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A novel thermosensitive growth-promoting collagen fibers composite hemostatic gel.

Xingyu YanYining ChenNianhua DanWeihua Dan
Published in: Journal of materials chemistry. B (2022)
As a feasible solution to massive blood loss in emergencies, ensuring the availability of absorbable exogenous topical hemostatic materials is a major current focus. Among the available materials, collagen is a surprising presence, but that does not mean that it is an ideal material from every aspect. Collagen fibers (CFs) and collagen have the same composition in terms of matter, but they have differing spatial structures and hierarchies. CFs can be directly seen as a slight advance on collagen, yet disadvantages relating to their mono-functionality and dosage form restrict their further utilization. It is worth noting that technology for extracting Bletilla striata polysaccharide (BSP), a natural derivative of Bletilla striata, is becoming more advanced. Based on extensive surveys and development studies, hydrogels can show extraordinary development flexibility. In particular, when it comes to wound adaptability and stimuli responsiveness, in situ gels show many advantages. Therefore, we introduced a collagen-based biocompatible and efficient thermosensitive hemostatic hydrogel material (COF). COF is a stable, safe, and bioactive material, and multiple characterization tests confirm this. Upon adjusting the ratios of different materials, COF-3, showing the most comprehensive performance, best in vitro hemostatic effects, good gelation speed, and good cell compatibility, was selected. COF-3 was applied during the in vivo hemostasis testing of a rat hemorrhage model, and COF-3 achieved hemostasis within 30 s. COF shows promising application and clinical potential, providing an effective route to the achievement of in vivo minimally invasive hemostasis and laying a solid foundation for the development of functional hemostatic gels.
Keyphrases
  • wound healing
  • tissue engineering
  • minimally invasive
  • drug delivery
  • hyaluronic acid
  • single cell
  • stem cells
  • climate change
  • cell therapy
  • mass spectrometry
  • extracellular matrix
  • drug release
  • heat stress