[1] F LOVELL J, B LIU T W, JUAN CHEN et al. Activatable photosensitizers for imaging and therapy. Chemical Reviews, 110, 2839-2857(2010).
[2] P CELLI J, Q SPRING B, I RIZVI et al. Imaging and photodynamic therapy: mechanisms, monitoring, and optimization. Chemical Reviews, 110, 2795-2838(2010).
[3] J DOLMANS D E J G, D FUKUMURA, K JAIN R. Photodynamic therapy for cancer. Nature Reviews Cancer, 3, 380-387(2003).
[4] B PENG, K ANG P, P LOH K. Two-dimensional dichalcogenides for light-harvesting applications. Nano Today, 10, 128-137(2015).
[5] L LI, J KIM, C JIN et al. Direct observation of the layer-dependent electronic structure in phosphorene. Nature Nanotechnology, 12, 21-25(2016).
[6] XUAN-HUA LI, JIN-MENG ZHU, BING-QING WEI. Hybrid nanostructures of metal/two-dimensional nanomaterials for plasmon- enhanced applications. Chemical Society Reviews, 45, 3145-3187(2016).
[7] S NOVOSELOV K, K GEIM A, V MOROZOV S et al. Electric field effect in atomically thin carbon films. Science, 306, 666-669(2004).
[8] M CHHOWALLA, ZHONG-FAN LIU, HUA ZHANG. Two- dimensional transition metal dichalcogenide (TMD) nanosheets. Chemical Society Reviews, 44, 2584-2586(2015).
[9] J ALLEN M, C TUNG V, B KANER R. Honeycomb carbon: a review of graphene. Chemical Reviews, 110, 132-145(2009).
[10] M NAGUIB, M KURTOGLU, V PRESSER et al. Two-dimensional nanocrystals produced by exfoliation of Ti3AlC2. Advanced Materials, 23, 4248-4253(2011).
[11] HAN LIU, T NEAL A, ZHEN ZHU et al. Phosphorene: a new 2D material with high carrier mobility. ACS Nano, 8, 4033-4041(2014).
[12] S MANZELI, D OVCHINNIKOV, D PASQUIER et al. 2D transition metal dichalcogenides. Nature Reviews Materials, 2, 17(2017).
[13] XU ZHANG, XU-DONG ZHAO, DI-HUA WU et al. MnPSe3 monolayer: a promising 2D visible-light photohydrolytic catalyst with high carrier mobility. Advanced Science, 3, 1600(2016).
[14] XING-XING LI, XIAO-JUN WU, JIN-LONG YANG. Half-metallicity in MnPSe3 exfoliated nanosheet with carrier doping. Journal of the American Chemical Society, 136, 110-110(2014).
[15] D MUKHERJEE, M AUSTERIA P, S SAMPATH. Two-dimensional, few-layer phosphochalcogenide, FePS3: a new catalyst for electrochemical hydrogen evolution over wide pH range. ACS Energy Letters, 1, 367-372(2016).
[16] KE-ZHAO DU, XING-ZHI WANG, YANG LIU et al. Weak van der Waals stacking, wide-range band gap, and Raman study on ultrathin layers of metal phosphorus trichalcogenides. ACS Nano, 10, 1738-1743(2015).
[17] QIU-HONG ZHANG, QIANG-BING GUO, QIAN CHEN et al. Highly efficient 2D NIR-II photothermal agent with fenton catalytic activity for cancer synergistic photothermal-chemodynamic therapy. Advanced Science, 7, 1902(2020).
[18] XUE-YANG FANG, XIAN-LIN WU, ZHEN-DONG LI et al. Biomimetic anti-PD-1 peptide-loaded 2D FePSe3 nanosheets for efficient photothermal and enhanced immune therapy with multimodal MR/PA/thermal imaging. Advanced Science, 8, 200(2020).
[19] LIANG CHENG, JING-JING LIU, XING GU et al. PEGylated WS2 nanosheets as a multifunctional theranostic agent for in vivo dual-modal CT/photoacoustic imaging guided photothermal therapy. Advanced Materials, 26, 1886-1893(2014).
[20] HAN LIN, SHAN-SHAN GAO, CHEN DAI et al. Two-dimensional biodegradable niobium carbide (MXene) for photothermal tumor eradication in NIR-I and NIR-II bio-windows. Journal of the American Chemical Society, 139, 162-162(2017).
[21] N COLEMAN J, M LOTYA, A O’NEILL et al. Two-dimensional nanosheets produced by liquid exfoliation of layered materials. Science, 331, 568-571(2011).
[22] WEI ZHAO, AI-HUA LI, AI-TANG ZHANG et al. Recent advances in functional-polymer-decorated transition-metal nanomaterials for bioimaging and cancer therapy. ChemMedChem, 13, 2134-2149(2018).
[23] YONG-CAI ZHANG, ZHEN-NI DU, KUN-WEI LI et al. High- performance visible-light-driven SnS/SnO nanocomposite photocatalyst prepared via in situ hydrothermal oxidation of SnS nanoparticles. ACS Applied Materials & Interfaces, 3, 1528-1537(2011).
[24] ZHONG-ZHOU CHENG, FENG-MEI WANG, A SHIFA T et al. Efficient photocatalytic hydrogen evolution via band alignment tailoring: controllable transition from type-I to type-II. Small, 13, 170(2017).
[25] PENG CHEN, YUN SU, HONG LIU et al. Interconnected tin disulfide nanosheets grown on graphene for Li-ion storage and photocatalytic applications. ACS Applied Materials & Interfaces, 5, 120-120(2013).
[26] R DETTY M, L GIBSON S, J WAGNER S. Current clinical and preclinical photosensitizers for use in photodynamic therapy. Journal of Medicinal Chemistry, 47, 3897-3915(2004).
[27] M SHARMAN W, M ALLEN C, E VAN LIER J. Photodynamic therapeutics: basic principles and clinical applications. Drug Discovery Today, 4, 507-517(1999).
[28] HUI WANG, XIAN-ZHU YANG, WEI SHAO et al. Ultrathin black phosphorus nanosheets for efficient single oxygen generation. Journal of the American Chemical Society, 137, 113-113(2015).
[29] CHEN LIANG, XING-LIN ZHANG, MENG-SU YANG et al. Remodeling tumor microenvironment by multifunctional nanoassemblies for enhanced photodynamic cancer therapy. ACS Materials Letters, 2, 1268-1286(2020).
[30] XIAN-GUANG DING, H LIOW C, MENG-XIN ZHANG et al. Surface plasmon resonance enhanced light absorption and photothermal therapy in the second near-infrared window. Journal of the American Chemical Society, 136, 156-1569(2014).
[31] N BASHKATOV A, A GENINA E, I KOCHUBEY V et al. Optical properties of human skin, subcutaneous and mucous tissues in the wavelength range from 400 to 2000 nm. Journal of Physics D: Applied Physics, 38, 2543(2005).
[32] T ROBINSON J, M TABAKMAN S, YONG-YE LIANG et al. Ultrasmall reduced graphene oxide with high near-infrared absorbance for photothermal therapy. Journal of the American Chemical Society, 133, 6825-6831(2011).
[33] C LI K, C CHU H, Y LIN et al. PEGylated copper nanowires as a novel photothermal therapy agent. ACS Applied Materials & Interfaces, 8, 1208-1209(2016).
[34] CAI-XIA SUN, LING WEN, JIAN-FENG ZENG et al. One-pot solventless preparation of PEGylated black phosphorus nanoparticles for photoacoustic imaging and photothermal therapy of cancer. Biomaterials, 91, 81-89(2016).
[35] M GIORGIO, E MIGLIACCIO, F ORSINI et al. Electron transfer between cytochrome c and p66Shc generates reactive oxygen species that trigger mitochondrial apoptosis. Cell, 122, 221-233(2005).
[36] N DANIAL N, J KORSMEYER S. Cell death: critical control points. Cell, 116, 205-219(2004).
[37] YI WANG, GUO-QING WEI, XIAO-BIN ZHANG et al. Multistage targeting strategy using magnetic composite nanoparticles for synergism of photothermal therapy and chemotherapy. Small, 14, 1702(2018).