{"title":"Emerging nitric oxide gas‐assisted cancer photothermal treatment","authors":"Shuang Liang, Yufei Liu, Hongquan Zhu, Guangfu Liao, Wenzhen Zhu, Li Zhang","doi":"10.1002/exp.20230163","DOIUrl":null,"url":null,"abstract":"Photothermal therapy (PTT) has garnered significant attention in recent years, but the standalone application of PTT still faces limitations that hinder its ability to achieve optimal therapeutic outcomes. Nitric oxide (NO), being one of the most extensively studied gaseous molecules, presents itself as a promising complementary candidate for PTT. In response, various nanosystems have been developed to enable the simultaneous utilization of PTT and NO‐mediated gas therapy (GT), with the integration of photothermal agents (PTAs) and thermally‐sensitive NO donors being the prevailing approach. This combination seeks to leverage the synergistic effects of PTT and GT while mitigating the potential risks associated with gas toxicity through the use of a single laser irradiation. Furthermore, additional internal or external stimuli have been employed to trigger NO release when combined with different types of PTAs, thereby further enhancing therapeutic efficacy. This comprehensive review aims to summarize recent advancements in NO gas‐assisted cancer photothermal treatment. It commences by providing an overview of various types of NO donors and precursors, including those sensitive to photothermal, light, ultrasound, reactive oxygen species, and glutathione. These NO donors and precursors are discussed in the context of dual‐modal PTT/GT. Subsequently, the incorporation of other treatment modalities such as chemotherapy (CHT), photodynamic therapy (PDT), alkyl radical therapy, radiation therapy, and immunotherapy (IT) in the creation of triple‐modal therapeutic nanoplatforms is presented. The review further explores tetra‐modal therapies, such as PTT/GT/CHT/PDT, PTT/GT/CHT/chemodynamic therapy (CDT), PTT/GT/PDT/IT, PTT/GT/starvation therapy (ST)/IT, PTT/GT/Ca2+ overload/IT, PTT/GT/ferroptosis (FT)/IT, and PTT/GT/CDT/IT. Finally, potential challenges and future perspectives concerning these novel paradigms are discussed. This comprehensive review is anticipated to serve as a valuable resource for future studies focused on the development of innovative photothermal/NO‐based cancer nanotheranostics.","PeriodicalId":503118,"journal":{"name":"Exploration","volume":" 7","pages":""},"PeriodicalIF":0.0000,"publicationDate":"2024-03-24","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Exploration","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.1002/exp.20230163","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}
引用次数: 0
Abstract
Photothermal therapy (PTT) has garnered significant attention in recent years, but the standalone application of PTT still faces limitations that hinder its ability to achieve optimal therapeutic outcomes. Nitric oxide (NO), being one of the most extensively studied gaseous molecules, presents itself as a promising complementary candidate for PTT. In response, various nanosystems have been developed to enable the simultaneous utilization of PTT and NO‐mediated gas therapy (GT), with the integration of photothermal agents (PTAs) and thermally‐sensitive NO donors being the prevailing approach. This combination seeks to leverage the synergistic effects of PTT and GT while mitigating the potential risks associated with gas toxicity through the use of a single laser irradiation. Furthermore, additional internal or external stimuli have been employed to trigger NO release when combined with different types of PTAs, thereby further enhancing therapeutic efficacy. This comprehensive review aims to summarize recent advancements in NO gas‐assisted cancer photothermal treatment. It commences by providing an overview of various types of NO donors and precursors, including those sensitive to photothermal, light, ultrasound, reactive oxygen species, and glutathione. These NO donors and precursors are discussed in the context of dual‐modal PTT/GT. Subsequently, the incorporation of other treatment modalities such as chemotherapy (CHT), photodynamic therapy (PDT), alkyl radical therapy, radiation therapy, and immunotherapy (IT) in the creation of triple‐modal therapeutic nanoplatforms is presented. The review further explores tetra‐modal therapies, such as PTT/GT/CHT/PDT, PTT/GT/CHT/chemodynamic therapy (CDT), PTT/GT/PDT/IT, PTT/GT/starvation therapy (ST)/IT, PTT/GT/Ca2+ overload/IT, PTT/GT/ferroptosis (FT)/IT, and PTT/GT/CDT/IT. Finally, potential challenges and future perspectives concerning these novel paradigms are discussed. This comprehensive review is anticipated to serve as a valuable resource for future studies focused on the development of innovative photothermal/NO‐based cancer nanotheranostics.
近年来,光热疗法(PTT)备受关注,但单独应用光热疗法仍面临诸多限制,阻碍了其实现最佳治疗效果的能力。一氧化氮(NO)是研究最为广泛的气态分子之一,它是 PTT 颇具前景的补充候选物质。为此,人们开发了各种纳米系统,以便同时利用 PTT 和一氧化氮介导的气体疗法 (GT),其中最普遍的方法是将光热剂 (PTA) 和热敏一氧化氮供体结合在一起。这种组合旨在利用 PTT 和 GT 的协同效应,同时通过使用单一激光照射减轻与气体毒性相关的潜在风险。此外,在与不同类型的 PTAs 结合使用时,还采用了额外的内部或外部刺激来触发 NO 释放,从而进一步提高疗效。本综述旨在总结氮氧化物气体辅助癌症光热治疗的最新进展。文章首先概述了各种类型的 NO 供体和前体,包括对光热、光、超声、活性氧和谷胱甘肽敏感的供体和前体。在双模式 PTT/GT 的背景下讨论了这些 NO 供体和前体。随后,介绍了将化疗(CHT)、光动力疗法(PDT)、烷基自由基疗法、放射疗法和免疫疗法(IT)等其他治疗模式纳入三重模式治疗纳米平台的情况。综述进一步探讨了四重模式疗法,如 PTT/GT/CHT/PDT、PTT/GT/CHT/化学动力疗法(CDT)、PTT/GT/PDT/IT、PTT/GT/饥饿疗法(ST)/IT、PTT/GT/Ca2+超载/IT、PTT/GT/铁变态反应(FT)/IT 和 PTT/GT/CDT/IT。最后,还讨论了有关这些新范例的潜在挑战和未来展望。这篇全面的综述预计将成为未来重点开发基于光热/氧化氮的创新癌症纳米疗法研究的宝贵资源。