Biomimetic nanoengineered scaffold for enhanced full-thickness cutaneous wound healing

[Display omitted] Wound healing is a complex process based on the coordinated signaling molecules and dynamic interactions between the engineered scaffold and newly formed tissue. So far, most of the engineered scaffolds used for the healing of full-thickness skin wounds do not mimic the natural ext...

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Bibliographic Details
Published in:Acta biomaterialia 2021-04, Vol.124, p.191-204
Main Authors: Zandi, Nooshin, Dolatyar, Banafsheh, Lotfi, Roya, Shallageh, Yousef, Shokrgozar, Mohammad Ali, Tamjid, Elnaz, Annabi, Nasim, Simchi, Abdolreza
Format: Article
Language:English
Subjects:
Bilayers
Biomimetics
Complexity
Controlled release
Dermis
Drug delivery
Epidermal growth factor
Epidermis
Extracellular matrix
Gelatin
Growth factor
Growth factors
Hydrogel
Hydrogels
Immobilization
Modulus of elasticity
Nanofiber
Nanofibers
Photocurable nanocomposite
Regeneration
Scaffolds
Skin
Skin repair
Sustained release
Thickness
Tissue engineering
Tissue Scaffolds
Tissues
Wound Healing
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Summary:[Display omitted] Wound healing is a complex process based on the coordinated signaling molecules and dynamic interactions between the engineered scaffold and newly formed tissue. So far, most of the engineered scaffolds used for the healing of full-thickness skin wounds do not mimic the natural extracellular matrix (ECM) complexity and therefore are not able to provide an appropriate niche for endogenous tissue regeneration [1]. To address this gap and to accelerate the wound healing process, we present biomimetic bilayer scaffolds compositing of gelatin nanofibers (GFS) and photocrosslinkable composite hydrogels loaded with epidermal growth factors (EGF). The nanofibers operate as the dermis layer, and EGF-loaded composite hydrogels acted as the epidermis matrix for the full-thickness wound healing application. The hydrogels are composed of gelatin metacryloyl (GelMA) modified with silicate nanoplatelets (Laponite). To overcome the challenges of transdermal delivery of EGF, including short half-life and lack of efficient formulation precise, controlled delivery was attained by immobilization of EGF on Laponite. It is shown that the addition of 1wt% silicate nanoplatelet increases the compressive modulus of the hydrogels by 170%. In vitro wound closure analysis also demonstrated improved adhesion of the scaffolds to the native tissue by 3.5 folds. Moreover, the tunable hemostatic ability of the scaffolds due to the negatively charged nanoplatelets is shown. In an established excisional full-thickness wound model, an enhanced wound closure (up to 93.1 ± 1.5%) after 14 days relative to controls (GFS and saline-treated groups) is demonstrated. The engineered adhesive and hemostatic scaffolds with sustained release of the growth factors have the potential to stimulate complete skin regeneration for full-thickness wound healing.
ISSN:1742-7061
1878-7568
DOI:10.1016/j.actbio.2021.01.029