低强度超声对活细胞影响的比较分析:从模拟到实验

IF 3 4区 医学 Q3 ENGINEERING, BIOMEDICAL
Giulia Tamboia, Michele Campanini, Veronica Vighetto, Luisa Racca, Luca Spigarelli, Giancarlo Canavese, Valentina Cauda
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引用次数: 2

摘要

超声波已经广泛应用于临床诊断,现在正在成为抗肿瘤治疗中一种强大而无害的工具,因为由于惯性空化和温度升高,它们能够对癌细胞产生损害。将US单独或联合用于分子化合物、微泡或固态纳米颗粒是当前研究和临床试验的重点,如热消融、药物超声穿孔或声动力疗法。在目前的工作中,我们讨论了超声波的非热效应和使氧自由基产生的条件,以及它们在引发不同癌细胞系死亡方面的作用。从这个角度来看,我们建立了一个数学模型来预测特定水样体积内的压力空间分布,从而获得不同输入功率下应用超声的声压和声强图。然后,我们通过直接声学测量和通过声化学发光(SCL)和电子顺磁共振(EPR)光谱检测活性氧(ROS)的产生来验证和验证这些数值结果,应用于相同的水样体积,并使用模拟中采用的相同的美国输入参数。最后,各种美国条件应用于两组不同的癌细胞系,宫颈腺癌和血液学癌,伯基特淋巴瘤。我们假设ROS的产生如何影响记录的细胞死亡。在第二组实验中,还通过将半导体金属氧化物纳米晶体(即氧化锌)添加到水和生物系统中来评估它们的作用。特别是,ZnO在促进ROS生成中的作用得到了验证。此外,在特定条件下,评估了US和ZnO纳米晶体之间的相互作用在引发癌细胞死亡方面的作用。本研究表明,在简单水溶液的US辐照过程中,数值模拟和实验声学验证以及定性和定量水平的ROS测量之间存在有用的相关性。它进一步试图翻译所获得的结果,以证明负责癌细胞死亡的可能机制之一。因此,它旨在为在癌症治疗中使用US铺平道路,并更好地了解一组特定的US参数对体外培养的癌细胞的非热效应。图形抽象
本文章由计算机程序翻译,如有差异,请以英文原文为准。

A comparative analysis of low intensity ultrasound effects on living cells: from simulation to experiments

A comparative analysis of low intensity ultrasound effects on living cells: from simulation to experiments

Ultrasounds are already broadly exploited in clinical diagnostics and are now becoming a powerful and not harmful tool in antitumoral therapies, as they are able to produce damages towards cancer cells, thank to inertial cavitation and temperature increase. The use of US alone or combined to molecular compounds, microbubbles or solid-state nanoparticles is the focus of current research and clinical trials, like thermoablation, drug sonoporation or sonodynamic therapies. In the present work, we discuss on the non-thermal effects of ultrasound and the conditions which enable oxygen radical production and which role they can have in provoking the death of different cancer cell lines. In this perspective, we set a mathematical model to predict the pressure spatial distribution in a defined water sample volume and thus obtain a map of acoustic pressures and acoustic intensities of the applied ultrasound at different input powers. We then validate and verify these numerical results with direct acoustic measurements and by detecting the production of reactive oxygen species (ROS) by means of sonochemiluminescence (SCL) and electron paramagnetic resonance (EPR) spectroscopy, applied to the same water sample volume and using the same US input parameters adopted in the simulation. Finally, the various US conditions are applied to two different set of cancer cell lines, a cervical adenocarcinoma and a hematological cancer, Burkitt’s lymphoma. We hypothesize how the ROS generation can influence the recorded cell death. In a second set of experiments, the role of semiconductor metal oxide nanocrystals, i.e. zinc oxide, is also evaluated by adding them to the water and biological systems. In particular, the role of ZnO in enhancing the ROS production is verified. Furthermore, the interplay among US and ZnO nanocrystals is evaluated in provoking cancer cell death at specific conditions. This study demonstrates a useful correlation between numerical simulation and experimental acoustic validation as well as with ROS measurement at both qualitative and quantitative levels during US irradiation of simple water solution. It further tries to translate the obtained results to justify one of the possible mechanisms responsible of cancer cell death. It thus aims to pave the way for the use of US in cancer therapy and a better understanding on the non-thermal effect that a specific set of US parameters can have on cancer cells cultured in vitro.

Graphical abstract

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来源期刊
Biomedical Microdevices
Biomedical Microdevices 工程技术-工程:生物医学
CiteScore
6.90
自引率
3.60%
发文量
32
审稿时长
6 months
期刊介绍: Biomedical Microdevices: BioMEMS and Biomedical Nanotechnology is an interdisciplinary periodical devoted to all aspects of research in the medical diagnostic and therapeutic applications of Micro-Electro-Mechanical Systems (BioMEMS) and nanotechnology for medicine and biology. General subjects of interest include the design, characterization, testing, modeling and clinical validation of microfabricated systems, and their integration on-chip and in larger functional units. The specific interests of the Journal include systems for neural stimulation and recording, bioseparation technologies such as nanofilters and electrophoretic equipment, miniaturized analytic and DNA identification systems, biosensors, and micro/nanotechnologies for cell and tissue research, tissue engineering, cell transplantation, and the controlled release of drugs and biological molecules. Contributions reporting on fundamental and applied investigations of the material science, biochemistry, and physics of biomedical microdevices and nanotechnology are encouraged. A non-exhaustive list of fields of interest includes: nanoparticle synthesis, characterization, and validation of therapeutic or imaging efficacy in animal models; biocompatibility; biochemical modification of microfabricated devices, with reference to non-specific protein adsorption, and the active immobilization and patterning of proteins on micro/nanofabricated surfaces; the dynamics of fluids in micro-and-nano-fabricated channels; the electromechanical and structural response of micro/nanofabricated systems; the interactions of microdevices with cells and tissues, including biocompatibility and biodegradation studies; variations in the characteristics of the systems as a function of the micro/nanofabrication parameters.
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