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个人简介 陈晓青，女，博士，二级教授，博士生导师，享受国务院政府特殊津贴。中南大学“531”二层次人才，“食品药品分子科学研究中心”主任。致力于生物、环境复杂体系分离分析，手性对映体识别与分离分析，生物、环境与食品安全及时检测（POCT）的研发。在Angew. Chem. Int. Ed., Anal. Chem., Chem. Commun., Org. Lett. 等国际权威刊物上发表SCI收录论文300余篇，其中ESI高被引论文12篇(ORCID: 0000-0002-8768-8965)，H指数为54。入围职业生涯全球top 2%科学家（主学科：分析化学，副学科：有机化学）。主持承担国家自然科学基金面上项目7项、及其他纵、横向项目近40项。2020年获湖南省自然科学二等奖1项，2013年获湖南省发明二等奖1项，2003年获湖南省进步一等奖1项。授权发明专利9项。 近年来代表性科研论文: 2024： [1] Au/Pt@ZIF-90 Nanoenzyme Capsule-Based "Explosive" Signal Amplifier for "All-in-Tube" POCT, Analytical Chemistry 2024, 96(3), 1362–1370. [2] Photoinduced, Palladium-Catalyzed Enantioselective 1,2-Alkylsulfonylation of 1,3-Dienes, ACS Catalysis 2024, 14(5), 3725–3732. 2023： [1] Quinine-Fabricated Surface-Enhanced Raman Spectroscopy Chiral Sensing Platform Enables Simultaneous Enantioselective Discrimination and Identification of Aliphatic Amino Acids, Analytical Chemistry 2023, 95(11), 4923-4931. [2] Endogenous mRNA-Powered and Spatial Confinement-Derived DNA Nanomachines for Ultrarapid and Sensitive Imaging of Let-7a, Analytical Chemistry, 2023, 96(1), 564–571. [3] Pore Size Tunable Trypsin@ ZIF-90 and Hydrogel Integrated Lateral Flow Point-of-Care Platform for ATP Detection. ACS Applied Materials & Interfaces, 2023 15(17), 21690-21698. 2022： [1] Photoredox‐Catalyzed Deoxygenation of Hexafluoroacetone Hydrate Enables Hydroxypolyfluoroalkylation of Alkenes." Angewandte Chemie International Edition 2022, 61, e2022110. [2] Regioselective Access to Vicinal Diamines by Metal‐Free Photosensitized Amidylimination of Alkenes with Oxime Esters. Angewandte Chemie International Edition 2022, 61,  e2022122. [3] Deep Learning-Based Label-Free Surface-Enhanced Raman Scattering Screening and Recognition of Small-Molecule Binding Sites in Proteins. Analytical Chemistry 2022, 94(33), 11483-11491. [4] Framework Nucleic Acid-Based Spatial-Confinement Amplifier for miRNA Imaging in Living Cells, Analytical Chemistry 2022, 94(6): 2934-2941 [5] Deep learning-based multicapturer SERS platform on plasmonic nanocube metasurfaces for multiplex detection of organophosphorus pesticides in environmental water. Analytical Chemistry 2022, 94(46), 16006-16014. [6] Facile construction of a reusable multi-enzyme cascade bioreactor for effective fluorescence discrimination and quantitation of amino acid enantiomers, Chemical Engineering Journal 2022, 428: 131975. 2021： [1] Simultaneous In Situ Extraction and Self-Assembly of Plasmonic Colloidal Gold Superparticles for SERS Detection of Organochlorine Pesticides in Water, Analytical Chemistry 2021, 93(10): 4657-4665 [2] AIEgen modulated per-functionalized flower-like IRMOF-3 frameworks with tunable light emission and excellent sensing properties, Chemical Communications 2021, 57: 2392-2395 [3] Framework nucleic acid programmed combinatorial delivery nanocarriers for parallel and multiplexed analysis, Chemical Communications 2021, 57, 10935-10938 [4] Photocatalytic Cyclization/Defluorination Domino Sequence to Access 3-Fluoro-1,5-dihydro-2H-pyrrol-2-one Scaffold, Organic Letters 2021, 23(12): 4754-4758 [5] Phosphonium ylide-mediated programmable fluorination to access mono-and difluoromethylarenes, Organic Letters 2021, 23(7): 2538-2542 [6] O-Perhalopyridin-4-yl Hydroxylamines: Amidyl-Radical Generation Scaffolds in Photoinduced Direct Amination of Heterocycles, Organic Letters 2021, 23(5): 1643-1647 [7] Enantioselectivity-Switchable Organocatalytic [4+ 2]-Annulation to Access the Spirooxindole–Norcamphor Scaffold, Organic Letters 2021, 23(3): 963-968 2020:[1] Integrating Target-Triggered Aptamer-Capped HRP@ Metal–Organic Frameworks with a Colorimeter Readout for On-Site Sensitive Detection of Antibiotics, Analytical Chemistry 2020, 92(20): 14259–14266. [2] l-Pyroglutamic Acid-Modified CdSe/ZnS Quantum Dots: A New Fluorescence-Responsive Chiral Sensing Platform for Stereospecific Molecular Recognition, Analytical Chemistry 2020, 92(17): 12040-12048. [3] “Pomegranate-like” plasmonic nanoreactors with accessible high-density hotspots for in situ SERS monitoring of catalytic reactions, Analytical Chemistry 2020, 92(5): 4115-4122.[4] Photoinduced Single‐Electron Transfer as an Enabling Principle in the Radical Borylation of Alkenes with NHC–Borane, Angewandte Chemie International Edition 2020, 59: 6706 –6710. [5] Photocatalytic C–F bond borylation of polyfluoroarenes with NHC-boranes, Organic Letters 2020, 22(5): 1742-1747. [6] Phosphine-mediated MBH-type/umpolung addition domino sequence: Divergent construction of coumarins, Organic Letters 2020, 22(2): 488-492. [7] AIE-active metal–organic frameworks: Facile preparation, tunable light emission, ultrasensitive sensing of copper (II) and visual fluorescence detection of glucose, Journal of Materials Chemistry C 2020, 8: 10408-10415 2019:[1] Development of a “dual gates” locked, target-triggered nanodevice for point-of-care testing with a glucometer readout, ACS Sensors 2019, 4(4): 968-976.[2] Intelligent platform for simultaneous detection of multiple aminoglycosides based on a ratiometric paper-based device with digital fluorescence detector readout, ACS Sensors 2019, 4(12): 3283-3290.[3] Organocatalytic, Enantioselective, Polarity-Matched Ring-Reorganization Domino Sequence Based on the 3‑Oxindole Scaffold, Organic Letters 2019, 21(7): 2166-2170.[4] Photocatalytic, phosphoranyl radical-mediated N–O cleavage of strained cycloketone oximes, Organic Letters 2019, 21(8): 2658-2662.[5] Rapid and visual detection of aflatoxin B1 in foodstuffs using aptamer/G-quadruplex DNAzyme probe with low background noise, Food Chemistry 2019, 271: 581-587.2018:[1] Valency‐Controlled Framework Nucleic Acid Signal Amplifiers, Angewandte Chemie International Edition 2018, 57, 7131-7135.[2] Simultaneous in situ extraction and fabrication of surface-enhanced Raman scattering substrate for reliable detection of thiram residue, Analytical Chemistry 2018, 90(22): 13647-13654.[3] Visible-Light-Induced External Radical-Triggered Annulation To Access CF2-Containing Benzoxepine Derivatives, Organic Letters 2018, 20(5): 1363-1366.[4] Unraveling and manipulating the stereospecific retro-aldol reaction in the organocatalytic asymmetric aldol reaction of isatin and cyclohexanone, Organic Letters 2018, 20(23): 7535-7538.[5] 4-Mercaptophenylboronic acid-modified spirally-curved mesoporous silica nanofibers coupled with ultra performance liquid chromatography–mass spectrometry for determination of brassinosteroids in plants, Food Chemistry 2018, 263: 51-58.[6] A magnetic pH-induced textile fabric with switchable wettability for intelligent oil/water separation, Chemical Engineering Journal 2018, 347: 52-63.2017-2015:[1] Synthesis of multi-Au-nanoparticle-embedded mesoporous silica microspheres as self-filtering and reusable substrates for SERS detection, ACS Applied Materials & Interfaces 2017, 9(48): 42156-42166.[2] Discovery of temperature-dependent, autoinductive reversal of enantioselectivity: palladium-mediated [3+ 3]-annulation of 4-hydroxycoumarins, Chemical Communications 2017, 53(32): 4441-4444.[3] Fetal bovine serum influences the stability and bioactivity of resveratrol analogues: A polyphenol-protein interaction approach, Food Chemistry 2017, 219: 321-328.[4] Amide-assisted intramolecular [3+ 2] annulation of cyclopropane ring-opening: a facile and diastereoselective access to the tricyclic core of (±)-scandine, Chemical Communications 2016, 52(10): 2177-2180.[5] Programmable engineering of a biosensing interface with tetrahedral DNA nanostructures for ultrasensitive DNA detection, Angewandte Chemie International Edition 2015, 54(7): 2151-2155. [6] Microbial biotransformation of bioactive flavonoids, Biotechnology Advances 2015, 33(1): 214-223[7] Visible-Light-Driven, Radical-Triggered Tandem Cyclization of o-Hydroxyaryl Enaminones: Facile Access to 3-CF2 /CF3-Containing Chromones, Organic Letters 2016, 19(1): 146-149.[8] Non-covalent interaction between dietary stilbenoids and human serum albumin: Structure–affinity relationship, and its influence on the stability, free radical scavenging activity and cell uptake of stilbenoids, Food Chemistry 2016, 202: 383-388.[9] Type 2 diabetes diminishes the benefits of dietary antioxidants: Evidence from the different free radical scavenging potential, Food Chemistry 2015, 186: 106-112.[10] Separation of polyphenols from leaves of Malus hupehensis (Pamp.) Rehder by off-line two-dimensional high speed counter-current chromatography combined with recycling elution mode, Food Chemistry 2015, 186: 139-145.[11] Separation of five flavonoids from tartary buckwheat (Fagopyrum tataricum (L.) Gaertn) grains via off-line two dimensional high-speed counter-current chromatography, Food Chemistry 2015, 186: 153-159.[12] Macrocyclic β-cyclodextrin derivative-based aqueous-two phase systems: phase behaviors and applications in enantioseparation, Chemical Engineering Science 2016, 143: 1-11. 教育经历 [1]   1986.9-1989.6 中南工业大学  |  分析化学  |  硕士学位  |  硕士研究生毕业 [2]   1982.9-1986.6 中南工业大学  |  冶金化学分析  |  学士学位  |  大学本科毕业 [3]   2003.9-2006.12 中南大学  |  应用化学  |  博士学位  |  博士研究生毕业 工作经历 [1]   2000.3-2001.1 日本东京工业大学  |  客座研究员 [2]   1989.8-至今 中南大学  |  化学化工学院  |  教授  |  在岗 社会兼职 [1]   2017.12-2022.12     湖南省精密仪器测试学会第七届理事会  常务理事 [2]   2017.12-2022.12     湖南省精密仪器测试学会色谱分会 副理事长 研究方向 [1]  生物、环境复杂体系分离分析： a. 新型功能SERS（表面增强拉曼光谱）基底设计与SERS高灵敏现场快速检测；b.基于MOFs/FNA/量子点设计合成功能探针，开发细胞功能分子的原位成像检测方法，实现生物/环境复杂体系中超痕量靶标的分析检测。 [2]  手性对映体识别与分离分析：a. 手性识别模块的设计：基于三点作用原理设计合成手性识别模块，阐述其手性作用原理，构建手性模块功能化纳米材料实现手性分离分析；b. 手性纳米材料：基于手性作用原理刻蚀组装手性纳米材料，并应用于手性光学识别。 [3]  生物、环境与食品安全智能检测 （POCT）：a. 便携智能化检测系统：基于功能化量子点/DNA纳米技术/核酸适体，结合微流控技术，构建基于智能终端的微型便携式食品安全电化学/光学检测系统，实现农残及环境污染物智能髙通量电化学/光学检测。 b. 纸基即时检测：基于功能化纳米材料设计具有微流体通道的纸基微流控芯片，开发纸基芯片的多重（光/电/热）检测装置，实现生物、环境及食品中多靶标纸基即时检测。 团队成员 团队名称：药物合成与分离分析 团队介绍：团队目前有教授6名，副教授1名，讲师1名。在校博士研究生17名，硕士研究生42名。 阳华    蒋新宇    焦飞鹏    施树云    于金刚    向皞月    刘琦