依替巴肽包裹于RGD修饰的纳米脂质体中可提高血小板聚集抑制活性。

Encapsulation of eptifibatide in RGD-modified nanoliposomes improves platelet aggregation inhibitory activity.

作者信息

Bardania Hassan, Shojaosadati Seyed Abbas, Kobarfard Farzad, Dorkoosh Farid, Zadeh Marjan Esfahani, Naraki Mahmoud, Faizi Mehrdad

机构信息

Department of Nanobiotechnology, Faculty of Biological Sciences, Tarbiat Modares University, Tehran, Iran.

Cellular and Molecular Research Center, Yasuj University of Medical Sciences, Yasuj, Iran.

出版信息

J Thromb Thrombolysis. 2017 Feb;43(2):184-193. doi: 10.1007/s11239-016-1440-6.

DOI:10.1007/s11239-016-1440-6

PMID:27778144

Abstract

Eptifibatide is an antiplatelet drug used for the treatment of thrombosis. However, as a result of its accumulation in non-targeted tissues and short half-life, it has a limited efficacy. In this study, RGD-modified nano-liposomes (RGD-MNL) were prepared as carriers for the targeted delivery of eptifibatide to activated platelets. The nano-liposomes were about 90 ± 10 nm in size, with an encapsulation efficiency of 37 ± 5 % and a good stability during 21 days, with a negligible change in the size of nanoliosomes. The in vitro cytotoxicity of nanoliposomes was examined using MTT assay. The results obtained from the ex vivo study showed that the antiplatelet activity of eptifibatide encapsulated nanoliposomes was higher in comparison with the free drug (81.63 vs. 46.17 % for RGD-MNL) and (66.67 vs. 46.17 % for UNL), and this increase was more significant for nanoliposomes targeted with RGD peptide (81.63 %; p < 0.05). The results indicated that RGD-MNL encapsulated eptifibatide had no significant cytotoxic effect on cells. In conclusion, the present nanoliposome formulation can be regarded as a new delivery system for protection and enhancement of the antiplatelet activity of eptifibatide.

摘要

依替巴肽是一种用于治疗血栓形成的抗血小板药物。然而，由于其在非靶向组织中的蓄积以及半衰期较短，其疗效有限。在本研究中，制备了RGD修饰的纳米脂质体（RGD-MNL）作为依替巴肽靶向递送至活化血小板的载体。纳米脂质体大小约为90±10nm，包封率为37±5%，在21天内稳定性良好，纳米脂质体大小变化可忽略不计。使用MTT法检测纳米脂质体的体外细胞毒性。体外研究结果表明，与游离药物相比，包封依替巴肽的纳米脂质体的抗血小板活性更高（RGD-MNL为81.63%对46.17%）和（未修饰纳米脂质体为66.67%对46.17%），并且对于用RGD肽靶向的纳米脂质体这种增加更显著（81.63%；p<0.05）。结果表明，RGD-MNL包封的依替巴肽对细胞没有显著的细胞毒性作用。总之，目前的纳米脂质体制剂可被视为一种新的递送系统，用于保护和增强依替巴肽的抗血小板活性。

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依替巴肽包裹于RGD修饰的纳米脂质体中可提高血小板聚集抑制活性。

Encapsulation of eptifibatide in RGD-modified nanoliposomes improves platelet aggregation inhibitory activity.

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