AI Article Synopsis
- Platelet gel is beneficial in regenerative medicine for its growth factors that aid healing, but faces challenges such as poor mechanical strength and quick degradation.
- Combining platelet gels with silk fibroin gel addresses these issues by prolonging the release of growth factors and improving the mechanical properties of the gel.
- The study found that the silk-platelet gel enhanced cell infiltration and blood vessel formation in animal models, suggesting it could lead to better therapeutic applications in the future.
Article Abstract
Platelet gel, a fibrin network containing activated platelets, is widely used in regenerative medicine due the capacity of platelet-derived growth factors to accelerate and direct healing processes. However, limitations to this approach include poor mechanical properties, relatively rapid degradation, and the lack of control of release of growth factors at the site of injection. These issues compromise the ability of platelet gels for sustained function in regenerative medicine. In the present study, a combination of platelet gels with silk fibroin gel was studied to address the above limitations. Mixing sonicated silk gels with platelet gels extended the release of growth factors without inhibiting gel-forming ability. The released growth factors were biologically active and their delivery was modified further by manipulation of the charge of the silk protein. Moreover, the silk gel augmented both the rheological properties and compressive stiffness of the platelet gel, tuned by the silk concentration and/or silk/platelet gel ratio. Silk-platelet gel injections in nude rats supported enhanced cell infiltration and blood vessel formation representing a step towards new platelet gel formulations with enhanced therapeutic impact.
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|---|---|
| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC4004629 | PMC |
| http://dx.doi.org/10.1016/j.biomaterials.2013.12.065 | DOI Listing |
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