组织工程血管贴片:绵羊模型的比较特性和临床前试验结果

L. Antonova, A. Mironov, A. Shabaev, V. Silnikov, E. Krivkina, V. Matveeva, E. Velikanova, E. A. Senokosova, M. Khanova, V. Sevostyanova, T. V. Glushkova, R. Mukhamadiyarov, L. Barbarash
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引用次数: 0

摘要

颈动脉内膜切除术联合膜片血管成形术是治疗颈动脉狭窄最有效的方法。然而,现有血管贴片的使用往往伴有血栓形成、再狭窄、钙化等并发症。目的:研制含有血管内皮生长因子(VEGF)或精氨酸酰甘氨酸-天冬氨酸(RGD)的可生物降解动脉重建贴片,并在体外实验和大型实验动物模型临床前试验中比较评价其生物相容性和疗效。材料和方法。以聚3-羟基丁酸-co-3-羟戊酸酯(PHBV)和聚ε-己内酯(PCL)为原料,采用静电纺丝法制备了生物可降解的贴片,并以不同构型的VEGF或肽序列RGD进行修饰。体外实验对其表面结构、物理力学性能和血液相容性进行了评价。在体内实验中,我们评估了植入12只羊颈动脉6个月后形成的血管贴片的有效性。用组织学和免疫荧光法对移植标本的重塑质量进行评价。PHBV/PCL/VEGF贴片具有更接近天然血管的物理力学特性,其生物功能化方法与未修饰的PHBV/PCL贴片相比,强度特性下降最小。RGD肽的修饰使聚合物贴片的强度降低了2倍,而不影响其应力-应变行为。在聚合物纤维中掺入VEGF可减少血小板与PHBV/PCL/VEGF贴片表面接触时的聚集,并没有增加红细胞溶血。植入羊颈动脉6个月时,PHBV/PCL/ VEGF贴片形成完整的新生血管组织,无相关炎症和钙化迹象。这表明VEGF并入贴片的效率很高。相比之下,不同构型RGD肽修饰的贴片在聚合物支架的生物吸收过程中出现了新内膜增生和慢性肉芽肿性炎症。与PHBV/PCL/RGD贴片相比,PHBV/PCL/VEGF贴片具有更好的生物相容性,更适合血管壁重建。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Tissue-engineered vascular patches: comparative characteristics and preclinical test results in a sheep model
Carotid endarterectomy (CEA) with patch angioplasty is the most effective treatment for carotid artery stenosis. However, the use of existing vascular patches is often associated with thrombosis, restenosis, calcification and other complications.Objective: to develop biodegradable patches for arterial reconstruction, containing vascular endothelial growth factor (VEGF) or arginyl-glycyl-aspartic acid (RGD), and comparatively evaluate their biocompatibility and efficacy in in vitro experiments and during preclinical trials in large laboratory animal models.Materials and methods. Biodegradable patches, made from a mixture of poly(3-hydroxybutyrate-co-3- hydroxyvalerate (PHBV) and poly(ε-caprolactone) (PCL), were fabricated by electrospinning and modified with VEGF or the peptide sequence RGD in different configurations. In in vitro experiments, the surface structure, physicomechanical and hemocompatibility properties were evaluated. In in vivo experiments, we evaluated the effectiveness of the developed vascular patches for 6 months after implantation into the carotid artery of 12 sheep. The quality of remodeling was assessed using histological and immunofluorescence studies of explanted specimens.Results. The PHBV/PCL/VEGF patches had physicomechanical characteristics closer to those of native vessels and their biofunctionalization method resulted in the smallest drop in strength characteristics compared with their unmodified PHBV/PCL counterparts. Modification with RGD peptides reduced the strength of the polymer patches by a factor of 2 without affecting their stress-strain behavior. Incorporation of VEGF into polymer fibers reduced platelet aggregation upon contact with the surface of the PHBV/PCL/VEGF patches and did not increase erythrocyte hemolysis. At month 6 of implantation into the carotid artery of sheep, the PHBV/PCL/ VEGF patches formed a complete newly formed vascular tissue without signs of associated inflammation and calcification. This indicates the high efficiency of the VEGF incorporated into the patch. In contrast, the patches modified with different configurations of RGD peptides combined the presence of neointimal hyperplasia and chronic granulomatous inflammation present in the patch wall and developed during bioresorption of the polymer scaffold.Conclusion. PHBV/PCL/VEGF patches have better biocompatibility and are more suitable for vascular wall reconstruction than PHBV/PCL/RGD patches.
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