Abstract
This review looks at the use of fibrin in vascular tissue engineering (VTE). Autologous fibrin is one of the most affordable biopolymers because it can be obtained from peripheral blood by simple techniques. A description and comparative analysis of the methods and approaches for producing fibrin gel is provided. The ability of fibrin to promote cell attachment and migration, survival and angiogenesis, to accumulate growth factors and release them in a controlled manner, are unique and extremely useful in VTE. Fibrin gels can serve as a three-dimensional matrix molded in different sizes and shapes to be applied in a variety of ways, including as a scaffold, coating, or impregnation material. Fibrin’s high porosity and biodegradability allows controllable release of growth factors, yet fibrinolysis must be tightly regulated to avoid side effects. We discuss the main methods of regulating the rate of fibrinolysis, as well as possible side effects of such exposure. Low mechanical strength is the main limitation in using fibrin as a scaffold for vascular tissue engineering. Possible options for increasing the strength properties of fibrin matrix and evaluating their effectiveness are presented. We propose that unique biocompatibility and ideal biodegradation profile of fibrin justify its use as a scaffold material for developing an ideal fully autologous small-diameter tissue-engineered vascular graft.
Highlights
This review looks at the use of fibrin in vascular tissue engineering (VTE)
Autologous fibrin is one of the most affordable biopolymers because it can be obtained from peripheral blood by simple techniques
Fibrin gels can serve as a three-dimensional matrix molded in different sizes and shapes to be applied in a variety of ways, including as a scaffold, coating, or impregnation material
Summary
Продолжается активный поиск идеального мате‐ риала для тканевой сосудистой инженерии (ТСИ). Понимание значимости нормальных физиологи‐ ческих реакций сосудистой стенки в профилактике и борьбе с тромбозами, гиперплазией и воспалением сформировало целое направление в ТСИ, связанное с имитацией структуры и функции нативной артери‐ альной стенки при разработке сосудистых протезов нового поколения. В этих направ‐ лениях фибрин вызывает у исследователей особый интерес, поскольку он обладает набором уникаль‐ ных характеристик, которые делают его практически идеальным природным биологическим материалом для ТСИ [2]. Биоматериалы на основе фибрина обладают идеальной биосовместимостью, имеют высокое сродство к различным биологиче ским поверхностям, контролируемой биодеградации посредством фибринолиза, при этом продукты био‐ деградации нетоксичны [3]. Далее более подробно будут освещены свойства и особенности фибрина, имеющие принципиальное значение для ТСИ
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