A Mini Review: Zinc Oxide NPs as a Promising Cancer Treatment Strategy: Insights into Synthesis Methodology and Mechanisms

Current Materials Science Pub Date : 2023-09-18 DOI:10.2174/2666145417666230918115854

Jian Xin Lim, Muhammad Nazrul Hakim Abdullah, Vuanghao Lim, Han Kee Lee, Yoke Keong Yong

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Abstract

Abstract: Cancer has become a major global public health concern, with millions of new cases and deaths reported annually. Conventional cancer treatments, such as chemotherapy and surgery, continue to be the standard of care; however, they frequently bear significant risks and high costs, necessitating the development of more cost-effective and safe alternatives. These limitations can be overcome by nanoparticle (NPs), composed of organic or inorganic substances in the nanoscale range, which offer benefits including enhanced pharmacokinetics, selective targeting of cancer cells, reduced toxicity, and decreased drug resistance. Green nanotechnology, which integrates nanotechnology with natural compounds, has emerged as a strategy for reducing toxicity on human health and the environment by functioning as reducing, capping, and stabilising agents. Compared to other NPs, Zinc oxide NPs (ZnO NPs) possess a unique selectivity and a potent capacity to target cancer cells, in addition to being biocompatible and considered safer for both humans and the environment. Due to the physiological function of zinc, an essential micronutrient, ZnO NPs have demonstrated greater bioavailability than other metal or metal oxide NPs. NP plays a more significant role in bioavailability than particle size, making ZnO NPs an attractive option for various applications. This mini review aims to comprehensively explore the synthesis methodology of ZnO NPs and the potential mechanisms underlying their anticancer properties. `

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氧化锌NPs作为一种有前景的癌症治疗策略:合成方法和机制的见解

摘要:癌症已成为全球关注的主要公共卫生问题，每年有数百万新发病例和死亡病例报告。传统的癌症治疗，如化疗和手术，仍然是标准的治疗方法;然而，它们往往有很大的风险和高昂的费用，因此有必要开发更具成本效益和更安全的替代品。这些限制可以通过纳米颗粒(NPs)来克服，纳米颗粒由纳米级范围内的有机或无机物质组成，它提供的好处包括增强药代动力学，选择性靶向癌细胞，降低毒性和降低耐药性。绿色纳米技术将纳米技术与天然化合物结合在一起，已经成为一种战略，通过发挥减少、封顶和稳定剂的作用，减少对人类健康和环境的毒性。与其他NPs相比，氧化锌NPs (ZnO NPs)除了具有生物相容性和对人类和环境更安全外，还具有独特的选择性和靶向癌细胞的强大能力。锌是一种必需微量营养素，由于锌的生理功能，ZnO NPs比其他金属或金属氧化物NPs具有更高的生物利用度。NP在生物利用度中扮演着比粒径更重要的角色，这使得ZnO NPs成为各种应用的有吸引力的选择。本文旨在全面探讨氧化锌NPs的合成方法及其抗癌特性的潜在机制。｀

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Current Materials Science Materials Science-Materials Science (all)

CiteScore

0.80

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0.00%

发文量