| 336 | 0 | 105 |
| 下载次数 | 被引频次 | 阅读次数 |
活性氧(reactive oxygen species,ROS)是细胞代谢过程中普遍存在的关键分子,广泛参与多种生理功能的调控过程。作为重要的信号分子,ROS不仅介导生物体的生长发育调控,还与机体健康状态及衰老进程密切相关,是维持生命活动正常运转不可或缺的生化基础要素,同时,这也是ROS调节应用在临床医学上的重要基础。纳米技术领域的突破性进展催生了一系列具备精准ROS调控功能的纳米材料的开发。这些材料能够定向调控生物微环境中的ROS动态平衡,为基于ROS浓度调控的新型治疗范式奠定了物质基础。这种治疗策略的核心在于:通过纳米材料介导的ROS水平时空控制,实现了“纳米调节—ROS响应—治疗输出”的三元级联协同。ROS调控被认为是一种具有化学机制、生物效应和纳米治疗应用相互交叉的新兴学科。本综述详细总结了基于ROS调控的纳米疗法的最新研究进展,重点介绍了纳米材料的潜在化学成分,这些化学成分通过产生或清除作用,提升或降低ROS水平以改善治疗效果,旨在帮助广大研究者解锁更多基于ROS的纳米材料应用手段和治疗方法。
Abstract:Reactive oxygen species(ROS) are key molecules ubiquitous in cellular metabolic processes, extensively participating in the regulation of various physiological functions. As important signaling molecules, ROS not only mediate the regulation of biological growth and development but are also closely related to the health status and aging process of organisms, serving as indispensable biochemical fundamental elements for maintaining normal life activities.This is also the important basis for ROS regulation applications in clinical medicine. Breakthrough advances in nanotechnology have catalyzed the development of a series of nanomaterials with precise ROS regulation functions. These materials can directionally regulate the ROS dynamic balance in biological microenvironments, laying the material foundation for novel therapeutic paradigms based on ROS concentration regulation. The core of this therapeutic strategy lies in: achieving the ternary cascade synergy of ″nano-regulation-ROS response-therapeutic output″ through nanomaterial-mediated spatiotemporal control of ROS levels. ROS regulation is considered an emerging discipline with the intersection of chemical mechanisms, biological effects, and nano-therapy applications. This review provides a detailed summary of recent research progress in ROS regulation-based nano-therapies, focusing on the potential chemical components of nanomaterials that elevate or decrease ROS levels through generation or scavenging effects to improve therapeutic outcomes, aiming to help researchers unlock more ROS-based nanomaterial application approaches and therapeutic methods.
[1]D′AUTRÉAUX B , TOLEDANO M B. ROS as signalling molecules:mechanisms that generate specificity in ROS homeostasis[J]. Nature Reviews Molecular Cell Biology ,2007, 8(10):813-824.
[2]NATHAN C, CUNNINGHAM-BUSSEL A. Beyond oxidative stress:an immunologist′s guide to reactive oxygen species[J]. Nature Reviews Immunology , 2013, 13(5):349-361.
[3]TRACHOOTHAM D , ALEXANDRE J , HUANG P. Targeting cancer cells by ROS-mediated mechanisms:a radical therapeutic approach?[J]. Nature Reviews Drug Discovery, 2009, 8(7):579-591.
[4]LIOU G Y, STORZ P. Reactive oxygen species in cancer[J]. Free Radical Research, 2010, 44(5):479-496.
[5]GORRINI C, HARRIS I S, MAK T W. Modulation of oxidative stress as an anticancer strategy[J]. Nature Reviews Drug Discovery, 2013, 12(12):931-947.
[6]SIES H, BELOUSOV V V, CHANDEL N S, et al. Defining roles of specific reactive oxygen species(ROS)in cell biology and physiology[J]. Nature Reviews Molecular Cell Biology, 2022, 23(7):499-515.
[7]STORZ P. Reactive oxygen species in tumor progression[J].Frontiers in Bioscience, 2005, 10(1/2/3):1881.
[8]AGGARWAL V, TULI H, VAROL A, et al. Role of reactive oxygen species in cancer progression:molecular mechanisms and recent advancements[J]. Biomolecules , 2019,9(11):735.
[9]YANG B W, CHEN Y, SHI J L. Reactive oxygen species(ROS)-based nanomedicine[J]. Chemical Reviews, 2019,119(8):4881-4985.
[10]DICKINSON B C, CHANG C J. Chemistry and biology of reactive oxygen species in signaling or stress responses[J].Nature Chemical Biology, 2011, 7(8):504-511.
[11]AI Y J, HE M Q, WAN C X, et al. Nanoplatform-based reactive oxygen species scavengers for therapy of ischemia-reperfusion injury[J]. Advanced Therapeutics, 2022,5(11):2200066.
[12]SARNIAK A, LIPINSKA J, TYTMAN K, et al. Endogenous mechanisms of reactive oxygen species(ROS)generation[J]. Post e py Higieny I Medycyny Do s wiadczalnej ,2016, 70:1150-1165.
[13]ROTTENBERG H, HOEK J B. The path from mitochondrial ROS to aging runs through the mitochondrial permeability transition pore[J]. Aging Cell , 2017, 16(5):943-955.
[14]DEMIRCIÇEKIÇS,ÇETINKAYA A, AVAN A N, et al.Correlation of total antioxidant capacity with reactive oxygen species(ROS)consumption measured by oxidative conversion[J]. Journal of Agricultural and Food Chemistry ,2013, 61(22):5260-5270.
[15]BRENNEISEN P, REICHERT A S. Nanotherapy and reactive oxygen species(ROS)in cancer:a novel perspective[J]. Antioxidants, 2018, 7(2):31.
[16]PERILLO B, di DONATO M, PEZONE A, et al. ROS in cancer therapy:the bright side of the moon[J]. Experimental&Molecular Medicine, 2020, 52(2):192-203.
[17]YAN L, GU Z J, ZHAO Y L. Chemical mechanisms of the toxicological properties of nanoma terials:generation of intracellular reactive oxygen species[J]. Chemistry-An Asian Journal, 2013, 8(10):2342-2353.
[18]ALEXANDROVA A Y, KOPNIN P B, VASILIEV J M, et al. ROS up-regulation mediates Ras-induced changes of cell morphology and motility[J]. Experimental Cell Research, 2006, 312(11):2066-2073.
[19]SELEZNEVA M, ROY S, LESSARD L, et al. Analytical model for prediction of strength and fracture paths characteristic to randomly oriented strand(ROS)composites[J].Composites Part B:Engineering, 2016, 96:103-111.
[20]AGOSTINIS P, BERG K, CENGEL K A, et al. Photodynamic therapy of cancer:an update[J]. CA:A Cancer Journal for Clinicians, 2011, 61(4):250-281.
[21]MITRAGOTRI S. Healing sound:the use of ultrasound in drug delivery and other therapeutic applications[J]. Nature Reviews Drug Discovery, 2005, 4(3):255-260.
[22]SONG G S, CHENG L, CHAO Y, et al. Emerging nanotechnology and advanced materials for cancer radiation therapy[J]. Advanced Materials, 2017, 29(32):1700996.
[23]WANG L Y, HUO M F, CHEN Y, et al. Tumor microenvironment-enabled nanotherapy[J]. Advanced Healthcare Materials, 2018, 7(8):1701156.
[24]HUO M F, WANG L Y, CHEN Y, et al. Tumor-selective catalytic nanomedicine by nanocatalyst delivery[J]. Nature Communications, 2017, 8:357.
[25]MAZUMDER A, SHIVASHANKAR G V. Gold-nanoparticle-assisted laser perturbation of chro matin assembly reveals unusual aspects of nuclear architecture within living cells[J]. Biophysical Journal, 2007, 93(6):2209-2216.
[26]RUBIO C P, CERÓN J J. Spectrophotometric assays for evaluation of reactive oxygen species(ROS)in serum:general concepts and applications in dogs and humans[J].BMC Veterinary Research, 2021, 17(1):226.
[27]CHECA J, ARAN J M. Reactive oxygen species:drivers of physiological and pathological processes[J]. Journal of Inflammation Research, 2020, 13:1057-1073.
[28]MAUNG K K O, YANG Y M, HU Y, et al. Gold nanoparticle-enhanced and size-dependent generation of reactive oxygen species from protoporphyrin IX[J]. ACS Nano, 2012,6(3):1939-1947.
[29]ONG W K, YAO X M, JANA D, et al. Efficient production of reactive oxygen species from Fe3O4/ZnPC coloaded nanoreactor for cancer therapeutics in vivo[J]. Small Structures, 2020, 1(3):2000065.
[30]WANG J, GUO Y W, LIU B, et al. Detection and analysis of reactive oxygen species(ROS)generated by nanosized TiO2powder under ultrasonic irradiation and application in sonocatalytic degradation of organic dyes[J]. Ultrasonics Sonochemistry, 2011, 18(1):177-183.
[31]SARKAR A R, JANA N R. Molecular sonosensitizerloaded polymer nanomicelle for ultrasound-based cell therapy via singlet oxygen generation[J]. ACS Applied Nano Materials, 2023, 6(22):21282-21292.
[32]YANG C C, WANG C X, KUAN C Y, et al. Using C-doped TiO2nanoparticles as a novel sonosensitizer for cancer treatment[J]. Antioxidants, 2020, 9(9):880.
[33]GUAN H N, WANG D D, SUN B Y. Dual-mode colorimetric/fluorometric sensor for the detection of glutathione based on the peroxidase-like activity of carbon quantum dots[J]. Inorganic Chemistry Communications, 2022, 136:109147.
[34]DUTTA A K, MAJI S K, SRIVASTAVA D N, et al. Synthesis of FeS and FeSe nanoparticles from a single source precursor:a study of their photocatalytic activity, peroxidase-like behavior, and electrochemical sensing of H2O2[J].ACS Applied Materials&Interfaces, 2012, 4(4):1919-1927.
[35]LI Z, XIE C J, REN X W, et al. CuS nanoenzyme against bacterial infection by in situ hydroxyl radical generation on bacteria surface[J]. Rare Metals , 2023 , 42(6):1899-1911.
[36]ANDR魪R, NATÁLIO F, HUMANES M, et al. V2O5nanowires with an intrinsic peroxidase-like activity[J]. Advanced Functional Materials, 2011, 21(3):501-509.
[37]FAN W P, HUANG P, CHEN X Y. Overcoming the Achilles′heel of photodynamic therapy[J]. Chemical Society Reviews, 2016, 45(23):6488-6519.
[38]ROZHKOVA E A, ULASOV I, LAI B, et al. A high-performance nanobio photocatalyst for targeted brain cancer therapy[J]. Nano Letters, 2009, 9(9):3337-3342.
[39]GE J C, LAN M H, ZHOU B J, et al. A graphene quantum dot photodynamic therapy agent with high singlet oxygen generation[J]. Nature Communications, 2014, 5:4596.
[40]WANG H, YANG X Z, SHAO W, et al. Ultrathin black phosphorus nanosheets for efficient singlet oxygen generation[J]. Journal of the American Chemical Society, 2015,137(35):11376-11382.
[41]YU Y W, ZHANG L, JIA H Y, et al. Dual-mode reactive oxygen species-stimulated carbon monoxide release for synergistic photodynamic and gas tumor therapy[J]. ACS Nano, 2024, 18(45):31286-31299.
[42]DUCO W, GROSSO V, ZACCARI D, et al. Generation of ROS mediated by mechanical waves(ultrasound)and its possible applications[J]. Methods, 2016, 109:141-148.
[43]DENG L M, LIU M Z, SHENG D L, et al. Low-intensity focused ultrasound-augmented Cascade chemodynamic therapy via boosting ROS generation[J]. Biomaterials, 2021,271:120710.
[44]WU S L, ZHANG H, WANG S C, et al. Ultrasound-triggered in situ gelation with ROS-controlled drug release for cartilage repair[J]. Materials Horizons, 2023, 10(9):3507-3522.
[45]HARADA A, ONO M, YUBA E, et al. Titanium dioxide nanoparticle-entrapped polyion complex micelles generate singlet oxygen in the cells by ultrasound irradiation for sonodynamic therapy[J]. Biomaterials Science, 2013, 1(1):65-73.
[46]YOU D G, DEEPAGAN V G, UM W, et al. ROS-generating TiO2nanoparticles for non-invasive sonodynamic therapy of cancer[J]. Scientific Reports, 2016, 6:23200.
[47]DEEPAGAN V G, YOU D G, UM W, et al. Long-circulating Au-TiO2nanocomposite as a sonosensitizer for ROSmediated eradication of cancer[J]. Nano Letters, 2016, 16(10):6257-6264.
[48]FANG Y J, YANG J J, LIANG X Y, et al. Endogenous and exogeneous stimuli-triggered reactive oxygen species evoke long-lived carbon monoxide to fight against lung cancer[J]. Journal of Nanobiotechnology , 2024 , 22(1):416.
[49]GUO Z, ZHU S, YONG Y, et al. Synthesis of BSA-coated BiOI@Bi2S3semiconductor heterojunction nanoparticles and their applications for radio/photodynamic/photothermal synergistic therapy of tumor[J]. Advanced Materials, 2017,29(44):1704136.
[50]YONG Y, ZHANG C F, GU Z J, et al. Polyoxometalatebased radiosensitization platform for treating hypoxic tumors by attenuating radioresistance and enhancing radiation response[J]. ACS Nano, 2017, 11(7):7164-7176.
[51]FAN W P, BU W B, ZHANG Z, et al. X-ray radiationcontrolled NO-release for on-demand depth-independent hypoxic radiosensitization[J]. Angewandte Chemie International Edition, 2015, 54(47):14026-14030.
[52]HUO M F, WANG L Y, CHEN Y, et al. Tumor-selective catalytic nanomedicine by nanocatalyst delivery[J]. Nature Communications, 2017, 8:357.
[53]ALI S S, HARDT J I, QUICK K L, et al. A biologically effective fullerene(C60)derivative with superoxide dismutase mimetic properties[J]. Free Radical Biology and Medicine, 2004, 37(8):1191-1202.
[54]LI Y Y, HE X, YIN J J, et al. Acquired superoxidescavenging ability of ceria nanoparticles[J]. Angewandte Chemie International Edition, 2015, 54(6):1832-1835.
[55]BENJAMIN E J, BLAHA M J, CHIUVE S, et al. Heart disease and stroke statistics-2017 update:a report from the American heart association[J]. Circulation , 2017 , 135:e146-e603.
[56]YOSHITOMI T, NAGASAKI Y. Reactive oxygen speciesscavenging nanomedicines for the treatment of oxidative stress injuries[J]. Advanced Healthcare Materials, 2014, 3(8):1149-1161.
[57]SCHUBERT D, DARGUSCH R, RAITANO J, et al. Cerium and yttrium oxide nanoparticles are neuroprotective[J].Biochemical and Biophysical Research Communications,2006, 342(1):86-91.
[58]KIM C K, KIM T, CHOI I Y, et al. Ceria nanoparticles that can protect against ischemic stroke[J]. Angewandte Chemie International Edition, 2012, 51(44):11039-11043.
[59]BAO Q Q, HU P, XU Y Y, et al. Simultaneous bloodbrain barrier crossing and protection for stroke treatment based on edaravone-loaded ceria nanoparticles[J]. ACS Nano, 2018, 12(7):6794-6805.
[60]GAO N, DONG K, ZHAO A D, et al. Polyoxometalatebased nanozyme:design of a multifunctional enzyme for multi-faceted treatment of Alzheimer′s disease[J]. Nano Research, 2016, 9(4):1079-1090.
基本信息:
DOI:10.12194/j.ntu.20241207001
中图分类号:R318.08;TB383.1
引用信息:
[1]李妍琪,周逢春,沈唯一,等.基于活性氧生成/消除机制的纳米平台的临床应用及研究进展[J].南通大学学报(自然科学版),2025,24(04):85-94.DOI:10.12194/j.ntu.20241207001.
2024-12-07
2024
2025-04-29
2025
2
2025-05-09
2025-05-09
2025-05-09