A Self-hygroscopic, Rapidly Self-gelling Polysaccharide-based Sponge with Robust Wet Adhesion for Non-compressible Hemorrhage Control and Infected Wounds Healing

Overview

Journal Bioact Mater

Date 2025 Jan 15

PMID 39811462

Authors

Xiong-Xin Lei

Meng-Long Liu

Chao-Feng Lu

Li-Li Han

Jie-Zhi Jia

Zheng Li

Na Xu

Jiang-Feng Li

Xuan-Jian Fu

Ya-Bin Jin

Ri-Kuan Tong

Yun-Long Yu

Gao-Xing Luo

Yang Chen

Affiliations

Soon will be listed here.

Abstract

Uncontrollable non-compressible hemorrhage and traumatic infection have been major causes of mortality and disability in both civilian and military populations. A dressing designed for point-of-care control of non-compressible hemorrhage and prevention of traumatic infections represents an urgent medical need. Here, a novel self-gelling sponge OHN@ε-pL is developed, integrating N-succinimidyl ester oxidized hyaluronic acid (OHN) and ε-poly-L-lysine (ε-pL). Upon application to the wound site, the sponge can rapidly absorb interfacial fluids and undergo a phase transition from sponge to gel. The transformed gel facilitates robust tissue adhesion and achieves synergistic hemostasis by enriching coagulation factors within the sponge phase and providing a barrier effect in the gel phase. The in vitro and in vivo studies revealed that the optimized OHN@ε-pL sponge possesses self-gelling capability, tissue adhesion, enhanced coagulation ability, and exhibits excellent biocompatibility and antibacterial efficacy. In hemostasis, OHN@ε-pL sponges exhibited reduced blood loss and decreased hemostatic time compared to commercial hemostatic agents, as demonstrated in rat liver, femoral vein, and tail truncation bleeding models. Furthermore, the OHN@ε-pL sponge exhibited superior performance in accelerating wound closure and healing of -infected wounds. Collectively, OHN@ε-pL sponges represent a promising candidate for medical dressings, specifically for managing uncontrollable non-compressible hemorrhage and traumatic infections.

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