Ph.D. Supervisor and Master's Supervisor
Name: 钟世安
Professional Title: Professor
Administrative Position: 教授/博导
Name (Pinyin): zhongshian
Sex: Male
School/Department: Chemistry and Chemical Engineering
Education Level: PhD Graduate
Date of Employment: 1999-06-01
Degree: Doctoral degree
Alma Mater: 中南大学
Status: Employed
Discipline: Chemical Engineering and Technology
Enrollment Disciplines: Chemical Engineering and Technology、Chemistry

钟世安,男,中共党员,博士(后),中南大学教授,博士生导师,天然产物及药物合成化学团队负责人,“531人才工程”计划资助。早年留学澳大利亚昆士兰大学,一直从事天然药效活性成分的分离与纯化、修饰与改性,现代分离科学与工程,环境科学与工程等方面的教学和科研。先后主持国家自然科学基金4项、国家农业成果转化基金、国家863计划项目、国家科技部科技攻关项目8项,省部级重点计划项目、省自然科学基金5项,各类企业合作项目15项,其中重大横向合作项目4项(经费在200万以上)。在《Analytical Chemistry》、《Chemical Communications》、《Chemical Engineering Journal》、《Journal of Cleaner Production》、《Food chemistry》、《International Journal of Biological Macromolecules》、《ACS Sensors》、《Materials Science and Engineering: C》、《Journal of hazard materials》、《Electrochimica Acta》、等国内外SCI刊物上共发表论文200余篇,现为《Journal of Chromatography A》、《Analytical Chemistry》、《International Journal of Biological Macromolecules》等国际权威刊物审稿专家;教育部科技进步奖评审专家,国家自然科学基金、中国博士后科学基金、教育部博士点基金、新教师基金评审专家。出版教材5本,专著3本,申请国家发明专利50余项,获国家授权专利45余项。先后荣获“广西壮族自治区自然科学奖二等奖”1项、“教育部自然科学进步二等奖”1项,"国家留学归国人员科研启动基金"资助,"中南大学优秀博士后"、"中南大学十佳讲课教师"、"湖南省教学能手"、中南大学”优秀班导师标兵“等多项荣誉称号。招生专业与研究方向:生物与医药(博士生与硕士生)、材料化工(博士生与硕士生)、制药工程(博士生与硕士生)

›湖南益龄时代健康有限公司:富硒灵芝菌丝体的生物合成,硒糖肽的分离纯化及药效活性研究,开始日期:2025-01-01,结项时间:2028-12-30.
›湖南益龄肿瘤科学研究院有限公司:富硒蕈菌菌丝体活性成分的分离纯化、结构表征及药效研究,开始日期:2024-05-13,立项时间:2024-05-13,结项时间:2025-11-07.
›国家自然科学基金委:抗原蛋白-分子印迹荧光可视化载体体系的精准构筑及其分离机制研究(22278445),zhongshian,立项时间:2022-09-30,结项时间:2026-12-31.
›广西中医药大学:广西中医药大学-中南大学壮瑶药研究联合实验室建设(桂科计字【2021】238),zhongshian,开始日期:2022-01-01,结项时间:2024-12-31.
›国家自然科学基金委:国家自然科学基金:磁性埃洛石纳米管聚合体系的组装及对外循环肿瘤细胞的吸附与分离研究,立项代码:21576295(国家自然科学基金:21576295),钟世安,立项时间:2016-01-01
›国家自然科学基金委:国家自然科学基金:刺激-响应性分子印迹复合微球的组装及其可控吸附与释放性能研究,立项代码:21276283(国家自然科学基金:21276283),钟世安,立项时间:2013-01-01
›企业重大横向项目:企业重大横向项目:树舌、云芝活性成分的分离纯化及药效研究,研究经费:220万元,立项时间:2020-10-01
›国家科技部:科技部科技攻关计划项目:分子印迹技术分离纯化藤茶中活性成分的研究,项目立项号:13C26214304134(13C26214304134),钟世安,立项时间:2014-01-01
›教育部:教育部留学归国人员基金项目:可降解人工骨骼材料的设计与制备,钟世安,立项时间:2012-01-01
›企业重大横向项目:企业重大横向项目:富硒覃菌菌粉活性成分分离纯化、结构表征及抗肿瘤活性研究,研究经费:120万元,立项时间:2017-10-01
›企业重大横向项目:有机硒食用菌粉活性成分对抗肝癌等7种肿瘤的动物实验研究,研究经费:120万元,立项时间:2018-10-01
›省自然科学基金项目:基于MOF核壳结构智能抗癌药物递送系统的构建及其药效性能研究,立项号:2020JJ4686
›2018年湖南省普通高校教学改革研究项目:(湘教通[2018]436号),有机化学”开放式精品示范课程建设与实践
›企业产业化项目:金丝桃素的制备方法,钟世安
›企业产业化项目:益生元黑茶的研发及产业化研究

›Synergistic self-assembly of a Cau/Fe-MIL/polydopamine composite membrane for multifunctional hemodialysis[J].JOURNAL OF MEMBRANE SCIENCE, 2026, 754: 125653.
›Intramolecular Proximity-Induced Amplification for Accurate Imaging of Glycosylated RNAs in Living Cells and Zebrafish[J].ANALYTICAL CHEMISTRY, 2025, 97 (38) : 20897-20907.
›PVP-mediated Zr-melamine-MOF/PVDF membranes for efficient uremic toxin removal and anti-fouling[J].COLLOIDS AND SURFACES B-BIOINTERFACES, 2026
›In Situ imaging of cell surface RNAs during inflammation in zebrafish models using near-infrared fluorescent DNA probe[J].SENSORS AND ACTUATORS B-CHEMICAL, 2026, 457: 139738.
›Electrically driven single-atom Mo enhances support effect for efficient PMS activation to degrade high-concentration sulfanilamide.Chemical Engineering Journal,521, 2025, 166845, 2025, 521
›Separation, purification, structure characterization, and immune activity of a polysaccharide from Alocasia cucullata obtained by freeze-thaw treatment.International Journal of Biological Macromolecules Volume 282, Part 6, December 2024, 137232
›Isolation, purification, structural characterization, and antitumor activity of Gynura divaricata polysaccharides[J].INTERNATIONAL JOURNAL OF BIOLOGICAL MACROMOLECULES,2025,290,138928
›Physicochemical characterization and antitumor activity in vitro of a polysaccharide from Christia vespertilionis.INTERNATIONAL JOURNAL OF BIOLOGICAL MACROMOLECULES,2025,290,139095, 2025
›Extraction, purification, structural characterization, and anti-inflammatory activity of a polysaccharide from Lespedeza formosa.INTERNATIONAL JOURNAL OF BIOLOGICAL MACROMOLECULES,2025,300:140154, 2025
›Isolation, characterization, and activity of the polysaccharides in Bulbophyllum kwangtumgense Schltr[J].INTERNATIONAL JOURNAL OF BIOLOGICAL MACROMOLECULES,2024,283:137382, 2024, 283 (2) : 137382.
›ReSeparation, purification, structure characterization, and immune activity of a polysaccharide from Alocasia cucullata obtained by freeze-thaw treatment[J].INTERNATIONAL JOURNAL OF BIOLOGICAL MACROMOLECULES, 2024, 282 (6) : 137232.
›Efficient degradation of norfloxacin by synergistic activation of PMS with a three-dimensional electrocatalytic system based on Cu-MOF[J].Separation and Purification Technology,Volume 356, Part B , 1 April 2025, 129945, 2024
›Construction of a dual colorimetric fluorescent imprinting polymer hybrid system for the detection of alpha-fetoprotein based on the multi-FRET effect and modeling of its color response mechanism[J].Sensors and Actuators: B. Chemical,Reference: SNB_136264, 2024
›A one-pot isothermal Fluorogenic Mango II arrays-based assay for label-free detection of miRNA[J].Talanta,Volume 281 , 1 January 2025, 126920
›Sensitive Detection of Escherichia coli O157:H7 Using Allosteric Probe and Hairpin Switches-Based Isothermal Transcription Amplification[J].Analytical Chemistry,DOI: 10.1021/acs.analchem.4c02413, 2024
›A label-free strategy for direct detection of Staphylococcus aureus in complex matrixes based on RCA and aptamer.Sensors and Actuators: B. Chemical, SNB-D-24-05318, 2024
›Construction of fluorescence-sensing molecularly imprinted membranes based on hydrophilic-hydrophobic multifunctional monomers for the detection of LPS molecules.Sensors and Actuators: B. Chemical, SNB-D-24-04343, 2024
›Electro-assisted activation of peroxymonosulfate in the presence of chloride ion for degradation of sulfamethoxazole.JOURNAL OF CLEANER PRODUCTION, 2023, 405 (15) : 136914.
›Structural characterization and anti-inflammatory activities of a purified polysaccharide from fruits remnants of Alpinia zerumbet (Pers.) Burtt. et Smith.International Journal of Biological Macromolecules, 2024: BIOMAC_131534.
›Mobile phone-assisted imprinted nanozyme for bicolor colorimetric visual detection of erythromycin in river water and milk samples[J].Food Chemistry, 2024, 449 (15) : 139291.
›Chemical Composition and Potential Antimicrobial and Anti-Inflammatory Activities of Essential Oil from Fruits of Alpinia zerumbet (Pers.) BLBurtt & RMSm.[J].CHEMISTRY & BIODIVERSITY, 2023, 20 (12) : 1-9.
›Fluorophore Label-Free Light-up Near Infrared Deoxyribonucleic Acid Nanosensor for Monitoring Extracellular Potassium Levels.ANALYTICAL CHEMISTRY, 2024, 96 (10) : 4023-4030.
›Waste tailing particle electrode enables enhanced electrochemical degradation of sulfamethoxazole.Environmental Science: Nano, 2023
›Hairpin Switches-Based Isothermal Transcription Amplification for Simple, Sensitivity Detection of MicroRNA.Analytical Chemistry, 2023, 95 (37) : 13872–13879.
›A smartphone-assisted one-step bicolor colorimetric detection of glucose in neutral environment based on molecularly imprinted polymer nanozymes.Talanta, 2023, TAL_125256
›CRISPR-Cas12a coupled with cyclic reverse transcription for amplified detection of miRNA.CHEMICAL COMMUNICATIONS, 59 (50) : 7763-7766.
›Nanoflare Couple: Multiplexed mRNA Imaging and Logic-Controlled Combinational Therapy.Anal. Chem., 2022 (94) : 12204-12212.
›Waste coal cinder catalyst enhanced electrocatalytic oxidation and persulfate advanced oxidation for the degradation of sulfadiazine.Chemosphere,2022,CHEM102480, 2022
›Fabrication, GSH-responsive drug release, and anticancer properties of thioctic acid-based intelligent hydrogels.Colloids and Surfaces B: Biointerfaces, 2022, 217: 112703.
›Peroxymonosulfate Activation by Bimetallic Modified Syderolite Pellets Catalyst for Degradation of Bromobenzenitrile.Process Safety and Environmental Protection, 2022, 165: 505-513.
›The Main Structural Unit Elucidation and Immunomodulatory Activity In Vitro of a Selenium-Enriched Polysaccharide Produced by Pleurotus ostreatus.molecules, 2022, 27 (8) : 2591.
›Structural characterization and anticancer activity of a polysaccharide from Coriolus versicolor.New Journal of Chemistry, 2022, DOI: 10.1039/D2NJ00897A
›Design of a CRISPR/Cas12a and Au-nanobeacons Based Diagnostic Biosensor Enabling Direct, Rapid, and Sensitive miRNA Detection.Analytical Chemistry,ac-2022-00401d.R1, 2022
›Bimetallic modified halloysite particle electrode enhanced electrocatalytic oxidation for the degradation of sulfanilamide.Journal of Environmental Management, 2022, 312 (15) : 1.
›High-efficient degradation of sulfamethazine by electro-enhanced peroxymonosulfate activation with Bimetallic modified Mud sphere catalyst.Separation and Purification Technology, 2022, 292: 12097.
›A natural selenium polysaccharide from Pleurotus ostreatus: structural elucidation, anti-gastric cancer and anti-colon cancer activity in vitro.International Journal of Biological Macromolecules, 2021, 203: 630-640.
›Cell-Surface-Anchored DNA sensors for simultaneously monitoring extracellular Sodium and potassium levels.Analytical Chemistry, 2021, 93: 16432-16438.
›Structural characterization and anti-tumor activity in vitro of a water-soluble polysaccharide from dark brick tea.International Journal of Biological Macromolecules, 2022, 205: 615-625.
›Discovery of the Rnase activity of CRISPR–Cas12a and its distinguishing cleavage efficiency on various substrates.chemical communication, 2022, 58 (15) : 2540-2543.
›Quantum dot based molecularly imprinted polymer test strips for fluorescence detection of ferritin.Chemical,Sensors and Actuators B: Chemical, 2022, 358: 1315.
›A critical review of molecularly imprinted solid phase extraction technology.Journal of Polymer Research, 2021, 28: 401.
›Capsule-like molecular imprinted polymer nanoparticles for targeted and chemophotothermal synergistic cancer therapy.Colloids and Surfaces B: Biointerfaces, 2021, 208: 112126.
›The degradation of sulfamilamide wastewater by three-dimensional electrocatalytic oxidation system composed of activated carbon bimetallic particle electrode.Journal of Cleaner Production, 2021, 324: 129256.
›Current methods and prospects of coronavirus detection.Talanta, 225: 121977..
›An Intelligent Nanoprobe: Acid-Responsive Drug Release and In Situ Evaluating Its Own Therapeutic Effect,Analytical. Chem. 2022, acs.analchem.2c00401[J], 2020
›A water-soluble selenium-enriched polysaccharide produced by Pleurotus ostreatus: Purification, characterization, antioxidant and antitumor activities in vitro.International Journal of Biological Macromolecules, 2020, 168 (31) : 356-370.
›Dually acid- and GSH-triggered bis(β-cyclodextrin) as drugs delivery nanoplatform for e?ective anticancer monotherapy[.Nanotechnology, 2020, 32: 145714.
›Physicochemical characterization and antitumor activity in vitro of a selenium polysaccharide from Pleurotus ostreatus,International Journal of Biological Macromolecules,2020, IJBIOMAC-D-20-04560R2
›An Autonomous Self-Cleavage DNAzyme Walker for Live Cell MicroRNA Imaging, ACS Applied Bio Materials,2020,ID:10.1021/acsabm.0c00777, 2020
›A nanoprobe for ratiometric imaging of Glutathione in living cells based on the use of a nanocomposite prepared from dual-emission carbon dots and manganese dioxide nanosheets,Microchimica Acta, 2020, MIAC-D-19-01939R1, 2020, MIAC-D-19
›PEGylated Thermo-Sensitive Bionic Magnetic Core-Shell Structure Molecularly Imprinted Polymers Based on Halloysite Nanotubes for Specific Adsorption and Separation of Bovine Serum Albumin, polymers, 2020,12(3):10.3390/polym12030536
›Preparation and characterization of molecularly imprinted polymers based on β-cyclodextrin stabilized Pickering emulsion polymerization for selective recognition of erythromycin from river water and milk, Journal of Separation Science,2020, JSSC jssc201901255
›GSH and Light Dual Stimuli-Responsive Supramolecular Polymer Drug Carriers for Cancer Therapy[J], Polymer Degradation and Stability,2019,PDST-D-19-00541R1
›Co-delivery of DNAzyme and chemotherapy drug using DNA tetrahedron for enhanced anticancer therapy through synergistic effects [J],New Journal of Chemistry, 2019, DOI: 10.1039/C9NJ02818H
›Micelles via self-assembly of amphiphilic beta-cyclodextrin block copolymers as drug carrier for cancer therapy[J],Colloids and Surfaces B: Biointerfaces,2019,DOI: 10.1016/j.colsurfb.2019.110425
›Cell-surface-anchored ratiometric DNA nanoswitch for extracellular ATP imaging[J], ACS Sensors,2019, 4, 1648-1653
›β-cyclodextrin Coated and Folic Acid Conjugated Magnetic Halloysite Nanotubes for Targeting and Isolating of Cancer Cells[J], Colloids and Surfaces B: Biointerfaces,2019, 181, 379-388
›Amphipathic β-cyclodextrin nanocarriers serve as intelligent delivery platform for anticancer drug[J], Colloids and Surfaces B: Biointerfaces, 2019,180: 429-440
›Molecularly imprinted polymers based on zeolite imidazolate framework-8 for selective removal of 2,4-dichlorophenoxyacetic acid[J]. Colloids and Surfaces A-physicochemical and engineering aspects, 2019, 570 :244–250
›Polymethacrylic acid encapsulated TiO2 nanotubes for sustained drug release and enhanced antibacterial activities[J]. New J. Chem. 2019,43?:1827-1837
›An improved synthesis of the 5?HT1A receptor agonist Eptapirone free base[J]. Chemical Papers, 2019, 73:1321-1331
›Assembling of stimuli-responsive tumor targeting polypyrrole nanotubes drug carrier system for controlled release[J]. Materials Science and Engineering: C , 2018, 89: 316~327
›Molecularly imprinted polymers fabricated using Janus particle-stabilized Pickering emulsions and charged monomer polymerization[J]. New J. Chem., 2018, 42, 7355
›Novel application of amphiphilic block copolymers in Pickering emulsions and selective recognition of proteins[J]. New J. Chem., 2018, 42:3028-3034
›Molecularly imprinted polymers fabricated via Pickering emulsions stabilized solely by food-grade casein colloidal nanoparticles for selective protein recognition [J]. Analytical and Bioanalytical Chemistry, 2018, 410:3133–3143
›An effective and convenient synthesis of cordycepin from adenosine[J].Chemical Papers, 2017
›Synthesis of Size-tunable Hollow Polypyrrole Nanostructures and Their Assembly into Folate Targeting and pH-responsive Anti-cancer Drug Delivery[J].Chemistry - A European Journal, 2017, 68: 17279-17289.
›A Pt/TiO2 Nanotube Array Electrode for Glucose Detection and Its Photoelectrocatalysis Self-Cleaning Ability.J. Electrochem. Soc
›Multifunctional Halloysite Nanotubes for Targeted Delivery and Controlled Release of Doxorubicin In-Vitro and In-Vivo Studies [J]. Nanotechnology, 2017, 28: 37-42
›Nanoscale trifunctional bovine hemoglobin for fabricating molecularly imprinted polydopamine via Pickering emulsions-hydrogels polymerization [J]. Colloids and Surfaces B: Biointerfaces, 2017, 159C: 131-138
›Hydrophilic surface molecularly imprinted naringin prepared via reverse atom transfer radical polymerization with excellent recognition ability in a pure aqueous phase [J]. RSC Advances, 2017, 7(45): 28082-28091
›Interconnectivity of macroporous molecularly imprinted polymers fabricated by hydroxyapatite-stabilized Pickering High internal phase emulsions-hydrogels for the selective recognition of protein [J]. Colloids and Surfaces B: Biointerfaces, 2017, 155: 142-149
›Combination of adsorption by functionalized halloysite nanotubes and encapsulation by polyelectrolyte coatings for sustained drug delivery [J]. RSC Advances, 2016, 6(59): 54463-54470
›The synthesis of temperature-sensitive molecularly imprinted film on novel support beads and its application for bovine serum albumin separation [J]. Colloids and Surfaces A, 2016, 504: 367-375
›Bio-inspired magnetic molecularly imprinted polymers based on Pickering emulsions for selective protein recognition [J]. New J. Chem,2016, 40(10): 8745-8752
›Halloysite-based dopamine-imprinted polymer for selective protein capture [J]. Journal of Separation Science, 2016, 39(12): 2431-2437
›Graphene oxide as a sacrificial material for fabricating molecularly imprinted polymers via Pickering emulsion polymerization [J]. RSC Advances, 2016, 6(78): 74654-74661[J]
›Functionalization of halloysite nanotubes by enlargement and hydrophobicity for sustained release of analgesic [J]. Colloids and Surfaces A, 2015, 487: 154-16, 2015
›Fabrication and evaluation of protein imprinted polymer based on magnetic halloysite nanotubes [J]. RSC Advances, 2015, (5): 61-68
›One-step synthesis of boronic acid group modified silica particles by the aid of epoxy silanes [J]. Applied Surface Science, 2015, 351: 353–357
›Water-compatible halloysite-imprinted polymer by Pickering emulsion polymerization for the selective recognition of herbicides [J]. Journal of Separation Science, 2015, 38: 1365
›One-pot preparation of boronic acid and PEG bi-functionalized silica particles for separation and purification of catecholamine from rat serum [J]. New Journal of Chemistry, 2015, 39: 8848-8854
›A novel molecularly imprinted materials based on magnetic halloysite nanotubes for rapid enrichment 2, 4- dichlorophenoxyacetic acid in water [J]. Journal of hazardous materials, 2014, 276: 58-65
›A novel self-cleaning, non-enzymatic glucose sensor working under a very low applied potential based on a Pt nanoparticle-decorated TiO2 nanotube array electrode [J]. Electrochimica Acta,, 2014, 115: 269-276
›Efficient conversion of myricetin from Ampelopsis grossedentata extracts and its purification by MIP- SPE [J]. Journal of Chromatography B, 2014, 945-946: 39-45
›Preparation and characterization of molecularly imprinted organic–inorganic hybrid materials by sol–gel processing for selective recognition of ibuprofen [J]. Journal of sol-gel science and technology, 2013, 66(1): 59–67
›Silica particles coated with azobenzene-containing photoresponsive molecule-imprinted skin layer [J]. Colloid and Polymer Science, 2013, 291(9): 92049–2059
›Synthesis of novel photoresponsive molecularly imprinted polymer microspheres with special binding properties [J]. Journal of Applied Polymer Science, 2013, 130(15): 869-876
›30.Design and computational simulation of stimuli-responsive polymer by sol-gel for selective recognition of (4-chloro-2-methylphenoxy)acetic acid [J]. Polymer international, 2012, 61: 1778–1785
›Dendritic polymers based on poly(ethylene glycol)-co-poly(glycolic acid)-co-methacrylate and 2.0 G-polyamidoamine- metharylamide: Design, Characterization, and in vitro degradation, and drug release properties [J]. Polymer Degradationand Stability, 2012, 97: 234-241
›Synthesis of molecularly imprinted organic-inorganic hybrid azobenzene materials by sol gels for radiation induced selective recognition of 2,4-Dichlorophenoxy- acetic acid [J]. Radiation Physical Chemistry, 2011, 80(2): 130-135
›Computer Simulation and Preparation of Molecularly Imprinted Polymer Membranes with Chlorogenic Acid as Template [J]. Polymer international, 2011, 60: 592-598

›多糖活性成分及其制备和在制备免疫调节药物中的应用. 申请日期:2024-03-21, 申请号:2024103259399
›检测甲胎蛋白的混合型双比色印迹聚合物材料及其制备方法和应用. 申请日期:2024-08-01, 申请号:2024105810884
›含硒多糖及其制备和在制备免疫调节药物中的应用, 申请号:2022102898432, 授权号:ZL2022102898432.
›一种抗癌活性多糖及其制备和在制备抗癌药物中的应用, 申请号:2022105005171, 授权号:ZL2022105005171.
›平菇多糖硒苷-Ⅱ及其制备和在制备特异性杀伤非小肺腺癌的药物中的应用, 申请号:2019110968219, 授权号:ZL2019110968219.
›一种平菇多糖硒苷-Ⅲ抗癌活性成分及其制备和在制备抗肝癌药物中的应用, 申请号:2019110957214, 授权号:ZL2019110957214.
›一种治疗宫颈癌的药物及其制备, 申请号:2019110957799, 授权号:ZL2019110957799.
›一种平菇多糖硒苷-Ⅲ在制备治疗卵巢癌的药物中的应用, 申请号:2019110968153, 授权号:ZL2019110968153.
›一种平菇多糖硒苷-Ⅲ抗癌活性成分在制备抗结肠癌的药物中的应用. 申请日期:2020-10-01, 申请号:2020100980113, 授权日期:2023-05-01, 授权号:ZL2020100980113.
›一种平菇多糖硒苷-Ⅲ抗癌活性成分在用于制备抗乳腺癌的药物中的应用. 申请日期:2020-10-09, 申请号:2020100960105, 授权日期:2023-05-01, 授权号:ZL2020100960105.
›一种平菇多糖硒苷-Ⅲ抗癌活性成分在用于制备抗胃癌的药物中的应用, 申请号:2020100961362, 授权日期:2023-05-01, 授权号:ZL2020100961362.
›一种平菇多糖硒苷-Ⅲ抗癌活性成分在制备抗前列腺癌的药物中的应用. 申请日期:2020-10-01, 授权号:ZL2020100979775.
›一种黑茶多糖-Ⅰ活性成分及其制备方法和在抗癌中应用,授权号ZL2021109558526. 申请日期:2021-08-19, 申请号:2021109558526, 授权日期:2022-02-14, 授权号:ZL2021109558526.
›一种红细胞膜包裹的磁性纳米颗粒及其制备方法和应用,授权号ZL202110770716X. 申请日期:2021-10-11, 申请号:202110770716X, 授权日期:2022-02-14, 授权号:ZL202110770716X.
›一种抗吸潮的减肥黑茶固体饮料及制备方法,授权号2018111994930. 申请日期:2018-11-01, 申请号:2018111994930, 授权日期:2022-02-14, 授权号:ZL2018111994930.
›一种光和氧化还原双重刺激响应型两亲性聚合物药物载体及其制备方法和应用, 授权号:ZL2019100528208, 授权日期:2020-09-22, 授权号:ZL2019100528208.
›基于氧化石墨烯牺牲材料制备表面分子印迹微球的方法及应用,钟世安. 申请日期:2014-04-13, 申请号:201610228706.2, 授权号:ZL 201610228706.2.
›一种核壳结构的温敏性磁性蛋白质印迹微球的制备方法及应用,授权号:ZL201510193366.X,钟世安. 申请日期:2015-04-25, 申请号:ZL 201510193366.X
›一种光智能化硅胶表面分子印迹微球及其制备方法,授权号:ZL201210505221.5,钟世安. 申请日期:2012-08-01, 申请号:201210505221.5, 授权号:ZL201210505221.5.
›一种埃洛石纳米管药物缓释材料及其制备方法,授权号:ZL201510061065.1,钟世安. 申请日期:2015-02-05, 申请号:201510061065.1, 授权号:ZL 201510061065.1.
›一种刺激响应型聚吡咯纳米管靶向药物载体及制备方法,授权号:201510974522.6,钟世安. 申请日期:2015-12-13, 申请号:ZL 201510974522.6
›玉竹的深加工及综合利用工艺,授权号:ZL201110414997.1,钟世安. 申请日期:2011-11-01, 申请号:201110414997.1, 授权日期:2013-09-01, 授权号:ZL专利201110414997.1.
›用藤茶制备杨梅素的方法和焦亚硫酸盐的应用,授权号:ZL201310189757.5,钟世安. 申请日期:2013-02-01, 申请号:201310189757.5, 授权日期:2015-02-01, 授权号:ZL201310189757.5.
›金丝桃素的合成方法,授权号:ZL201410380705.0,钟世安. 申请日期:2014-06-10, 申请号:201410380705.0, 授权日期:2015-12-05, 授权号:ZL201410380705.0.
›制备对2,4-二氯苯氧乙酸具有特异性吸附的磁性埃洛石分子印迹聚合物的方法,授权号:ZL201310624108.3,钟世安, 申请号:201310624108.3, 授权日期:2015-08-18, 授权号:ZL201310624108.3.
›一种泡腾片的制备方法,授权号:ZL201610381965.9,钟世安. 申请日期:2016-02-01, 申请号:201610068781.7, 授权日期:2018-05-03, 授权号:ZL 201610068781.7.
›基于疏水羟基磷灰石纳米稳定粒子的皮克林乳液聚合制备表面分子印迹微球的方法及应用,钟世安. 申请日期:2016-12-12, 申请号:2016111297542, 授权号:ZL2016111297542.
›一种2’-脱氧腺苷的合成方法. 申请日期:2016-06-01, 申请号:201610381965.9, 授权号:ZL201610381965.9.
›一种埃洛石纳米管药物载体及埃洛石纳米管载体药物的制备方法,授权号:ZL2017101991132,胡雨薇, 钟世安. 申请日期:2017-04-05, 申请号:2017101991132, 授权日期:2017-07-10, 授权号:ZL2017101991132.
›一种益生元添加剂及其制备方法和应用. 申请日期:2017-11-02, 申请号:2017110382082
›柚类青果、次果、果皮综合利用的加工工艺,授权号:ZL200710035811,钟世安, 授权日期:2009-09-07, 授权号:ZL专利200710035811.5.
›一种山苍籽核仁深加工及综合利用工艺,授权号:ZL200810031868,钟世安, 授权日期:2010-11-07, 授权号:ZL专利200810031868.2.
›一种刺激响应型两亲性环糊精聚合物载体、制备及其在制备缓控释药物中的应用, 授权号: ZL201810304175X. 申请日期:2018-04-08, 申请号:201810304175X, 授权日期:2020-09-23, 授权号:ZL201810304175X.
›柑橘类果皮中果胶的提取与制备工艺,授权号:ZL200510032091,钟世安, 授权日期:2009-03-07, 授权号:ZL专利 200510032091.8.
›依他匹隆的全合成方法. 申请日期:2018-04-08, 申请号:2018102955299
›一种免洗益生元黑茶及其制备方法. 申请日期:2018-04-10, 申请号:2018103097295
›薯蓣中分离提取薯蓣皂素、淀粉纤维素和黄色素的工艺,授权号:ZL 200610031158.0,钟世安, 授权日期:2009-01-14, 授权号:ZL专利200610031158.0.

›高等学校科学研究优秀成果奖
›豪鹏优秀教师奖
›广西壮族自治区自然科学二等奖
›西南铝业教育奖励-优秀教师奖(2011年)|2009,钟世安
›东富龙杯全国大学生制药工程设计大赛|2013,指导教师:钟世安
›国药杯全国大学生制药工程设计大赛|2015,指导教师:钟世安
›比亚迪教育奖励-优秀教师奖(2015年)|2015,钟世安
›优秀班导师标兵(2017年)|2017
›世纪翱翔教育奖励-优秀教师奖(2018年)
›中南大学第四届中青年教师教学比武“十佳讲课”教师(2007年)
›“湖南省教学能手”称号(2009年)
›中南大学教育质量优秀奖(2005-2006年度,2006-2007年度,2007-2008年度,2008-2009年度,2010-2011年度,2011-2012年度)

›1《壮药材质量标准研究与应用》,省部级科技成果奖,教育部自然科学奖二等奖,证书编号:2022-552-D03,2023-05-01
›2《壮药药材学创建于质量标准研究》,省部级科技成果奖,广西省自然科学奖二等奖,证书编号:2020-Z-07-D02,2020-12-31
›3 中南大学第四届中青年教师教学比武“十佳讲课”教师,2007-09-30
›4“湖南省教学能手”,2008-09-30

Major : 应用化学
Master's degreeMajor : 应用化学
Doctoral degreeMajor : 材料科学与工程

中南大学 › 化学化工学院 › 工会常务副主席 › 教授,博士生导师 › 教学、科研
中南大学 › 化学化工学院 › 制药系党支部书记 › 教授 › 教学、科研
澳大利亚昆士兰大学 › 澳大利亚生物工程与纳米技术国家实验室 › 研究员 › 科研
中南大学 › 化学化工学院 › 副所长 › 副教授 › 教学、科研
中南工业大学 › 化学系 › 讲师 › 教学、科研

湖南省食品与药品监督管理局化妆品与食品监督咨询专家
中南大学本科教学质量督导委员会建设组专家

›2018年中南大学教育教学改革研究项目(2018jy051), “有机化学”开放式精品示范课程建设与实践
›2014年中南大学教学改革研究项目(中大教字[2014]32号):化学化工类有机化学课程考试改革的研究与实践
›2015年中南大学开放式精品示范课堂计划立项(中大教字[2015]51号),制药工程类“有机化学”开放式精品示范课程建设
›2018年湖南省普通高校教学改革研究项目:(湘教通[2018]436号),有机化学”开放式精品示范课程建设与实践
›化学化工类有机化学课程考试改革的研究与实践[J], 大学化学,2017, 32(7): 25-31
›“有机化学”开放式精品示范课程建设与实践[J],化学教育,2018,39(22):11-15
›湖南省教学能手,2009-06-11
›中南大学第四届中青年教师教学比武“十佳讲课”教师,2007-10-06