Yuan Peng scite author profile

Excessive production of inflammatory chemokines and reactive oxygen species (ROS) can cause a feedback cycle of inflammation response that has a negative effect on cutaneous wound healing. The use of wound-dressing materials that simultaneously absorb chemokines and scavenge ROS constitutes a novel ‘weeding and uprooting’ treatment strategy for inflammatory conditions. In the present study, a composite hydrogel comprising an amine-functionalized star-shaped polyethylene glycol (starPEG) and heparin for chemokine sequestration as well as Cu 5.4 O ultrasmall nanozymes for ROS scavenging (Cu 5.4 O@Hep-PEG) was developed. The material effectively adsorbs the inflammatory chemokines monocyte chemoattractant protein-1 and interleukin-8, decreasing the migratory activity of macrophages and neutrophils. Furthermore, it scavenges the ROS in wound fluids to mitigate oxidative stress, and the sustained release of Cu 5.4 O promotes angiogenesis. In acute wounds and impaired-healing wounds (diabetic wounds), Cu 5.4 O@Hep-PEG hydrogels outperform the standard-of-care product Promogram® in terms of inflammation reduction, increased epidermis regeneration, vascularization, and wound closure.

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Engineering Bacteria‐Activated Multifunctionalized Hydrogel for Promoting Diabetic Wound Healing

Lü

Wang

et al. 2021

Adv Funct Materials

151

100

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Engineering therapeutic angiogenesis in impaired tissues is critical for chronic wound healing. Materials can be engineered to deliver specific biological cues that enhance angiogenesis. However, currently available materials have limitations for use in angiogenesis engineering since the complex inflammation environment of wounds requires spatiotemporal control. Immune cells are the central component of wound microenvironment and orchestrate immune responses to wound healing. This study presents a novel approach of using a delivery system comprising living Lactococcus, incorporated in a heparin‐poloxamer thermoresponsive hydrogel, designed to bioengineer the wound microenvironment and enhance the angiogenesis in a highly dynamic‐temporal manner. The living system can produce and protect vascular endothelial growth factor (VEGF) to increase proliferation, migration, and tube formation of endothelial cells, as well as secrete lactic acid to shift macrophages toward an anti‐inflammatory phenotype, resulting in successful angiogenesis in diabetic wounds. Further, the delivery system confines the bacterial population to wounds, thereby minimizing the risk of systemic toxicities. Therefore, this living hydrogel system can be harnessed for safe and efficient delivery of therapeutics that drive the wound microenvironment toward rapid healing and may serve as a promising scaffold in regenerative medicine.

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Yuan Peng

Xiaozhang Tie Improves Intestinal Motility in Rats With Cirrhotic Ascites by Regulating the Stem Cell Factor/c-kit Pathway in Interstitial Cells of Cajal

Construction of heparin-based hydrogel incorporated with Cu5.4O ultrasmall nanozymes for wound healing and inflammation inhibition

Engineering Bacteria‐Activated Multifunctionalized Hydrogel for Promoting Diabetic Wound Healing

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