[1] D. Mao, F. Hu, Kenry, S. Ji, W. Wu, D. Ding, D. Kong, B. Liu, Metal-Organic-Framework-Assisted In Vivo Bacterial Metabolic Labeling and Precise Antibacterial Therapy, Advanced materials. 2018;30: e1706831.
[2] M. Falcone, D. Paterson, Spotlight on ceftazidime/avibactam: a new option for MDR Gram-negative infections, The Journal of antimicrobial chemotherapy. 2016;71:2713-22.
[3] M. Baym, L.K. Stone, R. Kishony, Multidrug evolutionary strategies to reverse antibiotic resistance, Science. 2016; 6268:351.
[4] Y. Wang, Y. Jin, W. Chen, J. Wang, H. Chen, L. Sun, X. Li, J. Ji, Q. Yu, L. Shen, B. Wang, Construction of nanomaterials with targeting phototherapy properties to inhibit resistant bacteria and biofilm infections, Chemical Engineering Journal. 2019;358:74-90.
[5] H.-H. Ran, X. Cheng, Y.-W. Bao, X.-W. Hua, G. Gao, X. Zhang, Y.-W. Jiang, Y.-X. Zhu, F.-G. Wu, Multifunctional quaternized carbon dots with enhanced biofilm penetration and eradication efficiencies, Journal of Materials Chemistry B. 2019;7:5104-5114.
[6] F. Liu, D. He, Y. Yu, L. Cheng, S. Zhang, Quaternary Ammonium Salt-Based Cross-Linked Micelles to Combat Biofilm, Bioconjugate chemistry. 2019;30:541-546.
[7] J.W. Costerton, P.S. Stewart, E.P. Greenberg, Bacterial biofilms: a common cause of persistent infections, Science. 1999;284:1318-22.
[8] D. Hu, Y. Deng, F. Jia, Q. Jin, J. Ji, Surface Charge Switchable Supramolecular Nanocarriers for Nitric Oxide Synergistic Photodynamic Eradication of Biofilms, ACS nano. 2020;14:347-359.
[9] W. Qian, C. Yan, D. He, X. Yu, L. Yuan, M. Liu, G. Luo, J. Deng, pH-triggered charge-reversible of glycol chitosan conjugated carboxyl graphene for enhancing photothermal ablation of focal infection, Acta Biomaterialia. 2018;69:256-64.
[10] C. Korupalli, C.C. Huang, W.C. Lin, W.Y. Pan, P.Y. Lin, W.L. Wan, M.J. Li, Y. Chang, H.W. Sung, Acidity-triggered charge-convertible nanoparticles that can cause bacterium-specific aggregation in situ to enhance photothermal ablation of focal infection, Biomaterials. 2017;116:1-9.
[11] Y. Zhao, X. Dai, X. Wei, Y. Yu, X. Chen, X. Zhang, C. Li, Near-Infrared Light-Activated Thermosensitive Liposomes as Efficient Agents for Photothermal and Antibiotic Synergistic Therapy of Bacterial Biofilm, ACS Applied Materials & Interfaces. 2018;10:14426-37.
[12] D. Hu, H. Li, B. Wang, Z. Ye, W. Lei, F. Jia, Q. Jin, K.-F. Ren, J. Ji, Surface-Adaptive Gold Nanoparticles with Effective Adherence and Enhanced Photothermal Ablation of Methicillin-Resistant Staphylococcus aureus Biofilm, ACS nano. 2017;11:9330-9.
[13] Y. Zhao, Q. Guo, X. Dai, X. Wei, Y. Yu, X. Chen, C. Li, Z. Cao, X. Zhang, A Biomimetic Non-Antibiotic Approach to Eradicate Drug-Resistant Infections. 2019;31:1806024.
[14] L. Zhang, Y. Wang, J. Wang, Y. Wang, A. Chen, C. Wang, W. Mo, Y. Li, Q. Yuan, Y. Zhang, Photon-Responsive Antibacterial Nanoplatform for Synergistic Photothermal-/Pharmaco-Therapy of Skin Infection, ACS Applied Materials & Interfaces. 2019;11:300-310.
[15] Q. Gao, X. Zhang, W. Yin, D. Ma, C. Xie, L. Zheng, X. Dong, L. Mei, J. Yu, C. Wang, Z. Gu, Y. Zhao, Functionalized MoS2 Nanovehicle with Near-Infrared Laser-Mediated Nitric Oxide Release and Photothermal Activities for Advanced Bacteria-Infected Wound Therapy, Small. 2018;14:e1802290.
[16] M.C. Wu, A.R. Deokar, J.H. Liao, P.Y. Shih, Y.C. Ling, Graphene-based photothermal agent for rapid and effective killing of bacteria, ACS nano. 2013;7:1281-90.
[17] J. Huang, J. Zhou, J. Zhuang, H. Gao, D. Huang, L. Wang, W. Wu, Q. Li, D.P. Yang, M.Y. Han, Strong Near-Infrared Absorbing and Biocompatible CuS Nanoparticles for Rapid and Efficient Photothermal Ablation of Gram-Positive and -Negative Bacteria, ACS Appl Mater Interfaces. 2017;9:36606-14.
[18] W. Lei, K. Ren, T. Chen, X. Chen, B. Li, H. Chang, J. Ji, Polydopamine Nanocoating for Effective Photothermal Killing of Bacteria and Fungus upon Near-Infrared Irradiation, Advanced Materials Interfaces. 2016;3:1600767.
[19] L. Xiao, J. Sun, L. Liu, R. Hu, H. Lu, C. Cheng, Y. Huang, S. Wang, J. Geng, Enhanced Photothermal Bactericidal Activity of the Reduced Graphene Oxide Modified by Cationic Water-Soluble Conjugated Polymer, ACS Appl Mater Interfaces. 2017;9:5382-91.
[20] M. Liu, D. He, T. Yang, W. Liu, L. Mao, Y. Zhu, J. Wu, G. Luo, J. Deng, An efficient antimicrobial depot for infectious site-targeted chemo-photothermal therapy, J Nanobiotechnology. 2018;16:23.
[21] C. Mao, Y. Xiang, X. Liu, Y. Zheng, K.W.K. Yeung, Z. Cui, X. Yang, Z. Li, Y. Liang, S. Zhu, S. Wu, Local Photothermal/Photodynamic Synergistic Therapy by Disrupting Bacterial Membrane To Accelerate Reactive Oxygen Species Permeation and Protein Leakage, ACS applied materials & interfaces. 2019;11:17902-14.
[22] S. Yu, G. Li, R. Liu, D. Ma, W. Xue, Dendritic Fe3O4@Poly(dopamine)@PAMAM Nanocomposite as Controllable NO-Releasing Material: A Synergistic Photothermal and NO Antibacterial Study, Adv. Funct. Mater. 2018;28:1707440.
[23] M.T. Pelegrino, R.B. Weller, X. Chen, J.S. Bernardes, A.B. Seabra, Chitosan nanoparticles for nitric oxide delivery in human skin, Medchemcomm. 2016;8:713-9.
[24] R. Zhan, F. Wang, Y. Wu, Y. Wang, W. Qian, M. Liu, T. Liu, W. He, H. Ren, G. Luo, Nitric oxide induces epidermal stem cell de-adhesion by targeting integrin β1 and Talin via the cGMP signalling pathway, Nitric oxide : biology and chemistry. 2018;78:1-10.
[25] G. Li, S. Yu, W. Xue, D. Ma, W. Zhang, Chitosan-graft-PAMAM loading nitric oxide for efficient antibacterial application, Chemical Engineering Journal. 2018;347:923-31.
[26] H. Jin, L. Yang, M.J.R. Ahonen, M.H. Schoenfisch, Nitric Oxide-Releasing Cyclodextrins, J Am Chem Soc. 2018;140(43);14178-84.
[27] P.G. Wang, M. Xian, X. Tang, X. Wu, Z. Wen, T. Cai, A.J. Janczuk, ChemInform Abstract: Nitric Oxide Donors: Chemical Activities and Biological Applications, ChemInform. 2002;33:1091-134.
[28] S. Sortino, Light-controlled nitric oxide delivering molecular assemblies, Chemical Society Reviews. 2010;39:2903-13.
[29] H.-J. Xiang, Q. Deng, L. An, M. Guo, S.-P. Yang, J.-G. Liu, Tumor cell specific and lysosome-targeted delivery of nitric oxide for enhanced photodynamic therapy triggered by 808 nm near-infrared light, Chemical Communications. 2016;52:148-51.
[30] S.R. Wecksler, A. Mikhailovsky, D. Korystov, P.C. Ford, A Two-Photon Antenna for Photochemical Delivery of Nitric Oxide from a Water-Soluble, Dye-Derivatized Iron Nitrosyl Complex Using NIR Light, J Am Chem Soc. 2006;128:3831-7.
[31] S. Diring, D.O. Wang, C. Kim, M. Kondo, Y. Chen, S. Kitagawa, K.-i. Kamei, S. Furukawa, Localized cell stimulation by nitric oxide using a photoactive porous coordination polymer platform, Nature communications. 2013;4:2684.
[32] W. Yin, J. Yu, F. Lv, L. Yan, L.R. Zheng, Z. Gu, Y. Zhao, Functionalized Nano-MoS2 with Peroxidase Catalytic and Near-Infrared Photothermal Activities for Safe and Synergetic Wound Antibacterial Applications, ACS nano. 2016;10:11000-11.
[33] L. Zheng, P. Qi, D. Zhang, A simple, rapid and cost-effective colorimetric assay based on the 4-mercaptophenylboronic acid functionalized silver nanoparticles for bacteria monitoring, Sensors and Actuators B: Chemical. 2018;260:983-9.
[34] L. Liang, Z. Liu, A self-assembled molecular team of boronic acids at the gold surface for specific capture of cis-diol biomolecules at neutral pH, Chemical Communications. 2011;47:2255-7.
[35] A. Galstyan, R. Schiller, U. Dobrindt, Boronic Acid Functionalized Photosensitizers: A Strategy To Target the Surface of Bacteria and Implement Active Agents in Polymer Coatings, Angew Chem Int Ed Engl. 2017;56(35):10362-6.
[36] Biological and Medicinal Applications of Boronic Acids, Boronic Acids; 2006. p. 481-512.
[37] Q. Tian, F. Jiang, R. Zou, Q. Liu, Z. Chen, M. Zhu, S. Yang, J. Wang, J. Wang, J. Hu, Hydrophilic Cu9S5 nanocrystals: a photothermal agent with a 25.7% heat conversion efficiency for photothermal ablation of cancer cells in vivo, ACS nano. 2011;5:9761-71.
[38] R. Guo, Y. Tian, Y. Wang, W. Yang, Near-Infrared Laser-Triggered Nitric Oxide Nanogenerators for the Reversal of Multidrug Resistance in Cancer, Advanced Functional Materials. 2017;27:1606398.
[39] D. Meng, S. Yang, L. Guo, G. Li, J. Ge, Y. Huang, C.W. Bielawski, J. Geng, The enhanced photothermal effect of graphene/conjugated polymer composites: photoinduced energy transfer and applications in photocontrolled switches, Chem Commun (Camb). 2014;50(92):14345-8.
[40] D.O. Lapotko, Nanophotonics and theranostics: will light do the magic?, Theranostics. 2013;3:138-40.
[41] D. Meng, S. Yang, D. Sun, Y. Zeng, J. Sun, Y. Li, S. Yan, Y. Huang, C.W. Bielawski, J. Geng, A dual-fluorescent composite of graphene oxide and poly(3-hexylthiophene) enables the ratiometric detection of amines, Chemical Science. 2014;5:3130-4.
[42] W. Hou, N.-J. Zhao, D. Meng, J. Tang, Y. Zeng, Y. Wu, Y. Weng, C. Cheng, X. Xu, Y. Li, J.-P. Zhang, Y. Huang, C.W. Bielawski, J. Geng, Controlled Growth of Well-Defined Conjugated Polymers from the Surfaces of Multiwalled Carbon Nanotubes: Photoresponse Enhancement via Charge Separation, ACS nano. 2016;10:5189-98.
[43] L. Marcotte, J. Barbeau, M. Lafleur, Permeability and thermodynamics study of quaternary ammonium surfactants-phosphocholine vesicle system, J Colloid Interface Sci. 2005;292:219-27.
[44] W. Fan, W. Bu, Z. Zhang, B. Shen, H. Zhang, Q. He, D. Ni, Z. Cui, K. Zhao, J. Bu, J. Du, J. Liu, J. Shi, X-ray Radiation-Controlled NO-Release for On-Demand Depth-Independent Hypoxic Radiosensitization, Angewandte Chemie International Edition. 2015;54:14026-30.
[45] H.C. Flemming, J. Wingender, U. Szewzyk, P. Steinberg, S.A. Rice, S. Kjelleberg, Biofilms: an emergent form of bacterial life, Nature reviews. Microbiology. 2016;14:563-75.
[46] A.F. Halbus, T.S. Horozov, V.N. Paunov, Strongly Enhanced Antibacterial Action of Copper Oxide Nanoparticles with Boronic Acid Surface Functionality, ACS Applied Materials & Interfaces. 2019;11:12232-43.
[47] H.-J. Xiang, M. Guo, L. An, S.-P. Yang, Q.-L. Zhang, J.-G. Liu, A multifunctional nanoplatform for lysosome targeted delivery of nitric oxide and photothermal therapy under 808 nm near-infrared light, Journal of Materials Chemistry B. 2016;4:4667-74.
[48] K. Turcheniuk, C.-H. Hage, J. Spadavecchia, A.Y. Serrano, I. Larroulet, A. Pesquera, A. Zurutuza, M.G. Pisfil, L. Héliot, J. Boukaert, R. Boukherroub, S. Szunerits, Plasmonic photothermal destruction of uropathogenic E. coli with reduced graphene oxide and core/shell nanocomposites of gold nanorods/reduced graphene oxide, Journal of Materials Chemistry B. 2015;3:375-86.
[49] F. Qiao Y Fau - Ma, C. Ma F Fau - Liu, C. Liu, Q. Zhou B Fau - Wei, W. Wei Q Fau - Li, D. Li W Fau - Zhong, Y. Zhong D Fau - Li, M. Li Y Fau - Zhou, M.A.-O.h.o.o. Zhou, Near-Infrared Laser-Excited Nanoparticles To Eradicate Multidrug-Resistant Bacteria and Promote Wound Healing, ACS Appl Mater Interfaces. 2018;10(1):193-206.
[50] L. Xie, Q. Bao, A. Terada, M. Hosomi, Single-cell analysis of the disruption of bacteria with a high-pressure jet device: An application of atomic force microscopy, Chemical Engineering Journal. 2016;306:1099-108.
[51] X. Yu, D. He, X. Zhang, H. Zhang, J. Song, D. Shi, Y. Fan, G. Luo, J. Deng, Surface-Adaptive and Initiator-Loaded Graphene as a Light-Induced Generator with Free Radicals for Drug-Resistant Bacteria Eradication, ACS Applied Materials & Interfaces. 2019;11:1766-81.
[52] N. Kurantowicz, B. Strojny, E. Sawosz, S. Jaworski, M. Kutwin, M. Grodzik, M. Wierzbicki, L. Lipińska, K. Mitura, A. Chwalibog, Biodistribution of a High Dose of Diamond, Graphite, and Graphene Oxide Nanoparticles After Multiple Intraperitoneal Injections in Rats, Nanoscale Research Letters. 2015;10:398.
[53] K.-H. Liao, Y.-S. Lin, C.W. Macosko, C.L. Haynes, Cytotoxicity of Graphene Oxide and Graphene in Human Erythrocytes and Skin Fibroblasts, ACS Appl Mater Interfaces. 2011;3(7):2607-15.
[54] L. Wang, Y. Chen, H.Y. Lin, Y.-T. Hou, L.-C. Yang, A.Y. Sun, J.-Y. Liu, C.-W. Chang, D. Wan, Near-IR-Absorbing Gold Nanoframes with Enhanced Physiological Stability and Improved Biocompatibility for In Vivo Biomedical Applications, ACS Appl Mater Interfaces. 2017;9(4):3873-84.
[55] G. Lalwani, M. D'Agati, A.M. Khan, B. Sitharaman, Toxicology of graphene-based nanomaterials, Advanced Drug Delivery Reviews. 2016;105:109-44.
[56] L. Ou, B. Song, H. Liang, J. Liu, X. Feng, B. Deng, T. Sun, L. Shao, Toxicity of graphene-family nanoparticles: a general review of the origins and mechanisms, Particle and Fibre Toxicology. 2016;13:57.
[57] R. Li, L.M. Guiney, C.H. Chang, N.D. Mansukhani, Z. Ji, X. Wang, Y.-P. Liao, W. Jiang, B. Sun, M.C. Hersam, A.E. Nel, T. Xia, Surface Oxidation of Graphene Oxide Determines Membrane Damage, Lipid Peroxidation, and Cytotoxicity in Macrophages in a Pulmonary Toxicity Model, ACS nano. 2018;12:1390-402.
[58] X. Feng, L. Chen, W. Guo, Y. Zhang, X. Lai, L. Shao, Y. Li, Graphene oxide induces p62/SQSTM-dependent apoptosis through the impairment of autophagic flux and lysosomal dysfunction in PC12 cells, Acta biomaterialia. 2018;81:278-92.
[59] N. Chatterjee, J.S. Yang, K. Park, S.M. Oh, J. Park, J. Choi, Screening of toxic potential of graphene family nanomaterials using in vitro and alternative in vivo toxicity testing systems, Environ Health Toxicol. 2015;30:e2015007.
[60] P.-P. Jia, T. Sun, M. Junaid, L. Yang, Y.-B. Ma, Z.-S. Cui, D.-P. Wei, H.-F. Shi, D.-S. Pei, Nanotoxicity of different sizes of graphene (G) and graphene oxide (GO) in vitro and in vivo, Environ Pollut. 2019;247:595-606.
[61] M. Xu, J. Zhu, F. Wang, Y. Xiong, Y. Wu, Q. Wang, J. Weng, Z. Zhang, W. Chen, S. Liu, Improved In Vitro and In Vivo Biocompatibility of Graphene Oxide through Surface Modification: Poly(Acrylic Acid)-Functionalization is Superior to PEGylation, ACS nano. 2016;10:3267-81.
[62] Y. Li, L. Feng, X. Shi, X. Wang, Y. Yang, K. Yang, T. Liu, G. Yang, Z. Liu, Surface coating-dependent cytotoxicity and degradation of graphene derivatives: towards the design of non-toxic, degradable nano-graphene, Small. 2014;10(8):1544-54.
[63] W.L.A. Brooks, B.S. Sumerlin, Synthesis and Applications of Boronic Acid-Containing Polymers: From Materials to Medicine, Chemical Reviews. 2016;116:1375-97.