Procoagulant and Antimicrobial Effects of Chitosan in Wound Healing.
Chih-Hsin WangJuin-Hong CherngChuan-Chieh LiuTong-Jing FangZhi-Jie HongShu-Jen ChangGang-Yi FanSheng-Der HsuPublished in: International journal of molecular sciences (2021)
Chitosan, a polysaccharide derived from chitin, has excellent wound healing properties, including intrinsic antimicrobial and hemostatic activities. This study investigated the effectiveness of chitosan dressing and compared it with that of regular gauze dressing in controlling clinically surgical bleeding wounds and profiled the community structure of the microbiota affected by these treatments. The dressings were evaluated based on biocompatibility, blood coagulation factors in rat, as well as antimicrobial and procoagulant activities, and the microbial phylogenetic profile in patients with abdominal surgical wounds. The chitosan dressing exhibited a uniformly fibrous morphology with a large surface area and good biocompatibility. Compared to regular gauze dressing, the chitosan dressing accelerated platelet aggregation, indicated by the lower ratio of prothrombin time and activated partial thromboplastin time, and had outstanding blood absorption ability. Adenosine triphosphate assay results revealed that the chitosan dressing inhibited bacterial growth up to 8 d post-surgery. Moreover, 16S rRNA-based sequencing revealed that the chitosan dressing effectively protected the wound from microbial infection and promoted the growth of probiotic microbes, thereby improving skin immunity and promoting wound healing. Our findings suggest that chitosan dressing is an effective antimicrobial and procoagulant and promotes wound repair by providing a suitable environment for beneficial microbiota.
Keyphrases
- wound healing
- staphylococcus aureus
- microbial community
- randomized controlled trial
- systematic review
- single cell
- drug delivery
- minimally invasive
- coronary artery disease
- coronary artery bypass
- high resolution
- acute coronary syndrome
- percutaneous coronary intervention
- atomic force microscopy
- high speed
- tissue engineering