[1]	Gao J, Wang F, Wang S, . Hyperthermia-triggered on-demand biomimetic nanocarriers for synergetic photothermal and chemotherapy. Advanced Science, 2020, 7(11): 1903642 CrossRef Pubmed Google scholar

[2]	Wang X, Jiang G, Li X, . Synthesis of multi-responsive polymeric nanocarriers for controlled release of bioactive agents. Polymer Chemistry, 2013, 4(17): 4574–4577 CrossRef Google scholar

[3]	Song G, Jiang G, Liu T, . Separable microneedles for synergistic chemo-photothermal therapy against superficial skin tumors. ACS Biomaterials Science & Engineering, 2020, 6(7): 4116–4125 CrossRef Pubmed Google scholar

[4]	Liu J, Zheng J, Nie H, . Co-delivery of erlotinib and doxorubicin by MoS2 nanosheets for synergetic photothermal chemotherapy of cancer. Chemical Engineering Journal, 2020, 381: 122541 CrossRef Google scholar

[5]	Kobayashi H, Watanabe R, Choyke P L. Improving conventional enhanced permeability and retention (EPR) effects; what is the appropriate target? Theranostics, 2014, 4(1): 81–89 CrossRef Pubmed Google scholar

[6]	Kalyane D, Raval N, Maheshwari R, . Employment of enhanced permeability and retention effect (EPR): Nanoparticle-based precision tools for targeting of therapeutic and diagnostic agent in cancer. Materials Science and Engineering C, 2019, 98: 1252–1276 CrossRef Pubmed Google scholar

[7]	Xu F, Liu M, Li X, . Loading of indocyanine green within polydopamine-coated laponite nanodisks for targeted cancer photothermal and photodynamic therapy. Nanomaterials, 2018, 8(5): 347 CrossRef Pubmed Google scholar

[8]	Zhang S, Cao C, Lv X, . A H2O2 self-sufficient nanoplatform with domino effects for thermal-responsive enhanced chemodynamic therapy. Chemical Science, 2020, 11(7): 1926–1934 CrossRef Google scholar

[9]	Zhang M, Cao Y, Wang L, . Manganese doped iron oxide theranostic nanoparticles for combined T1 magnetic resonance imaging and photothermal therapy. ACS Applied Materials & Interfaces, 2015, 7(8): 4650–4658 CrossRef Pubmed Google scholar

[10]	Fan W, Bu W, Shen B, . Intelligent MnO2 nanosheets anchored with upconversion nanoprobes for concurrent pH-/H2O2-responsive UCL imaging and oxygen-elevated synergetic therapy. Advanced Materials, 2015, 27(28): 4155–4161 CrossRef Pubmed Google scholar

[11]	Zhao Z, Fan H, Zhou G, . Activatable fluorescence/MRI bimodal platform for tumor cell imaging via MnO2 nanosheet-aptamer nanoprobe. Journal of the American Chemical Society, 2014, 136(32): 11220–11223 CrossRef Pubmed Google scholar

[12]	Sun P, Deng Q, Kang L, . A smart nanoparticle-laden and remote-controlled self-destructive macrophage for enhanced chemo/chemodynamic synergistic therapy. ACS Nano, 2020, 14(10): 13894–13904 CrossRef Pubmed Google scholar

[13]	Lin L S, Song J, Song L, . Simultaneous fenton-like ion delivery and glutathione depletion by MnO2-based nanoagent to enhance chemodynamic therapy. Angewandte Chemie International Edition, 2018, 57(18): 4902–4906 CrossRef Pubmed Google scholar

[14]	Zhang M, Xing L, Ke H, . MnO2-based nanoplatform serves as drug vehicle and MRI contrast agent for cancer. ACS Applied Materials & Interfaces, 2017, 9(13): 11337–11344 CrossRef Pubmed Google scholar

[15]	Zhang Z, Ji Y. Nanostructured manganese dioxide for anticancer applications: Preparation, diagnosis, and therapy. Nanoscale, 2020, 12(35): 17982–18003 CrossRef Pubmed Google scholar

[16]	Zeng W, Zhang H, Deng Y, . Dual-response oxygen-generating MnO2 nanoparticles with polydopamine modification for combined photothermal–photodynamic therapy. Chemical Engineering Journal, 2020, 389: 124494 CrossRef Google scholar

[17]	Yang G, Xu L, Chao Y, . Hollow MnO2 as a tumor-microenvironment-responsive biodegradable nano-platform for combination therapy favoring antitumor immune responses. Nature Communications, 2017, 8(1): 902 CrossRef Pubmed Google scholar

[18]	Liu Y, Ai K, Liu J, . Dopamine-melanin colloidal nanospheres: An efficient near-infrared photothermal therapeutic agent for in vivo cancer therapy. Advanced Materials, 2013, 25(9): 1353–1359 CrossRef Pubmed Google scholar

[19]	Ou C, Zhang Y, Pan D, . Zinc porphyrin-polydopamine core–shell nanostructures for enhanced photodynamic/photothermal cancer therapy. Materials Chemistry Frontiers, 2019, 3(9): 1786–1792 CrossRef Google scholar

[20]	Guo H, Sun H, Zhu H, . Synthesis of Gd-functionalized Fe3O4@polydopamine nanocomposites for T1/T2 dual-modal magnetic resonance imaging-guided photothermal therapy. New Journal of Chemistry, 2018, 42(9): 7119–7124 CrossRef Google scholar

[21]	Gong C, Lu C, Li B, . Dopamine-modified poly(amino acid): An efficient near-infrared photothermal therapeutic agent for cancer therapy. Journal of Materials Science, 2017, 52(2): 955–967 CrossRef Google scholar

[22]	Liu C, Cao Y, Cheng Y, . An open source and reduce expenditure ROS generation strategy for chemodynamic/photodynamic synergistic therapy. Nature Communications, 2020, 11(1): 1735 CrossRef Pubmed Google scholar

[23]	Zhao Z, Wang W, Li C, . Reactive oxygen species-activatable liposomes regulating hypoxic tumor microenvironment for synergistic photo/chemodynamic therapies. Advanced Functional Materials, 2019, 29(44): 1905013 CrossRef Google scholar

[24]	Huang P, Bao L, Zhang C, . Folic acid-conjugated silica-modified gold nanorods for X-ray/CT imaging-guided dual-mode radiation and photo-thermal therapy. Biomaterials, 2011, 32(36): 9796–9809 CrossRef Pubmed Google scholar

[25]	Tang X, Zhao C, Li Z, . Hollow sandwich-structured N-doped carbon–silica–carbon nanocomposite anode materials for Li-ion batteries. Journal of Physics: Conference Series, 2020, 1520: 012012 CrossRef Google scholar

[26]	Boyjoo Y, Wang M, Pareek V K, . Synthesis and applications of porous non-silica metal oxide submicrospheres. Chemical Society Reviews, 2016, 45(21): 6013–6047 CrossRef Pubmed Google scholar

[27]	Boyjoo Y, Rochard G, Giraudon J-M, . Mesoporous MnO2 hollow spheres for enhanced catalytic oxidation of formaldehyde. Sustainable Materials and Technology, 2019, 20: e00091 CrossRef Google scholar

[28]	Cheng M, Yu Y, Huang W, . Monodisperse hollow MnO2 with biodegradability for efficient targeted drug delivery. ACS Biomaterials Science & Engineering, 2020, 6(9): 4985–4992 CrossRef Pubmed Google scholar

[29]	Lin B, Chen H, Liang D, . Acidic pH and high-H2O2 dual tumor microenvironment-responsive nanocatalytic graphene oxide for cancer selective therapy and recognition. ACS Applied Materials & Interfaces, 2019, 11(12): 11157–11166 CrossRef Pubmed Google scholar

[30]	Kirtane A R, Kalscheuer S M, Panyam J. Exploiting nanotechno-logy to overcome tumor drug resistance: Challenges and opportunities. Advanced Drug Delivery Reviews, 2013, 65(13–14): 1731–1747 CrossRef Pubmed Google scholar

[31]	Xiong X B, Huang Y, Lu W L, . Intracellular delivery of doxorubicin with RGD-modified sterically stabilized liposomes for an improved antitumor efficacy: in vitro and in vivo. Journal of Pharmaceutical Sciences, 2005, 94(8): 1782–1793 CrossRef Pubmed Google scholar

[32]

Li J, Cai D, Yao X, . Protective effect of ginsenoside Rg1 on hematopoietic stem/progenitor cells through attenuating oxidative stress and the Wnt/β-catenin signaling pathway in a mouse model of d-galactose-induced aging. International Journal of Molecular Sciences, 2016, 17(6): 849 CrossRef Pubmed Google scholar