Photoactivatable bioinspired nanomedicines

IF 40.4 1区化学 Q1 CHEMISTRY, MULTIDISCIPLINARY

Chemical Society Reviews Pub Date : 2025-07-08 DOI:10.1039/d5cs00257e

Khatia Merabishvili, Islam Zmerli, Jana Alhoussein, Christophe Regeard, Ali Makky

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Abstract

Photoactivatable nanomedicines are therapeutic agents that generate heat, produce reactive oxygen species, or initiate photochemical reactions through their interaction with light. These agents can be used for the diagnosis, monitoring and remote induction of therapeutic effects. However, such nanoconstructs may have limitations, primarily attributable to the light–matter interaction and/or to the physiological characteristics of the disease. Consequently, there is growing interest in photoactivatable bioinspired nanoconstructs, which have led to significant improvements in their functionalities. By employing rational design methodologies, biomimicry enables researchers to engineer light-responsive nanomaterials with enhanced functionalities. The bioinspiration from phototrophs, light-harvesting antennas, chlorophylls, and carotenoids has led to the development of unique spatial organizations with broad spectral cross-sections. This resulted in more effective light collection and conversion into chemical energy. For instance, mechanisms like photoprotection can prevent photodamage and ensure treatment safety. In addition, certain animals, particularly marine species, generate or utilize light from other non-photosynthetic species to enhance their function. Finally, photoactivatable nanomedicines bioinspired by the functionalities of DNA scaffolds or biohybridized with cell membranes, cyanobacteria or hemoglobin have been discussed. This review provides a comprehensive perspective on how bioinspiration has contributed to the development of photoactivatable nanomedicines by overcoming some of the conventional nanosystem limitations.

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光活化生物启发纳米药物

光活化纳米药物是一种能够产生热量、产生活性氧或通过与光的相互作用引发光化学反应的治疗剂。这些药物可用于诊断、监测和远程诱导治疗效果。然而，这种纳米结构可能有局限性，主要归因于光-物质相互作用和/或疾病的生理特征。因此，人们对光激活的生物启发纳米结构越来越感兴趣，这导致了它们功能的显着改进。通过采用合理的设计方法，仿生学使研究人员能够设计出具有增强功能的光响应纳米材料。来自光养生物、光收集天线、叶绿素和类胡萝卜素的生物灵感导致了具有广谱截面的独特空间组织的发展。这导致了更有效的光收集和转化为化学能。例如，光保护等机制可以防止光损伤，确保治疗安全。此外，某些动物，特别是海洋物种，产生或利用其他非光合作用物种的光来增强其功能。最后，讨论了受DNA支架功能启发或与细胞膜、蓝藻或血红蛋白生物杂交的光活化纳米药物。这篇综述提供了一个全面的视角，关于生物灵感如何通过克服一些传统纳米系统的局限性来促进光活化纳米药物的发展。

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来源期刊

Chemical Society Reviews 化学-化学综合

CiteScore

80.80

自引率

1.10%

发文量

345

审稿时长

6.0 months

期刊介绍： Chemical Society Reviews is published by: Royal Society of Chemistry. Focus: Review articles on topics of current interest in chemistry; Predecessors: Quarterly Reviews, Chemical Society (1947–1971); Current title: Since 1971; Impact factor: 60.615 (2021); Themed issues: Occasional themed issues on new and emerging areas of research in the chemical sciences