透视无机纳米/微粒在超声波触发下产生的活性氧物种

IF 4 Q2 ENGINEERING, BIOMEDICAL

Advanced Nanobiomed Research Pub Date : 2024-06-20 DOI:10.1002/anbr.202400060

Yijun Han, Xinyue Yu, Zeinab Marfavi, Yumo Chen, Linxuan Zhang, Jing Chu, Kang Sun, Mingda Li, Ke Tao

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引用次数: 0

摘要

超声波可以激活纳米/微粒子，诱导活性氧（ROS）。深层渗透和精确时空控制的优势在声动力治疗、化学工业和环境治理等多种应用中得到了证明。同时，还开发了一个无机颗粒工具箱，通过空化增强、声发光和压催化效应来提高 ROS 的产生。然而，超声参数的复杂影响阻碍了对新型声敏化材料的进一步探索。本研究综述了不同机制中的影响参数，强调了超声频率与催化活性之间的关系，并对无机声敏化剂的研究进行了展望。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

A Perspective on Ultrasound-Triggered Production of Reactive Oxygen Species by Inorganic Nano/Microparticles

查看原文本刊更多论文

A Perspective on Ultrasound-Triggered Production of Reactive Oxygen Species by Inorganic Nano/Microparticles

Ultrasound can activate nano/microparticles to induce reactive oxygen species (ROS). The advantages of deep penetration and precise spatiotemporal control are demonstrated for multiple applications, such as sonodynamic therapy, chemical industry, and environmental treatment. Meanwhile, a toolbox of inorganic particles is developed to enhance ROS production via cavitation enhancement, sonoluminescence, and piezocatalytic effect. Nonetheless, sophisticated influences of ultrasonic parameters hamper further exploration of novel sonosensitized materials. In this perspective, the influential parameters in different mechanisms are reviewed, emphasizing the relationship between ultrasound frequency and catalytic activity, and outlooks are provided on the study of inorganic sonosensitizers.

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来源期刊

Advanced Nanobiomed Research nanomedicine, bioengineering and biomaterials-

CiteScore

5.00

自引率

5.90%

发文量

审稿时长

21 weeks

期刊介绍： Advanced NanoBiomed Research will provide an Open Access home for cutting-edge nanomedicine, bioengineering and biomaterials research aimed at improving human health. The journal will capture a broad spectrum of research from increasingly multi- and interdisciplinary fields of the traditional areas of biomedicine, bioengineering and health-related materials science as well as precision and personalized medicine, drug delivery, and artificial intelligence-driven health science. The scope of Advanced NanoBiomed Research will cover the following key subject areas: ▪ Nanomedicine and nanotechnology, with applications in drug and gene delivery, diagnostics, theranostics, photothermal and photodynamic therapy and multimodal imaging. ▪ Biomaterials, including hydrogels, 2D materials, biopolymers, composites, biodegradable materials, biohybrids and biomimetics (such as artificial cells, exosomes and extracellular vesicles), as well as all organic and inorganic materials for biomedical applications. ▪ Biointerfaces, such as anti-microbial surfaces and coatings, as well as interfaces for cellular engineering, immunoengineering and 3D cell culture. ▪ Biofabrication including (bio)inks and technologies, towards generation of functional tissues and organs. ▪ Tissue engineering and regenerative medicine, including scaffolds and scaffold-free approaches, for bone, ligament, muscle, skin, neural, cardiac tissue engineering and tissue vascularization. ▪ Devices for healthcare applications, disease modelling and treatment, such as diagnostics, lab-on-a-chip, organs-on-a-chip, bioMEMS, bioelectronics, wearables, actuators, soft robotics, and intelligent drug delivery systems. with a strong focus on applications of these fields, from bench-to-bedside, for treatment of all diseases and disorders, such as infectious, autoimmune, cardiovascular and metabolic diseases, neurological disorders and cancer; including pharmacology and toxicology studies.