AI Article Synopsis
- A fibrin-rich matrix forms after an injury to stop bleeding and support healing, but issues with fibrin network formation can lead to poor healing, especially in hemophilia.
- Platelet-like particles (PLPs) mimic platelet functions, enhancing clotting and aiding in wound healing by binding to fibrin and facilitating clot retraction.
- The study showed that PLPs improved the quality of clot networks and promoted cell migration in a hemophilia model, suggesting they could help improve healing in conditions with impaired fibrin formation.
Article Abstract
Following injury, a fibrin-rich provisional matrix is formed to stem blood loss and provide a scaffold for infiltrating cells, which rebuild the damaged tissue. Defects in fibrin network formation contribute to impaired healing outcomes, as evidenced in hemophilia. Platelet-fibrin interactions greatly influence fibrin network structure via clot contraction, which increases fibrin density over time. Previously developed hemostatic platelet-like particles (PLPs) are capable of mimicking platelet functions including binding to fibrin fibers, augmenting clotting, and inducing clot retraction. In this study, we aimed to apply PLPs within a plasma-based in vitro hemophilia B model of deficient fibrin network structure to determine the ability of PLPs to improve fibrin structure and wound healing responses within hemophilia-like abnormal fibrin network formation. PLP impact on structurally deficient clot networks was assessed via confocal microscopy, a micropost deflection model, atomic force microscopy and an in vitro wound healing model of early cell migration within a provisional fibrin matrix. PLPs improved clot network density, force generation, and stiffness, and promoted fibroblast migration within an in vitro model of early wound healing under hemophilic conditions, indicating that PLPs could provide a biomimetic platform for improving wound healing events in disease conditions that cause deficient fibrin network formation.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC7415593 | PMC |
| http://dx.doi.org/10.1016/j.jcis.2020.05.088 | DOI Listing |
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