Litcius/Paper detail

Hyaluronan-Based Rapid-Gelling Hemostatic Powder to Bridge Dynamic Wound Sealing and Tissue Regeneration

Kai Wu, Junhao Li, Hanzhang Ran, Chen Zhao, Jiaze Gao, Yuan Tian, Chengheng Wu, Jie Ding, Dan Wei, Yunlong Yu, Yanfei Tan, Jing Sun, Hongsong Fan

2025Biomacromolecules7 citationsDOI

Abstract

Hemostatic materials combining rapid bleeding control with regenerative potential remain a major clinical need. Here, we report a bioinspired hemostatic powder (GSHD) engineered through molecular conjugation of thiolated gelatin and dopamine-modified hyaluronic acid. Upon contact with biofluids, GSHD rapidly gels via dynamic thiol-catechol cross-linking, achieving ultrafast hydration (<5 s) and forming a robust hydrogel. This hydrogel exhibits high blood absorption (569.2 ± 46.3%), strong tissue adhesion (28.3 ± 3 kPa), and burst pressure resistance (216.2 ± 10.5 mmHg), enabling effective sealing under high-flow conditions. In vivo tests in rat liver, cardiac, and femoral artery models show rapid hemostasis (<30 s) with minimal blood loss. Additionally, GSHD promotes M2 macrophage polarization, enhances angiogenesis, and supports organized collagen deposition, facilitating tissue regeneration. By integrating rapid sealing, antioxidant activity, and biomimetic extracellular matrix cues, GSHD represents a paradigm shift in hemostatic design, bridging emergency care with functional tissue repair.

Topics & Concepts

Hyaluronic acidHemostasisRegeneration (biology)ChemistryExtracellular matrixBiomedical engineeringGelatinSelf-healing hydrogelsWound healingIn vivoTissue engineeringRegenerative medicineAngiogenesisBiophysicsNanotechnologyMaterials scienceBiochemistryCell biologySurgeryAnatomyPolymer chemistryCellMedicineCancer researchBiotechnologyBiologyHemostasis and retained surgical itemsWound Healing and TreatmentsElectrospun Nanofibers in Biomedical Applications