[1] CHEUNG EC,VOUSDEN KH.The role of ROS in tumour development and progression[J].Nat Rev Cancer,2022,22(5):280-297.
[2] HORNING KJ,CAITO SW,TIPPS KG,et al.Manganese is essential for neuronal health[J].Annu Rev Nutr,2015,35:71-108.
[3] MENGFAN L,XUEYANG S,BOYA C,et al.Insights into manganese superoxide dismutase and human diseases[J].International Journal of Molecular Sciences,2022,23(24):15893.
[4] SONG M,LIU T,SHI C,et al.Bioconjugated manganese dioxide nanoparticles enhance chemotherapy response by priming tumor-associated macrophages toward M1-like phenotype and attenuating tumor hypoxia[J].ACS Nano,2016,10(1):633-647.
[5] ZHOU L,YANG Z,GUO L,et al.Noninvasive assessment of kidney injury by combining structure and function using artificial intelligence-based manganese-enhanced magnetic resonance imaging[J].ACS Applied Materials & Interfaces,2024,16(5):5474-5485.
[6] QINGBIN H,RUNXIAO Z,JUNCHI M,et al.Responsive manganese-based nanoplatform amplifying cGAS-STING activation for immunotherapy[J].Biomaterials Research,2023,27(1):29.
[7] SUN X,ZHANG Y,LI J,et al.Amplifying STING activation by cyclic dinucleotide-manganese particles for local and systemic cancer metalloimmunotherapy[J].Nature Nanotechnology,2021,16(11):1260-1270.
[8] HUANG S,GAO Y,LI H,et al.Manganese@albumin nanocomplex and its assembled nanowire activate TLR4-dependent signaling cascades of macrophages[J].Advanced Materials (Deerfield Beach,Fla),2024,36(5):e2310979.
[9] ZHANG S,KANG L,DAI X,et al.Manganese induces tumor cell ferroptosis through type-Ⅰ IFN dependent inhibition of mitochondrial dihydroorotate dehydrogenase[J].Free Radic Biol Med,2022,193(Pt 1):202-212.
[10] RAO L,ZHAO SK,WEN C,et al.Activating macrophage-mediated cancer immunotherapy by genetically edited nanoparticles[J].Adv Mater,2020,32(47):e2004853.
[11] GUNASSEKARAN GR,POONGKAVITHAI VADEVOO SM,BAEK MC,et al.M1 macrophage exosomes engineered to foster M1 polarization and target the IL-4 receptor inhibit tumor growth by reprogramming tumor-associated macrophages into M1-like macrophages[J].Biomaterials,2021,278:121137.
[12] HOU L,TIAN C,YAN Y,et al.Manganese-based nanoactivator optimizes cancer immunotherapy via enhancing innate immunity[J].ACS Nano,2020,14(4):3927-3940.
[13] ZHAO Y,PAN Y,ZOU K,et al.Biomimetic manganese-based theranostic nanoplatform for cancer multimodal imaging and twofold immunotherapy[J].Bioact Mater,2023,19:237-250.
[14] LIU XZ,WEN ZJ,LI YM,et al.Bioengineered bacterial membrane vesicles with multifunctional nanoparticles as a versatile platform for cancer immunotherapy[J].ACS Appl Mater Interfaces,2023,15(3):3744-3759.
[15] BHANDARI V,HOEY C,LIU LY,et al.Molecular landmarks of tumor hypoxia across cancer types[J].Nat Genet,2019,51(2):308-318.
[16] CHEN Q,CHEN J,YANG Z,et al.Nanoparticle-enhanced radiotherapy to trigger robust cancer immunotherapy[J].Adv Mater,2019,31(10):e1802228.
[17] LU WL,LAN YQ,XIAO KJ,et al.BODIPY-Mn nanoassemblies for accurate MRI and phototherapy of hypoxic cancer[J].J Mater Chem B,2017,5(6):1275-1283.
[18] LI W,LI R,YE Q,et al.Mn(3) O(4) nanoshell coated metal-organic frameworks with microenvironment-driven O(2) production and GSH exhaustion ability for enhanced chemodynamic and photodynamic cancer therapies[J].Adv Healthc Mater,2023,12(15):e2202280.
[19] ZHU DM,WU L,SUO M,et al.Engineered red blood cells for capturing circulating tumor cells with high performance[J].Nanoscale,2018,10(13):6014-6023.
[20] LI N,YU L,WANG J,et al.A mitochondria-targeted nanoradiosensitizer activating reactive oxygen species burst for enhanced radiation therapy[J].Chem Sci,2018,9(12):3159-3164.
[21] WANG Y,LIU Z,WANG H,et al.Starvation-amplified CO generation for enhanced cancer therapy via an erythrocyte membrane-biomimetic gas nanofactory[J].Acta Biomater,2019,92:241-253.
[22] CIOCCI M,IORIO E,CAROTENUTO F,et al.H2S-releasing nanoemulsions:a new formulation to inhibit tumor cells proliferation and improve tissue repair[J].Oncotarget,2016,7(51):84338-84358.
[23] LI L,WHITEMAN M,GUAN YY,et al.Characterization of a novel,water-soluble hydrogen sulfide-releasing molecule (GYY4137):new insights into the biology of hydrogen sulfide[J].Circulation,2008,117(18):2351-2360.
[24] HE T,QIN X,JIANG C,et al.Tumor pH-responsive metastable-phase manganese sulfide nanotheranostics for traceable hydrogen sulfide gas therapy primed chemodynamic therapy[J].Theranostics,2020,10(6):2453-2462.
[25] CAI X,ZHU Q,ZENG Y,et al.Manganese oxide nanoparticles as MRI contrast agents in tumor multimodal imaging and therapy[J].Int J Nanomedicine,2019,14:8321-8344.
[26] YANG G,XIA J,DAI X,et al.A targeted multi-crystalline manganese oxide as a tumor-selective nano-sized MRI contrast agent for early and accurate diagnosis of tumors[J].International Journal of Nanomedicine,2024,19:527-540.
[27] LI X,ZHAO W,LIU X,et al.Mesoporous manganese silicate coated silica nanoparticles as multi-stimuli-responsive T1-MRI contrast agents and drug delivery carriers[J].Acta Biomater,2016,30:378-387.
[28] ZHU H,ZHANG L,LIU Y,et al.Aptamer-PEG-modified Fe(3)O(4)@Mn as a novel T1- and T2- dual-model MRI contrast agent targeting hypoxia-induced cancer stem cells[J].Sci Rep,2016,6:39245.
[29] FU L,ZHANG W,ZHOU X,et al.Tumor cell membrane-camouflaged responsive nanoparticles enable MRI-guided immuno-chemodynamic therapy of orthotopic osteosarcoma[J].Bioact Mater,2022,17:221-233.
[30] CHUNXING L,YUN W,HUAYAN N,et al.Manganese and dysprosium codoped carbon quantum dots as a potential fluorescent/T1/T2/CT quadri-modal imaging nanoprobe[J].Nanotechnology,2021,33(2):5101.
[31] BRANDT M,CARDINALE J,RAUSCH I,et al.Manganese in PET imaging:Opportunities and challenges[J].J Labelled Comp Radiopharm,2019,62(8):541-551.
[32] BANERJEE A,BERTOLESI GE,LING CC,et al.Bifunctional pyrrolidin-2-one terminated manganese oxide nanoparticles for combined magnetic resonance and fluorescence imaging[J].ACS Appl Mater Interfaces,2019,11(14):13069-13078.
[33] LI H,KIM Y,JUNG H,et al.Near-infrared (NIR) fluorescence-emitting small organic molecules for cancer imaging and therapy[J].Chem Soc Rev,2022,51(21):8957-9008.
[34] FAROKHI M,MOTTAGHITALAB F,SAEB MR,et al.Functionalized theranostic nanocarriers with bio-inspired polydopamine for tumor imaging and chemo-photothermal therapy[J].J Control Release,2019,309:203-219.
[35] SONG ZL,DAI X,LI M,et al.Biodegradable nanoprobe based on MnO(2) nanoflowers and graphene quantum dots for near infrared fluorescence imaging of glutathione in living cells[J].Mikrochim Acta,2018,185(10):485.
[36] WANG Y,ZOU L,QIANG Z,et al.Enhancing targeted cancer treatment by combining hyperthermia and radiotherapy using Mn-Zn ferrite magnetic nanoparticles[J].ACS Biomater Sci Eng,2020,6(6):3550-3562.
[37]宋帅,赫丽杰,韩彧佳,等.非小细胞肺癌放疗抵抗研究进展[J].现代肿瘤医学,2019,27(19):3520-3523.
SONG Shuai,HE Lijie,HAN Yujia,et al.Advances in radiotherapy resistance of non-small cell lung cancer[J].Modern Oncology,2019,27(19):3520-3523.
[38] GIACOMO D,ANGELO T,PIERSANDRO P.Prussian blue nanoparticles as a versatile photothermal tool[J].Molecules (Basel,Switzerland),2018,23(6):1414.
[39] FANG D,LIU Z,JIN H,et al.Manganese-based prussian blue nanocatalysts suppress non-small cell lung cancer growth and metastasis via photothermal and chemodynamic therapy[J].Front Bioeng Biotechnol,2022,10:939158.
[40] CHEN Z,LI Z,LI C,et al.Manganese-containing polydopamine nanoparticles as theranostic agents for magnetic resonance imaging and photothermal/chemodynamic combined ferroptosis therapy treating gastric cancer[J].Drug Deliv,2022,29(1):1201-1211.
[41] ZHAN W,CAI X,LI H,et al.GMBP1-conjugated manganese oxide nanoplates for in vivo monitoring of gastric cancer MDR using magnetic resonance imaging[J].RSC Adv,2020,10(23):13687-13695.
[42] LI K,LI P,WANG Y,et al.Manganese-based targeted nanoparticles for postoperative gastric cancer monitoring via magnetic resonance imaging[J].Front Oncol,2020,10:601538.
[43] SONG Y,LIU Y,TEO HY,et al.Manganese enhances the antitumor function of CD8(+) T cells by inducing type I interferon production[J].Cell Mol Immunol,2021,18(6):1571-1574.
[44] LV M,CHEN M,ZHANG R,et al.Manganese is critical for antitumor immune responses via cGAS-STING and improves the efficacy of clinical immunotherapy[J].Cell Res,2020,30(11):966-979.
[45] LIANG Q,CHEN J,HOU S,et al.Activatable Mn(2+)-armed nanoagonist augments antitumor immunity in colorectal cancer:A NIR-II photonic neoadjuvant paradigm[J].Biomaterials,2023,300:122206.
[46] CHEN M,LIANG X,GAO C,et al.Ultrasound triggered conversion of porphyrin/camptothecin-fluoroxyuridine triad microbubbles into nanoparticles overcomes multidrug resistance in colorectal cancer[J].ACS Nano,2018,12(7):7312-7326.
[47] LIU B,XU T,XU X,et al.Biglycan promotes the chemotherapy resistance of colon cancer by activating NF-κB signal transduction[J].Mol Cell Biochem,2018,449(1-2):285-294.
[48] PEI M,LIU K,QU X,et al.Enzyme-catalyzed synthesis of selenium-doped manganese phosphate for synergistic therapy of drug-resistant colorectal cancer[J].J Nanobiotechnology,2023,21(1):72.
[49] LIU J,LI L,ZHANG B,et al.MnO(2)-shelled Doxorubicin/Curcumin nanoformulation for enhanced colorectal cancer chemo-immunotherapy[J].J Colloid Interface Sci,2022,617:315-325.
[50] KIM SM,IM GH,LEE DG,et al.Mn(2+)-doped silica nanoparticles for hepatocyte-targeted detection of liver cancer in T1-weighted MRI[J].Biomaterials,2013,34(35):8941-8948.
[51] XIONG Y,XIAO C,LI Z,et al.Engineering nanomedicine for glutathione depletion-augmented cancer therapy[J].Chem Soc Rev,2021,50(10):6013-6041.
[52] TANG H,LI C,ZHANG Y,et al.Targeted manganese doped silica nano GSH-cleaner for treatment of liver cancer by destroying the intracellular redox homeostasis[J].Theranostics,2020,10(21):9865-9887.
[53] GOLRA A,KOZLOWSKI M,GUZIK P,et al.The role of selenium and manganese in the formation,diagnosis and treatment of cervical,endometrial and ovarian cancer[J].International Journal of Molecular Sciences,2023,24(13):10887.
[54] ZHANG L,CHEN Q,ZOU X,et al.Intelligent protein-coated bismuth sulfide and manganese oxide nanocomposites obtained by biomineralization for multimodal imaging-guided enhanced tumor therapy[J].J Mater Chem B,2019,7(34):5170-5181.
[55] ZHU J,LI H,XIONG Z,et al.Polyethyleneimine-coated manganese oxide nanoparticles for targeted tumor PET/MR imaging[J].ACS Appl Mater Interfaces,2018,10(41):34954-34964.
[56] HAN C,XIE T,WANG K,et al.Development of fluorescence/MR dual-modal manganese-nitrogen-doped carbon nanosheets as an efficient contrast agent for targeted ovarian carcinoma imaging[J].J Nanobiotechnology,2020,18(1):175.
[57] CHEN W,WANG X,ZHAO B,et al.CuS-MnS(2) nano-flowers for magnetic resonance imaging guided photothermal/photodynamic therapy of ovarian cancer through necroptosis[J].Nanoscale,2019,11(27):12983-12989.
[58] ABBASI AZ,PRASAD P,CAI P,et al.Manganese oxide and docetaxel co-loaded fluorescent polymer nanoparticles for dual modal imaging and chemotherapy of breast cancer[J].J Control Release,2015,209:186-196.
[59] XU X,ZHANG R,YANG X,et al.A honeycomb-like bismuth/manganese oxide nanoparticle with mutual reinforcement of internal and external response for triple-negative breast cancer targeted therapy[J].Adv Healthc Mater,2021,10(18):e2100518.