[1] 王学川,王雪莹,杨淑琴,等.微生物胶原酶研究进展[J].皮革科学与工程,2021,31(2):16-22. [2] 胡可欣,李国英.没食子酸对胶原蛋白膜的改性研究[J].皮革科学与工程,2020,30(4):1-6. [3] Takehiko Mima,Kazuyoshi Gotoh,Yumiko Yamamoto,et al.Expression of collagenase is regulated by the VarS/VarA two-component regulatory system in vibrio alginolyticus[J].The Journal of Membrane Biology,2018,251(1):51-63. [4] Amanda J.Brosnahan,Patrick M.Schlievert.Gram-positive bacterial superantigen outside-in signaling causes toxic shock syndrome[J].FEBS Journal,2011,278(23):4649-4667. [5] Thomas R.Martin,Naoki Hagimoto,Morio Nakamura,et al.Apoptosis and epithelial injury in the lungs[J].Proceedings of the American Thoracic Society,2005,2(3):214-220. [6] Chang Jinming,Chen Yi,Zhao Shiyu,et al.Poly(N-acryloyl ciprofloxacin-co-acrylic acid)grafted magnetite nanoparticles for microbial decontamination of collagen solution:have we conquered the problem of antimicrobial residues?[J].Polymer Chemistry,2015,6(47):8150-8160. [7] Wang Lei,Li Xin,Sun Tianyu, et al.Dual-functional dextran-PEG hydrogel as an antimicrobial biomedical material[J].Macromolecular Bioscience,2018,18(2):1700325. [8] Rustam Aminov.History of antimicrobial drug discovery:major classes and health impact[J].Biochemical Pharmacology,2017,133:4-19. [9] Yan Shunjie, Luan Shifang,Shi Hengchong,et al.Hierarchical polymer brushes with dominant antibacterial mechanisms switching from bactericidal to bacteria repellent[J].Biomacromolecules,2016,17(5):1696-1704. [10] Stuart B.Levy.The challenge of antibiotic resistance[J].Scientific American,1998,278(3):46-53. [11] Farrell LJ, Lo R, Wanford JJ,et al.Revitalizing the drug pipeline:AntibioticDB,an open access database to aid antibacterial research and development[J].Journal of Antimicrobial Chemotherapy,2018,73(9):2284-2297. [12] 杨高夫. 刺激响应型环丙沙星的制备及其抗菌活性开关控制研究[D].成都:四川大学,2021:9-10. [13] Pau Gorostiza,Ehud Y.Isacoff.Optical switches for remote and noninvasive control of cell signaling[J].Science,2008,322(5900):395-399. [14] Günter Mayer,Alexander Heckel.Biologically active molecules with a“light switch”[J].Angewandte Chemie International Edition,2006,45(30):4900-4921. [15] Armaĝan Koçer,Martin Walko,Wim Meijberg,etal.A light-actuated nanovalve derived from a channel protein[J].Science,2005,309(5735):755-758. [16] Lee Wenlin,Li Zhihong,Sergei Vakulenko,et al.A light-inactivated antibiotic[J].Journal of Medicinal Chemistry,2000,43(1):128-132. [17] Willem A.Velema,Jan Pieter van der Berg,Mickel J.Hansen,et al.Optical control of antibacterial activity[J].Nature Chemistry,2013,5(11):924-928. [18] Yasuhiro Matsumura,Honnavara N Ananthaswamy.Toxic effects of ultraviolet radiation on the skin[J].Toxicology and Applied Pharmacology,2004,195(3):298-308. [19] Katrin Kalka, Hans Merk, Hasan Mukhtar.Photodynamic therapy in dermatology[J]. Journal of the American Academy of Dermatology,2000,42(3):389-413. [20] Michael Wegener,Mickel J.Hansen,Arnold J.M.Driessen,et al.Photocontrol of antibacterial activity:shifting from UV to red light activation[J].Journal of the American Chemical Society,2017,139:17979-17986. [21] Li Ziyong,Wang Yangyang, Li Mengna,et al.Synthesis and properties of dithienylethene-functionalized switchable antibacterial agents[J].Organic&Biomolecular Chemistry,2018,16(38):6988-6997. [22] Hou Delong, Wang Rui, Wang Zhonghui, et al.A light-activatable antibiotic with high activation efficiency and uncompromised bactericidal potency in the activated state[J].Journal of Leather Science and Engineering,2021,3:8. [23] Inga S.Shchelik,Andrea Tomio,Karl Gademann.Design,synthesis,and biological evaluation of light-activated antibiotics[J].ACS Infectious Diseases,2021,7(3):681-692. [24] Sameer Varma,See-Wing Chiu,Eric Jakobsson.The influence of amino acid protonation states on molecular dynamics simulations of the bacterial porin OmpF[J].Biophysical journal,2006,90(1):112-123. [25] Chang Jinming, Chen Yi, Xu Zhou,et al.Switchable control of antibiotic activity:a shape-shifting“tail”strategy[J].Bioconjugate Chemistry,2018,29(1):74-82. [26] Chang Jinming,Xu Zhou,Yang Gaofu,et al.Thermally responsive collagen switching from bactericidal for ambient storage condition to biologically inert in vivo[J].Journal of the American Leather Chemists Association,2018,113(4):114-121. [27] Hollie Hathaway, Jude Ajuebor,Liam Stephens,et al.Thermally triggered release of the bacteriophage endolysin CHAPK and the bacteriocin lysostaphin for the control of methicillin resistant staphylococcus aureus(MRSA)[J].Journal of the Controlled Release Society,2017,245:108-115. [28] Sandeep J.Sonawane,Rahul S.Kalhapure,Mahantesh Jadhav,et al.AB2-type amphiphilic block copolymer containing a pH-cleavable hydrazone linkage for targeted antibiotic delivery[J].International Journal of Pharmaceutics,2020,575,118948. [29] Loic Pichavant,Chantal Bourget,Marie-Christine Durrieu,et al.Synthesis of pH-sensitive particles for local delivery of an antibiotic via dispersion ROMP[J].Macromolecules,2011,44(20):7879-7887. [30] Parasmani Pageni, Peng Yang,Marpe Bam,et al.Recyclable magnetic nanoparticles grafted with antimicrobial metallopolymer-antibiotic bioconjugates[J].Biomaterials,2018, 178:363-372. [31] Jason Lagona,Pritam Mukhopadhyay,Sriparna Chakrabarti,et al.The cucurbit[n]uril family[J].Angewandte Chemie International Edition,2005,44(31):4844-4870. [32] BaiHaotian, Yuan Huanxiang, Nie Chenyao, et al. A supramolecular antibiotic switch for antibacterial regulation[J].Angewandte Chemie International Edition,2015,54(45):13208-13213. [33] Huang Zehuan, Zhang Hongyi, Bai Haotian,et al.Polypseudorotaxane constructed from cationic polymer with cucurbit[7]uril for controlled antibacterial activity[J].ACS Macro Letters,2016,5(10):1109-1113. [34] Steven J.Barrow,Setu Kasera,Matthew J.Rowland,et al.Cucurbituril-based molecular recognition[J].Chemical Reviews.2015,115(22):12320-12406. [35] Li Shengke, Jiang Nan, Zhao Wenxuan,et al.An eco-friendly in situ activatable antibiotic via cucurbit[8]uril-mediated supramolecular crosslinking of branched polyethylenimine[J].Chemical Communications,2017,53(43):5870-5873. |