Department of Cardiacthoracic, Transplantation and Vascular Surgery, 9177Hannover Medical School, Hannover, Germany.
Lower Saxony Centre for Biomedical Engineering, Implant Research and Development (NIFE), Hannover Medical School, Hannover, Germany.
J Biomater Appl. 2022 Jan;36(6):1126-1136. doi: 10.1177/08853282211046800. Epub 2021 Oct 7.
The generation of bio-/hemocompatible cardiovascular patches with sufficient stability and regenerative potential remains an unmet goal. Thus, the aim of this study was the generation and biomechanical evaluation of a novel cardiovascular patch composed of pressure-compacted fibrin with embedded spider silk cocoons.
Fibrin-based patches were cast in a customized circular mold. One cocoon of spider silk was embedded per patch during the casting process. After polymerization, the fibrin clot was compacted by 2 kg weight for 30 min resulting in thickness reduction from up to 2 cm to <1 mm. Tensile strength and burst pressure was determined after 0 weeks and 14 weeks of storage. A sewing strength test and a long-term load test were performed using a customized device to exert physiological pulsatile stretching of a silicon surface on which the patch had been sutured.
Fibrin patches resisted supraphysiological pressures of well over 2000 mmHg. Embedding of spider silk increased tensile force 1.8-fold and tensile strength 1.45-fold ( < .001), resulting in a final strength of 1.07 MPa and increased sewing strength. Storage for 14 weeks decreased tensile strength, but not significantly and suturing properties of the spider silk patches were satisfactory. The long-term load test indicated that the patches were stable for 4 weeks although slight reduction in patch material was observed.
The combination of compacted fibrin matrices and spider silk cocoons may represent a feasible concept to generate stable and biocompatible cardiovascular patches with regenerative potential.
具有足够稳定性和再生潜力的生物相容性/血液相容性心血管补片仍然是一个未满足的目标。因此,本研究的目的是开发一种由压缩纤维蛋白和嵌入蜘蛛丝茧组成的新型心血管补片,并对其进行生物力学评估。
纤维蛋白补片在定制的圆形模具中浇铸。在浇铸过程中,每个补片嵌入一个蜘蛛丝茧。聚合后,纤维蛋白凝块用 2kg 重量压实 30 分钟,厚度从高达 2cm 减少到<1mm。在储存 0 周和 14 周后,测定拉伸强度和爆裂压力。使用定制设备进行缝合强度测试和长期负荷测试,该设备对已缝合补片的硅表面施加生理脉动拉伸。
纤维蛋白补片能够抵抗超过 2000mmHg 的超生理压力。嵌入蜘蛛丝可使拉伸力增加 1.8 倍,拉伸强度增加 1.45 倍(<0.001),最终强度达到 1.07MPa,缝合强度增加。储存 14 周后,拉伸强度略有下降,但不显著,且蜘蛛丝补片的缝合性能令人满意。长期负荷测试表明,补片在 4 周内稳定,尽管观察到补片材料略有减少。
压缩纤维蛋白基质和蜘蛛丝茧的组合可能是一种可行的概念,可以生成具有再生潜力的稳定且生物相容性的心血管补片。
