Core‐Shell Gel Nanofiber Scaffolds Constructed by Microfluidic Spinning toward Wound Repair and Tissue Regeneration

Dong, Yue; Ding, Zongkun; Bai, Yuting; Lu, Ling‐Yu; Dong, Ting; Li, Qing; Liu, Ji‐Dong; Chen, Su

doi:10.1002/advs.202404433

Advanced Science

2024

DOI: 10.1002/advs.202404433

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Core‐Shell Gel Nanofiber Scaffolds Constructed by Microfluidic Spinning toward Wound Repair and Tissue Regeneration

Yue Dong,

Zongkun Ding,

Yuting Bai

et al.

Abstract: Growing demand for wound care resulting from the increasing chronic diseases and trauma brings intense pressure to global medical health service system. Artificial skin provides mechanical and microenvironmental support for wound, which is crucial in wound healing and tissue regeneration. However, challenges still remain in the clinical application of artificial skin since the lack of the synergy effect of necessary performance. In this study, a multi‐functional artificial skin is fabricated through microfluid… Show more

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Cited by 3 publications

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Electrical Microneedles for Wound Treatment

Wang,

Cai,

Fan

et al. 2024

Advanced Science

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Electrical stimulation has been hotpot research and provoked extensive interest in a broad application such as wound closure, tissue injury repair, and nerve engineering. In particular, immense efforts have been dedicated to developing electrical microneedles, which demonstrate unique features in terms of controllable drug release, real‐time monitoring, and therapy, thus greatly accelerating the process of wound healing. Here, a review of state‐of‐art research concerning electrical microneedles applied for wound treatment is presented. After a comprehensive analysis of the mechanisms of electrical stimulation on wound healing, the derived three types of electrical microneedles are clarified and summarized. Further, their applications in wound healing are highlighted. Finally, current perspectives and directions for the development of future electrical microneedles in improving wound healing are addressed.

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Electrical Microneedles for Wound Treatment

Wang,

Cai,

Fan

et al. 2024

Advanced Science

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A Multifunctional Nanocomplex as miRNA/Antibiotic Co‐Delivery System Based on Tetrahedral Framework DNA: Application to Infected Wound Healing

Lyu,

Wu,

Chen

et al. 2024

Small

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Infected wounds are a complex disease involving bacterial infections and dysregulated inflammation. However, current research has mostly focused on bacterial inhibition rather than on inflammation. Thus, combined therapeutic strategies with anti‐bacterial and anti‐inflammation efficacies are urgently needed. Antibiotics are the main treatment strategy for infections. However, the excessive use of antibiotics throughout the body can cause serious side effects. In addition, miRNA‐based therapeutics are superior for the treatment of wounds, but their rapid degradation and poor cellular uptake limit their clinical application. Tetrahedral framework DNA (tFNA) is an ideal drug delivery system owing to its excellent stability and remarkable transport ability. Herein, a novel multi‐functional miRNA and antibiotic co‐delivery system based on tFNA is presented for the first time, called B/L. B/L has heightened resistance to serum and excellent codelivery ability. After transdermal administration, B/L can specifically target TNF receptor‐associated factor 6(TRAF6) and IL‐1receptor‐associated kinase 1(IRAK1), thereby regulating nuclear factor kappa‐B (NF‐𝜿B) and thus effectively reducing inflammation and promoting the healing of infected wounds. This novel multi‐functional co‐delivery system provides a versatile, simple, biocompatible, and powerful platform for the personalized and combined treatment of multiple diseases.

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Multifunctional Nanofiber Membranes Constructed by Microfluidic Blow-Spinning to Inhibit Scar Formation at Early Intervention Stage

Wen,

Zhao,

Zhang

et al. 2024

ACS Appl. Mater. Interfaces

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Pathological scarring has been a challenge in skin injury repair since ancient times, and prophylactic treatment in the early stages of wound healing usually results in delayed wound healing. In this study, poly(ethylene oxide) (PEO) and chitosan (CTS) were used as carrier materials to construct multifunctional pirfenidone (PFD)/CTS/PEO (PCP) nanofiber membranes (NFMs) loaded with PFD by microfluidic blow-spinning (MBS). MBS is a good method for quickly, safely, and greenly constructing large-area manufacturing of inexpensive NFMs. PCP NFMs were uniform in external morphology, with diameters ranging from 200 to 500 nm. The encapsulation efficiency of the drug-loaded PCP NFMs was above 80%, which had a good slow release, visualization, water absorption, and biocompatibility. The inhibitory effect of PCP NFMs on normal human dermal fibroblasts was dose-dependent and inhibited the expression of the transforming growth factor-β1/SMAD family member 3 (TGF-β1/SMAD3) signaling pathway. PCP NFMs showed significant antibacterial effects against both Staphylococcus aureus and Escherichia coli. In the rabbit ear scar experiment, the wound healed about 70% on day 5 and almost completely on day 10 after PCP-3 NFMs treatment, with the thinnest scar tissue, skin color, tenderness close to normal tissue, and a Vancouver scar scale score of less than 5. PCP-3 NFMs had good effects on antiinflammatory, wound healing, and collagen-I deposition reducing effects. In conclusion, PCP-3 NFMs can both promote wound healing and intervene to inhibit pathological scarring in advance, making them a potential multifunctional wound dressing for early prevention and treatment of pathological scarring.

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Core‐Shell Gel Nanofiber Scaffolds Constructed by Microfluidic Spinning toward Wound Repair and Tissue Regeneration

Cited by 3 publications

References 64 publications

Electrical Microneedles for Wound Treatment

Electrical Microneedles for Wound Treatment

A Multifunctional Nanocomplex as miRNA/Antibiotic Co‐Delivery System Based on Tetrahedral Framework DNA: Application to Infected Wound Healing

Multifunctional Nanofiber Membranes Constructed by Microfluidic Blow-Spinning to Inhibit Scar Formation at Early Intervention Stage

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