Engineered nanoflowers, nanotrees, nanostars, nanodendrites, and nanoleaves for biomedical applications

IF 6.1 3区材料科学 Q1 CHEMISTRY, MULTIDISCIPLINARY

Nanotechnology Reviews Pub Date : 2023-01-01 DOI:10.1515/ntrev-2022-0523

M. Khakbiz, Sara Shakibania, L. Ghazanfari, Shan Zhao, M. Tavakoli, Zi Chen

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引用次数: 1

Abstract

Abstract The development of architectured nanomaterials has been booming in recent years in part due to their expanded applications in the biomedical field, such as biosensing, bioimaging, drug delivery, and cancer therapeutics. Nanomaterials exhibit a wide variety of shapes depending on both the intrinsic properties of the materials and the synthesis procedures. Typically, the large surface areas of nanomaterials improve the rate of mass transfer in biological reactions. They also have high self-ordering and assembly behaviors, which make them great candidates for various biomedical applications. Some nanomaterials have a high conversion rate in transforming the energy of photons into heat or fluorescence, thus showing promise in cancer treatment (such as hyperthermia) and bioimaging. The nanometric dimension makes them suitable for passing through the biological barriers or interacting with the natural molecules (such as DNA, protein). Nanoflowers, nanotrees, nanostars, and nanodendrites are examples of nano-sized structures, which exhibit unique geometry-dependent properties. Here we reviewed the fabrication methods, features, properties, and biomedical applications of four nano-structured materials including nanoflowers, nanotrees, nanostars, nanodendrites, and nanoleaves. We further provided our perspectives on employing these novel nanostructures as advanced functional materials for a broad spectrum of applications. Graphical abstract

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用于生物医学应用的工程纳米花、纳米树、纳米星、纳米枝晶和纳米叶

近年来，纳米结构材料的发展迅速，部分原因是其在生物医学领域的应用越来越广泛，如生物传感、生物成像、药物传递和癌症治疗。纳米材料表现出各种各样的形状，这取决于材料的内在性质和合成过程。通常，纳米材料的大表面积提高了生物反应中的传质速率。它们还具有高度的自排序和组装行为，这使它们成为各种生物医学应用的伟大候选人。一些纳米材料在将光子能量转化为热量或荧光方面具有很高的转化率，因此在癌症治疗(如热疗)和生物成像方面显示出前景。纳米尺度使它们适合于通过生物屏障或与自然分子(如DNA，蛋白质)相互作用。纳米花、纳米树、纳米星和纳米树突是纳米级结构的例子，它们具有独特的几何依赖性质。本文综述了纳米花、纳米树、纳米星、纳米树突和纳米叶等四种纳米结构材料的制备方法、特点、性能及其在生物医学上的应用。我们进一步提出了将这些新型纳米结构应用于广泛应用的先进功能材料的观点。图形抽象

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来源期刊

Nanotechnology Reviews CHEMISTRY, MULTIDISCIPLINARY-NANOSCIENCE & NANOTECHNOLOGY

CiteScore

11.40

自引率

13.50%

发文量

137

审稿时长

7 weeks

期刊介绍： The bimonthly journal Nanotechnology Reviews provides a platform for scientists and engineers of all involved disciplines to exchange important recent research on fundamental as well as applied aspects. While expert reviews provide a state of the art assessment on a specific topic, research highlight contributions present most recent and novel findings. In addition to technical contributions, Nanotechnology Reviews publishes articles on implications of nanotechnology for society, environment, education, intellectual property, industry, and politics.