Nanotherapy based on magneto-mechanochemical modulation of tumor redox state.

IF 6.9 2区 医学 Q1 MEDICINE, RESEARCH & EXPERIMENTAL
Valerii B Orel, Αndreas S Papazoglou, Christos Tsagkaris, Dimitrios V Moysidis, Stavros Papadakos, Olexander Yu Galkin, Valerii E Orel, Liubov A Syvak
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引用次数: 6

Abstract

Magnetic nanoparticles (MNs) are typically used as contrast agents for magnetic resonance imaging or as drug carriers with a remotely controlled delivery to the tumor. However, they can also potentiate the action of anticancer drugs under the influence of applied constant magnetic (CMFs) and electromagnetic fields (EMFs). This review demonstrates the role of magneto-mechanochemical effects produced by MNs alone and loaded with anticancer agents (MNCs) in response to CMFs and EMFs for modulation of tumor redox state. The combined treatment is suggested to act by two mechanisms: spin-dependent electron transport propagates free radical chain reactions, while magnetomechanical interactions cause conformational changes in drug molecules loaded onto MNs and generate reactive oxygen species (ROS). By adjusting the parameters of CMFs and EMFs during the magneto-mechanochemical synthesis and subsequent treatment, it is possible to modulate ROS production and switch redox signaling involved in ERK1/2 and NF-κB pathways from initiation of tumor growth to inhibition. Observations of tumor volume in different animal models and treatment combinations reported a 6%-70% reduction as compared with conventional drugs. Despite these results, there is a general lack of research in magnetic nanotheranostics that link redox changes across multiple levels of organization in the tumor-bearing host. Further multidisciplinary studies with more focus on the relationship between the electron transport processes in biomolecules and their effects on the tumor-host interaction should accelerate the clinical translation of magnetic nanotheranostics. This article is categorized under: Therapeutic Approaches and Drug Discovery > Nanomedicine for Oncologic Disease Therapeutic Approaches and Drug Discovery > Emerging Technologies Nanotechnology Approaches to Biology > Nanoscale Systems in Biology.

基于磁-机械化学调节肿瘤氧化还原状态的纳米疗法。
磁性纳米颗粒(MNs)通常用作磁共振成像的造影剂或作为远程控制递送到肿瘤的药物载体。然而,它们也可以在施加恒定磁场(CMFs)和电磁场(emf)的影响下增强抗癌药物的作用。本文综述了MNs外加抗癌剂(MNCs)在CMFs和EMFs作用下产生的磁-机械化学效应对肿瘤氧化还原状态的调节作用。联合处理被认为通过两种机制起作用:自旋依赖的电子传递传播自由基链反应,而磁力学相互作用引起装载在MNs上的药物分子的构象变化并产生活性氧(ROS)。通过在磁机械化学合成和后续处理过程中调节CMFs和EMFs的参数,有可能调节ROS的产生,并将ERK1/2和NF-κB通路中涉及的氧化还原信号从肿瘤生长的启动转变为抑制。与常规药物相比,不同动物模型和治疗组合的肿瘤体积减少了6%-70%。尽管有这些结果,但在磁性纳米治疗方面普遍缺乏将肿瘤宿主中多个组织水平的氧化还原变化联系起来的研究。进一步的多学科研究,更多地关注生物分子中的电子传递过程及其对肿瘤-宿主相互作用的影响之间的关系,将加速磁纳米治疗的临床转化。本文分类如下:治疗方法和药物发现>肿瘤疾病的纳米药物治疗方法和药物发现>新兴技术生物学的纳米技术方法>生物学中的纳米级系统。
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来源期刊
Wiley interdisciplinary reviews. Nanomedicine and nanobiotechnology
Wiley interdisciplinary reviews. Nanomedicine and nanobiotechnology NANOSCIENCE & NANOTECHNOLOGY-MEDICINE, RESEARCH & EXPERIMENTAL
CiteScore
16.60
自引率
2.30%
发文量
93
期刊介绍: Nanotechnology stands as one of the pivotal scientific domains of the twenty-first century, recognized universally for its transformative potential. Within the biomedical realm, nanotechnology finds crucial applications in nanobiotechnology and nanomedicine, highlighted as one of seven emerging research areas under the NIH Roadmap for Medical Research. The advancement of this field hinges upon collaborative efforts across diverse disciplines, including clinicians, biomedical engineers, materials scientists, applied physicists, and toxicologists. Recognizing the imperative for a high-caliber interdisciplinary review platform, WIREs Nanomedicine and Nanobiotechnology emerges to fulfill this critical need. Our topical coverage spans a wide spectrum, encompassing areas such as toxicology and regulatory issues, implantable materials and surgical technologies, diagnostic tools, nanotechnology approaches to biology, therapeutic approaches and drug discovery, and biology-inspired nanomaterials. Join us in exploring the frontiers of nanotechnology and its profound impact on biomedical research and healthcare.
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