超声空化触发载药氟碳纳米液滴的选择性胞内递送以降低细胞毒性阈值。

Selective intracellular delivery of perfluorocarbon nanodroplets for cytotoxicity threshold reduction on ultrasound-induced vaporization.

机构信息

Medical Device Development and Regulation Research Center, The University of Tokyo, Tokyo, Japan.

Research Center for Advanced Science and Technology, The University of Tokyo, Tokyo, Japan.

出版信息

Cancer Rep (Hoboken). 2019 Aug;2(4):e1165. doi: 10.1002/cnr2.1165. Epub 2019 Feb 17.

DOI:10.1002/cnr2.1165

PMID:32721118

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7941471/

Abstract

BACKGROUND

Phase-change nanodroplets (PCNDs), which are liquid perfluorocarbon nanoparticles, have garnered much attention as ultrasound-responsive nanomedicines. The vaporization phenomenon has been employed to treat tumors mechanically. However, the ultrasound pressure applied to induce vaporization must be low to avoid damage to nontarget tissues.

AIMS

Here, we report that the pressure threshold for vaporization to induce cytotoxicity can be significantly reduced by selective intracellular delivery of PCNDs into targeted tumors.

METHODS AND RESULTS

In vitro experiments revealed that selective intracellular delivery of PCNDs induced PCND aggregation specifically inside the targeted cells. This close-packed configuration decreased the pressure threshold for vaporization to induce cytotoxicity. Moreover, following ultrasound exposure, significant decrease was observed in the viability of cells that incorporated PCNDs (35%) but not in the viability of cells that did not incorporate PCNDs (88%).

CONCLUSIONS

Intracellular delivery of PCNDs reduced ultrasound pressure applied for vaporization to induce cytotoxicity. Confocal laser scanning microscopy and flow cytometry revealed that prolonged PCND-cell incubation increased PCND uptake and aggregation. This aggregation effect might have contributed to the cytotoxicity threshold reduction effect.

摘要

背景

作为超声响应型纳米药物，相变型纳米液滴（PCND），即液态全氟碳纳米颗粒，受到了广泛关注。已经利用其蒸发现象对肿瘤进行机械治疗。但是，为了避免对非靶组织造成损伤，必须应用低超声压力来诱导其蒸发。

目的

本文报道，通过将 PCND 选择性递送至靶肿瘤细胞内，可显著降低诱导细胞毒性的蒸发所需的压力阈值。

方法和结果

体外实验表明，PCND 的选择性细胞内递送至靶细胞内可特异性诱导 PCND 聚集。这种紧密堆积的结构降低了诱导细胞毒性所需的蒸发压力阈值。此外，在超声暴露后，观察到纳入 PCND 的细胞（35%）的活力显著下降，而未纳入 PCND 的细胞（88%）的活力没有明显下降。

结论

PCND 的细胞内递送降低了用于诱导细胞毒性的蒸发所应用的超声压力。共聚焦激光扫描显微镜和流式细胞术显示，延长 PCND-细胞孵育时间可增加 PCND 的摄取和聚集。这种聚集效应可能有助于降低细胞毒性的阈值效应。

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