Accelerating Skin Repair in Diabetic MiceXiaoli Huang0Na Guan1Qiu Li2Central Laboratory and College of Chemistry and Pharmaceutical Sciences, Qingdao Agricultural University, Qingdao 266109, ChinaCentral Laboratory and College of Chemistry and Pharmaceutical Sciences, Qingdao Agricultural University, Qingdao 266109, ChinaCentral Laboratory and College of Chemistry and Pharmaceutical Sciences, Qingdao Agricultural University, Qingdao 266109, ChinaReconstructing the typical analogue of extracellular matrix (ECM) in engineered biomaterials is essential for promoting tissue repair. Here, we report an ECM-mimetic scaffold that successfully accelerated wound healing through enhancing vascularization and regulating inflammation. We prepared an electrospun fiber comprising a brown alga-derived polysaccharide (BAP) and polyvinyl alcohol (PVA). The two polymers in concert exerted the function upon the application of PVA/BAP2 fiber in vivo; it started to reduce the inflammation and promote angiogenesis at the wound site. Our serial in vitro and in vivo tests validated the efficacy of PVA/BAP2 fiber. Particularly, PVA/BAP2 fiber accelerated the repair of a full-thickness skin wound in diabetic mice and induced optimal neo-tissue formation. Generally, our results suggest that, by mimicking the function of ECM, this fiber as an engineered biomaterial can effectively promote the healing efficiency of diabetic wounds. Our investigation may inspire the development of new, effective, and safer marine-derived scaffold for tissue regeneration.https://www.mdpi.com/1660-3397/19/9/496brown alga polysaccharideinflammatorydiabetic wound healing
collection DOAJ
language English
format Article
sources DOAJ
author Xiaoli Huang
Na Guan
Qiu Li
spellingShingle Xiaoli Huang
Na Guan
Qiu Li
A Marine-Derived Anti-Inflammatory Scaffold for Accelerating Skin Repair in Diabetic Mice
Marine Drugs
brown alga polysaccharide
inflammatory
diabetic wound healing
author_facet Xiaoli Huang
Na Guan
Qiu Li
author_sort Xiaoli Huang
title A Marine-Derived Anti-Inflammatory Scaffold for Accelerating Skin Repair in Diabetic Mice
title_short A Marine-Derived Anti-Inflammatory Scaffold for Accelerating Skin Repair in Diabetic Mice
title_full A Marine-Derived Anti-Inflammatory Scaffold for Accelerating Skin Repair in Diabetic Mice
title_fullStr A Marine-Derived Anti-Inflammatory Scaffold for Accelerating Skin Repair in Diabetic Mice
title_full_unstemmed A Marine-Derived Anti-Inflammatory Scaffold for Accelerating Skin Repair in Diabetic Mice
title_sort marine-derived anti-inflammatory scaffold for accelerating skin repair in diabetic mice
publisher MDPI AG
series Marine Drugs
issn 1660-3397
publishDate 2021-08-01
description Reconstructing the typical analogue of extracellular matrix (ECM) in engineered biomaterials is essential for promoting tissue repair. Here, we report an ECM-mimetic scaffold that successfully accelerated wound healing through enhancing vascularization and regulating inflammation. We prepared an electrospun fiber comprising a brown alga-derived polysaccharide (BAP) and polyvinyl alcohol (PVA). The two polymers in concert exerted the function upon the application of PVA/BAP2 fiber in vivo; it started to reduce the inflammation and promote angiogenesis at the wound site. Our serial in vitro and in vivo tests validated the efficacy of PVA/BAP2 fiber. Particularly, PVA/BAP2 fiber accelerated the repair of a full-thickness skin wound in diabetic mice and induced optimal neo-tissue formation. Generally, our results suggest that, by mimicking the function of ECM, this fiber as an engineered biomaterial can effectively promote the healing efficiency of diabetic wounds. Our investigation may inspire the development of new, effective, and safer marine-derived scaffold for tissue regeneration.
topic brown alga polysaccharide
inflammatory
diabetic wound healing
url https://www.mdpi.com/1660-3397/19/9/496
work_keys_str_mv AT xiaolihuang amarinederivedantiinflammatoryscaffoldforacceleratingskinrepairindiabeticmice
AT naguan amarinederivedantiinflammatoryscaffoldforacceleratingskinrepairindiabeticmice
AT qiuli amarinederivedantiinflammatoryscaffoldforacceleratingskinrepairindiabeticmice
AT xiaolihuang marinederivedantiinflammatoryscaffoldforacceleratingskinrepairindiabeticmice
AT naguan marinederivedantiinflammatoryscaffoldforacceleratingskinrepairindiabeticmice
AT qiuli marinederivedantiinflammatoryscaffoldforacceleratingskinrepairindiabeticmice
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