Advances on the modification and biomedical applications of acellular dermal matrices

Liu, Xinhua; Zheng, Xin; Huang, Xuantao; Dan, Weihua; Li, Zhengjun; Dan, Nianhua; Wang, Yunbing

doi:10.1186/s42825-022-00093-4

Cited by 7 publications

(9 citation statements)

References 102 publications

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“…Both single-point masking and multipoint crosslinking have covalent crosslinking bonds, but in single-point masking, only one active group in the crosslinker molecule has covalent crosslinking with a certain active group of collagens, which can modify and fill collagen but has little effect on improving structural stability. While multipoint crosslinking refers to the covalent reaction between two or more active groups in a crosslinker molecule and the active sites on collagen, which can stabilize the structure and improve the thermal stability of collagen. , The DSC results show that the T d of HTCC-pADM is not much different from that of pADM, owing to the lack of active group that can covalently react with collagen fibers in HTCC, only physical adsorption and hydrogen bonding exist, and may be eluted during the cleaning process of the material. The T d of OHTCC-pADM increased to varying degrees because OHTCC contained active aldehyde groups that could covalently crosslink with collagen fibers in pADM, which could produce single-point masking and multipoint crosslinking to improve the thermal stability of collagen.…”

Section: Results and Discussionmentioning

confidence: 99%

“…Ideal tissue engineering skin scaffolds should have comprehensive therapeutic effects and multiple functions, including biostable and long-lasting antimicrobial activity; extracellular matrix (ECM) mimics to promote cell migration, angiogenesis, and collagen deposition bionic structure; and appropriate mechanical properties, in order to play an effective role in the repair of full-thickness skin defect . Acellular dermal matrix (ADM) is obtained from human or animal dermal tissue by removing epidermal and intradermal cellular components but retaining the ECM structure . And thus, ADM produces negligible inflammatory response and prevents rejection of the transplanted tissue. , Nature collagen fibers, as the main component of ADM, have natural woven and porous structures, which produce biomimetic microenvironment similar to natural tissues and can promote cell adhesion and proliferation significantly .…”

Section: Introductionmentioning

confidence: 99%

“…4 Acellular dermal matrix (ADM) is obtained from human or animal dermal tissue by removing epidermal and intradermal cellular components but retaining the ECM structure. 5 And thus, ADM produces negligible inflammatory response and prevents rejection of the transplanted tissue. 6,7 Nature collagen fibers, as the main component of ADM, have natural woven and porous structures, which produce biomimetic microenvironment similar to natural tissues and can promote cell adhesion and proliferation significantly.…”

Section: Introductionmentioning

confidence: 99%

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Converting Acellular Dermal Matrix into On-Demand Versatile Skin Scaffolds by a Balanceable Crosslinking Approach for Integrated Infected Wounds Therapy

et al. 2023

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Ideal tissue-engineered skin scaffolds should possess integrated therapeutic effects and multifunctionality, such as broad-spectrum antibacterial properties, adjustable mechanical properties, and bionic structure. Acellular dermal matrix (ADM) has been broadly used in many surgical applications as an alternative treatment to the “gold standard” tissue transplantation. However, insufficient broad-spectrum antibacterial and mechanical properties for therapeutic efficacy limit the practical clinical applications of ADM. Herein, a balanceable crosslinking approach based on oxidized 2-hydroxypropyltrimethyl ammonium chloride chitosan (OHTCC) was developed for converting ADM into on-demand versatile skin scaffolds for integrated infected wounds therapy. Comprehensive experiments show that different oxidation degrees of OHTCC have significative influences on the specific origins of OHTCC-crosslinked ADM scaffolds (OHTCC-ADM). OHTCC with an oxidation degree of about 13% could prosperously balance the physiochemical properties, antibacterial functionality, and cytocompatibility of the OHTCC-ADM scaffolds. Owing to the natural features and comprehensive crosslinking effects, the proposed OHTCC-ADM scaffolds possessed the desirable multifunctional properties, including adjustable mechanical, degradable characteristics, and thermal stability. In vitro/in vivo biostudies indicated that OHTCC-ADM scaffolds own well-pleasing broad-spectrum antibacterial performances and play effectively therapeutic roles in treating infection, inhibiting inflammation, promoting angiogenesis, and promoting collagen deposition to enhance the infected wound healing. This study proposes a facile balanceable crosslinking approach for the design of ADM-based versatile skin scaffolds for integrated infected wounds therapy.

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Section: Results and Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Converting Acellular Dermal Matrix into On-Demand Versatile Skin Scaffolds by a Balanceable Crosslinking Approach for Integrated Infected Wounds Therapy

et al. 2023

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“…Chest wall defects are frequently caused by tumor herniation and resection (1,2,21,29,30,(81)(82)(83)(84)(85)(86)(87)(88)(89)(90)(91). Defects in the chest wall impair the strong framework that supports breathing and safeguards the viscera (92). Loss of chest wall integrity leads to devastating complications such as lung hernia, hemithorax shrinkage, and paradoxical chest wall motion (50).…”

Section: Chestmentioning

confidence: 99%

Acellular dermal matrix in reconstructive surgery: Applications, benefits, and cost

Mohammadyari

Parvin²,

Khorvash³

et al. 2023

Front. Transplant.

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Modern tissue engineering has made substantial advancements that have revolutionized plastic surgery. Acellular dermal matrix (ADM) is an example that has gained considerable attention recently. ADM can be made from humans, bovines, or porcine tissues. ADM acts as a scaffold that incorporates into the recipient tissue. It is gradually infiltrated by fibroblasts and vascularized. Fortunately, many techniques have been used to remove cellular and antigenic components from ADM to minimize immune system rejection. ADM is made of collagen, fibronectin, elastin, laminin, glycosaminoglycans, and hyaluronic acid. It is used in critical wounds (e.g., diabetic wounds) to protect soft tissue and accelerate wound healing. It is also used in implant-based breast reconstruction surgery to improve aesthetic outcomes and reduce capsule contracture risk. ADM has also gained attention in abdominal and chest wall defects. Some studies have shown that ADM is associated with less erosion and infection in abdominal hernias than synthetic meshes. However, its higher cost prevents it from being commonly used in hernia repair. Also, using ADM in tendon repair (e.g., Achilles tendon) has been associated with increased stability and reduced rejection rate. Despite its advantages, ADM might result in complications such as hematoma, seroma, necrosis, and infection. Moreover, ADM is expensive, making it an unsuitable option for many patients. Finally, the literature on ADM is insufficient, and more research on the results of ADM usage in surgeries is needed. This article aims to review the literature regarding the application, Benefits, and costs of ADM in reconstructive surgery.

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“…Natural animal skin is a renewable biomass with collagen as the main component and with hierarchical collagen fibers of 3D as the main network structure, which has the advantages of high strength, flexibility, bio‐friendliness, and an extensive range of sources, [ 16,17 ] and is widely used in biomedical materials, [ 18 ] food, [ 19 ] cosmetic, [ 20 ] and leather industry. [ 21 ] Traditionally, animal skin is utilized to extract type I collagen molecules.…”

Section: Introductionmentioning

confidence: 99%

Multifunctional, Ultra‐Tough Organohydrogel E‐Skin Reinforced by Hierarchical Goatskin Fibers Skeleton for Energy Harvesting and Self‐Powered Monitoring

Fan

Tao

2023

Adv Funct Materials

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E‐skins based on conductive hydrogels are regarded as ideal candidates for sensing application. However, limited by the constructed materials and strategies, the current conductive hydrogels have poor mechanical properties, single function, and unsatisfactory conductivity, which seriously hinder their development and application. Herein, the natural goatskin with hierarchical 3D network structure weaved by collagen fibers is used as the substrate material for the construction of ultra‐tough hydrogel through a “top‐down” strategy, in which acrylic acid monomer is first vacuum‐impregnated into the interstices of goatskin fibers skeleton and is then polymerized in situ to produce the skin‐based hydrogel with unique 3D wrapping structure. Based on the skin‐based hydrogel, a substrate with load‐carrying capacity, after loaded with a new multifunctional nanoscale‐conductive medium nanosilver particles (AgNPs) and 1,3‐propanediol, a goatskin‐derived multifunctional organohydrogel S@HCP is constructed with excellent mechanical properties, self‐adhesion, transparency, ultraviolet shielding, antibacterial, biocompatibility, environmental stability, and conductivity. Notably, the stretchable S‐TENG assembled using S@HCP can be perfectly suited for real‐life applications including biomechanical energy harvesting, self‐powered tactile‐sensing, and motion monitoring. It is believed that, by combining natural animal skin with different functional materials, it is possible to reuse animal skin, “dead skin,” which provides a new platform for developing multifunctional flexible e‐skin.

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Advances on the modification and biomedical applications of acellular dermal matrices

Cited by 7 publications

References 102 publications

Converting Acellular Dermal Matrix into On-Demand Versatile Skin Scaffolds by a Balanceable Crosslinking Approach for Integrated Infected Wounds Therapy

Converting Acellular Dermal Matrix into On-Demand Versatile Skin Scaffolds by a Balanceable Crosslinking Approach for Integrated Infected Wounds Therapy

Acellular dermal matrix in reconstructive surgery: Applications, benefits, and cost

Multifunctional, Ultra‐Tough Organohydrogel E‐Skin Reinforced by Hierarchical Goatskin Fibers Skeleton for Energy Harvesting and Self‐Powered Monitoring

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