图像引导纳米治疗递送中的激活策略

S. Choi
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引用次数: 2

摘要

治疗纳米材料是在图像引导下进行药物递送的重要平台。尽管有着显著的增长和广泛的应用,但它们的设计细节仍然是人们持续关注的主题,这主要是由于所涉及的多功能因素,从纳米材料特性、成像模式、治疗剂到激活策略。这篇综述文章总结了关于其设计特征的关键发现,特别是对治疗激活(释放)策略的研究。首先,可以使用包括低pH和谷胱甘肽在内的内源性因子或通过光、超声或电磁场的外部刺激来控制它们的激活。与后者相比,前者是从时空方面被动控制的,后者在其他方面是通过药物连接体光解、纳米材料分解或栅极打开主动控制的。其次,光刺激是一种最显著的策略,因为它在控制药物释放、光热激活(热疗)和活性氧(ROS)的光动力产生中发挥着重要作用。第三,一些依赖于超声波、光热、光声、磁场或X射线辐射的激活策略由于其在成像模式中的作用而具有双重功能。总之,这篇综述文章介绍了纳米治疗递送系统的最新进展和新见解。它还解决了与组织穿透(光)、空间分辨率(超声、热疗)和细胞抵抗(ROS)发生相关的技术限制。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Activation Strategies in Image-Guided Nanotherapeutic Delivery
Therapeutic nanomaterials serve as an important platform for drug delivery under image guidance. Despite significant growth and broad applications, their design specifics remain a subject of continued interest primarily due to multifunctional factors involved, ranging from nanomaterial properties, imaging modalities, and therapeutic agents to activation strategies. This review article summarizes key findings on their design characteristics with a particular interest in strategies developed for therapeutic activation (release). First, their activation can be controlled using either an endogenous factor including low pH and glutathione or an external stimulation by light, ultrasound, or electromagnetic field. The former is passively controlled from a spatiotemporal aspect compared to the latter, which is otherwise actively controlled through drug linker photolysis, nanomaterial disassembly, or gate opening. Second, light stimulation serves a most notable strategy due to its essential role in controlled drug release, photothermal activation (hyperthermia), and photodynamic production of reactive oxygen species (ROS). Third, some of those activation strategies that rely on ultrasound, photothermal, photoacoustic, magnetic field, or X-ray radiation are dually functional due to their role in imaging modalities. In summary, this review article presents recent advances and new insights that pertain to nanotherapeutic delivery systems. It also addresses their technical limitations associated with tissue penetration (light), spatial resolution (ultrasound, hyperthermia), and occurrence of cellular resistance (ROS).
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