Chronic diabetic wounds seriously threaten the health and life of human beings, however, it is challenging to develop pluripotent dressings that comprehensively remodel inflammation microenvironment, neovascularization and reepithelization to achieve high performance healing in diabetic wounds. Herein we construct a bioinspired polysaccharide coordinated hydrogel composed of bisphosphate-modified β-glucan (BG) with bioactive metal ions of Zn2+ and Mg2+, in which multiple chelation enables fast gelation, self-healing, and dynamically sealing wounds. In vitro Mg2+ release from BGM or BGMZ could promote intracellular uptake of Zn2+ through upregulating Zn2+-related transporter protein ZIP6 while intracellular Mg2+ remained relatively stable via downregulating the Mg2+ transporter protein of MagT1. The screened lead hydrogel BGMZ could substantially polarize proinflammatory M1 to prohealing M2 phenotypes by the main BG-downregulating NF-kB signaling pathway, and both Mg2+ and Zn2+ release from BGMZ synergistically promoted proliferation and angiogenesis by upregulating PI3K/Akt signaling pathway, facilitating the reepithelization and tissue remodeling. Remarkably, single BGMZ treatment performed full-thickness wound closure, fast granulation and dermis regeneration, optimal neovascularization and reepithelization, high levels of overall collagen and fibrous collagen-I, and dense hair follicles, thus achieving high performance prohealing in diabetic wounds. Consequently, this study opens a new avenue to design pluripotent polysaccharide hydrogel dressing for structures and functions remodeling of chronic and diabetic wounds.
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