超声穿孔:通过超声空化来机械传递DNA。

Douglas L Miller, Sorin V Pislaru, James E Greenleaf
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引用次数: 346

摘要

非病毒基因转移方法的发展将是对基因治疗宝库的一个有价值的补充,特别是针对特定组织体积的局部靶向。超声可以通过声空化产生包括DNA传递在内的多种非热生物效应。空化泡可能在单细胞水平上诱导细胞死亡或短暂的膜渗透(声穿孔),以及微血管出血和组织结构破坏。应用声波穿孔技术将基因传递到细胞中需要控制空化活性。许多研究使用体外暴露系统进行,其中空化现象几乎无处不在。在体内,空化的产生和控制比较困难,但可以通过空化成核剂,如超声造影剂来增强。超声穿孔和超声增强基因传递已被报道用于广泛的条件,包括低频超声(千赫兹频率),碎石机冲击波,HIFU,甚至诊断超声(兆赫兹频率)。在体外,多种细胞系已被成功转染,并伴有细胞杀伤。在体内,最初的应用是癌症基因治疗,杀死细胞可以作为一种有用的同时治疗,以及心血管疾病。利用超声进行非病毒基因传递已在体外和哺乳动物系统中得到证实,这为临床医学开发新的基因治疗方法提供了基础和强大的前景。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Sonoporation: mechanical DNA delivery by ultrasonic cavitation.

Development of nonviral gene transfer methods would be a valuable addition to the gene-therapy armamentarium, particularly for localized targeting of specific tissue volumes. Ultrasound can produce a variety of nonthermal bioeffects via acoustic cavitation including DNA delivery. Cavitation bubbles may induce cell death or transient membrane permeabilization (sonoporation) on a single cell level, as well as microvascular hemorrhage and disruption of tissue structure. Application of sonoporation for gene delivery to cells requires control of cavitation activity. Many studies have been performed using in vitro exposure systems, for which cavitation is virtually ubiquitous. In vivo, cavitation initiation and control is more difficult, but can be enhanced by cavitation nucleation agents, such as an ultrasound contrast agent. Sonoporation and ultrasonically enhanced gene delivery has been reported for a wide range of conditions including low frequency sonication (kilohertz frequencies), lithotripter shockwaves, HIFU, and even diagnostic ultrasound (megahertz frequencies). In vitro, a variety of cell lines has been successfully transfected, with concomitant cell killing. In vivo, initial applications have been to cancer gene therapy, for which cell killing can be a useful simultaneous treatment, and to cardiovascular disease. The use of ultrasound for nonviral gene delivery has been demonstrated for a robust array of in vitro and mammalian systems, which provides a fundamental basis and strong promise for development of new gene therapy methods for clinical medicine.

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