Immunomodulation of wound healing leading to efferocytosis

Zhao, Yun; Li, Minxiong; Mao, Jiayi; Su, Yinghong; Huang, Xin; Xia, Wenzheng; Leng, Xiangfeng; Zan, Tao

doi:10.1002/smmd.20230036

Smart Medicine

2024

DOI: 10.1002/smmd.20230036

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Immunomodulation of wound healing leading to efferocytosis

Yun Zhao,

Minxiong Li,

Jiayi Mao

et al.

Abstract: Effectively eliminating apoptotic cells is precisely controlled by a variety of signaling molecules and a phagocytic effect known as efferocytosis. Abnormalities in efferocytosis may bring about the development of chronic conditions, including angiocardiopathy, chronic inflammatory diseases and autoimmune diseases. During wound healing, failure of efferocytosis leads to the collection of apoptosis, the release of necrotic material and chronic wounds that are difficult to heal. In addition to the traditional ph… Show more

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Cited by 9 publications

References 116 publications

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Grid Efferocytosis via Near‐Field Electrostatic Printing Rectifies Skin Immunity

Li,

Wang

et al. 2024

Adv Funct Materials

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Efferocytosis, by phagocytosing and processing apoptotic cells in injured skin, directly influences the immune microenvironment. However, the comprehensive widespread inflammation and disrupted efferocytosis in injured skin cannot be effectively halted. Herein, “Grid Efferocytosis” strategy within injury site is proposed, which segments the inflammation regulatory into grid microdomains, and further rectifies intra‐grid immune microenvironment to accelerate tissue repair. GelMA/PLA/Laponite gridded fiber membranes (GPL) are custom‐designed via near‐field electrostatic printing, and then coated with HAMA‐PBA/EGCG hydrogel by photo‐crosslinking and dynamic borate bonding to form a composite fiber membrane (GPL‐E). Gridded modulation via GPL‐E confines the entire chaotic inflammatory microenvironment into controllable microinflammatory niches. Leveraging the hydrogel coating and boronic ester bond dissociation induced by microenvironmental glucose and reactive oxygen species, GPL‐E achieves dynamic anti‐glucose and anti‐oxidation within microdomains, reconstructing macrophage efferocytosis. Notably, the “grid efferocytosis” recruits repair cells into the grid by magnesium ion release triggered by Laponite exposure on fibers, and enhances endothelial cell vascularization by ≈2.5‐fold. In a mouse diabetic ischemic flap model, implantation of grid GPL‐E maintains flap‐to‐base fusion, attenuates inflammatory infiltration & spread, and improves blood perfusion for flap survival. This study demonstrates that “Grid Efferocytosis” rectifies the immune microenvironment, fostering tissue repair and regeneration.

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Grid Efferocytosis via Near‐Field Electrostatic Printing Rectifies Skin Immunity

Li,

Wang

et al. 2024

Adv Funct Materials

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Activating Macrophage Continual Efferocytosis via Microenvironment Biomimetic Short Fibers for Reversing Inflammation in Bone Repair

Wang,

Zhang,

Zhang

et al. 2024

Advanced Materials

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Efferocytosis‐mediated inflammatory reversal plays a crucial role in bone repairing process. However, in refractory bone defects, the macrophage continual efferocytosis may be suppressed due to the disrupted microenvironment homeostasis, particularly the loss of apoptotic signals and overactivation of intracellular oxidative stress. In this study, we present a polydopamine‐coated short fiber matrix containing biomimetic “apoptotic signals” to reconstruct the microenvironment and reactivate macrophage continual efferocytosis for inflammatory reversal and bone defect repair. The “apoptotic signals” (AM/CeO2) are prepared using CeO2 nanoenzymes with apoptotic neutrophil membrane coating for macrophage recognition and oxidative stress regulation. Additionally, a short fiber “biomimetic matrix” is utilized for loading AM/CeO2 signals via abundant adhesion sites involving π‐π stacking and hydrogen bonding interactions. Ultimately, the implantable apoptosis‐mimetic nanoenzyme/short‐fiber matrixes (PFS@AM/CeO2), integrating apoptotic signals and biomimetic matrixes, are constructed to facilitate inflammatory reversal and reestablish pro‐efferocytosis microenvironment. In vitro and in vivo data indicate that the microenvironment biomimetic short fibers could activate macrophage continual efferocytosis, leading to the suppression of overactivated inflammation. The enhanced repair of rat femoral defect further demonstrates the osteogenic potential of pro‐efferocytosis strategy. We believe that the regulation of macrophage efferocytosis through microenvironment biomimetic materials could provide a new perspective for tissue repair.This article is protected by copyright. All rights reserved

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A Portable, Sprayable, Highly Malleable, Elastic, and Hydrophobic Antibacterial Fibrous Wound Dressing for Infected Wound Healing

Zhang,

Yang,

Wang

et al. 2024

Adv. Fiber Mater.

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Immunomodulation of wound healing leading to efferocytosis

Cited by 9 publications

References 116 publications

Grid Efferocytosis via Near‐Field Electrostatic Printing Rectifies Skin Immunity

Grid Efferocytosis via Near‐Field Electrostatic Printing Rectifies Skin Immunity

Activating Macrophage Continual Efferocytosis via Microenvironment Biomimetic Short Fibers for Reversing Inflammation in Bone Repair

A Portable, Sprayable, Highly Malleable, Elastic, and Hydrophobic Antibacterial Fibrous Wound Dressing for Infected Wound Healing

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