Double‐Layer Asymmetric Porous Mesh with Dynamic Mechanical Support Properties Enables Efficient Single‐Stage Repair of Contaminated Abdominal Wall Defect

Double‐Layer Asymmetric Porous Mesh with Dynamic Mechanical Support Properties Enables Efficient Single‐Stage Repair of Contaminated Abdominal Wall Defect

Contamination tolerance and long‐term mechanical support are the two critical properties of meshes for contaminated abdominal wall defect repair. However, biological meshes with excellent pollution tolerance fail to provide bio‐adaptive long‐term mechanical support due to their rapid degradation. He...

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Veröffentlicht in:Advanced materials (Weinheim) 2024-06, Vol.36 (24), p.e2307845-n/a
Hauptverfasser: Tang, Fuxin, Miao, Dongtian, Huang, Rongkang, Zheng, Bingna, Yu, Yang, Ma, Pengwei, Peng, Binying, Li, Yong, Wang, Hui, Wu, Dingcai
Format: Artikel
Sprache:eng
Schlagworte:
Abdomen
Abdominal Wall - surgery
Animals
Asymmetry
Biocompatible Materials - chemistry
contaminated abdominal wall defect
Defects
Degradation
dynamic mechanical support
Freeze-thaw
local immune regulation
Polyvinyl alcohol
Polyvinyl Alcohol - chemistry
Porosity
porous mesh
Surgical Mesh
Tensile Strength
tissue remodeling
Wound Healing
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container_issue 24
container_start_page e2307845
container_title Advanced materials (Weinheim)
container_volume 36
creator Tang, Fuxin
Miao, Dongtian
Huang, Rongkang
Zheng, Bingna
Yu, Yang
Ma, Pengwei
Peng, Binying
Li, Yong
Wang, Hui
Wu, Dingcai
description Contamination tolerance and long‐term mechanical support are the two critical properties of meshes for contaminated abdominal wall defect repair. However, biological meshes with excellent pollution tolerance fail to provide bio‐adaptive long‐term mechanical support due to their rapid degradation. Here, a novel double‐layer asymmetric porous mesh (SIS/PVA‐EXO) is designed by simple and efficient in situ freeze–thaw of sticky polyvinyl alcohol (PVA) solution on the loosely porous surface of small intestinal submucosal decellularized matrix (SIS), which can successfully repair the contaminated abdominal wall defect with bio‐adaptive dynamic mechanical support through only single‐stage surgery. The exosome‐loaded degradable loosely porous SIS layer accelerates the tissue healing; meanwhile, the exosome‐loaded densely porous PVA layer can maintain long‐term mechanical support without any abdominal adhesion. In addition, the tensile strength and strain at break of SIS/PVA‐EXO mesh change gradually from 0.37 MPa and 210% to 0.10 MPa and 385% with the degradation of SIS layer. This unique performance can dynamically adapt to the variable mechanical demands during different periods of contaminated abdominal wall reconstruction. As a result, this SIS/PVA‐EXO mesh shows an attractive prospect in the treatment of contaminated abdominal wall defect without recurrence by integrating local immune regulation, tissue remodeling, and dynamic mechanical supporting. Double‐layer asymmetric porous mesh (SIS/PVA‐EXO) designed via simple and efficient in situ freeze–thaw of PVA solution on the loosely porous surface of SIS can successfully repair the contaminated abdominal wall defect with bio‐adaptive dynamic mechanical support through only single‐stage surgery, showing an appealing application prospect for tissue repair.
doi_str_mv 10.1002/adma.202307845
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However, biological meshes with excellent pollution tolerance fail to provide bio‐adaptive long‐term mechanical support due to their rapid degradation. Here, a novel double‐layer asymmetric porous mesh (SIS/PVA‐EXO) is designed by simple and efficient in situ freeze–thaw of sticky polyvinyl alcohol (PVA) solution on the loosely porous surface of small intestinal submucosal decellularized matrix (SIS), which can successfully repair the contaminated abdominal wall defect with bio‐adaptive dynamic mechanical support through only single‐stage surgery. The exosome‐loaded degradable loosely porous SIS layer accelerates the tissue healing; meanwhile, the exosome‐loaded densely porous PVA layer can maintain long‐term mechanical support without any abdominal adhesion. In addition, the tensile strength and strain at break of SIS/PVA‐EXO mesh change gradually from 0.37 MPa and 210% to 0.10 MPa and 385% with the degradation of SIS layer. This unique performance can dynamically adapt to the variable mechanical demands during different periods of contaminated abdominal wall reconstruction. As a result, this SIS/PVA‐EXO mesh shows an attractive prospect in the treatment of contaminated abdominal wall defect without recurrence by integrating local immune regulation, tissue remodeling, and dynamic mechanical supporting. Double‐layer asymmetric porous mesh (SIS/PVA‐EXO) designed via simple and efficient in situ freeze–thaw of PVA solution on the loosely porous surface of SIS can successfully repair the contaminated abdominal wall defect with bio‐adaptive dynamic mechanical support through only single‐stage surgery, showing an appealing application prospect for tissue repair.</abstract><cop>Germany</cop><pub>Wiley Subscription Services, Inc</pub><pmid>38408735</pmid><doi>10.1002/adma.202307845</doi><tpages>10</tpages><orcidid>https://orcid.org/0000-0003-1396-0097</orcidid></addata></record>
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source MEDLINE; Wiley Journals
subjects Abdomen
Abdominal Wall - surgery
Animals
Asymmetry
Biocompatible Materials - chemistry
contaminated abdominal wall defect
Defects
Degradation
dynamic mechanical support
Freeze-thaw
local immune regulation
Polyvinyl alcohol
Polyvinyl Alcohol - chemistry
Porosity
porous mesh
Surgical Mesh
Tensile Strength
tissue remodeling
Wound Healing
title Double‐Layer Asymmetric Porous Mesh with Dynamic Mechanical Support Properties Enables Efficient Single‐Stage Repair of Contaminated Abdominal Wall Defect
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