个人简介
1998年获江苏石油化工学院热能工程专业学士学位、2003获中国科学院广州能源研究所热能工程专业硕士学位、2006获中国科学技术大学工程热物理专业博士学位;2006-至今华南师范大学任职,主要从事微流控光学传感器及其生物医学应用的研究;主持国家/省市项目6项;在国际权威期刊如Chemical Reviews (IF 52.613)、Biosensors and Bioelectronics (IF 8.173)、Lab on a Chip (IF 5.995)等发表SCI收录论文40多篇;获省部奖项3项;获授权发明专利9项;
学习经历
2003.9-2006.6 中国科学技术大学 工程热物理专业 博士
2000.9-2003.6 中国科学院广州能源研究所 热能工程专业 硕士
1994.9-1998.6 江苏石油化工学院 能源工程专业 学士
工作经历
2012.1-至今 华南师范大学激光生命科学教育部重点实验室研究员
2007.12-2011.12 华南师范大学激光生命科学教育部重点实验室 副研究员
2006.7-2007.11 华南师范大学激光生命科学教育部重点实验室 讲师
1998.7-2000.8 江苏省涟水县高级职业中学 物理教师[1] Cuiling Liu, Dan
专利情况
[1] 章春笋, 吴培京. 一种基于紫外光刻技术的布基微流控芯片制备方法. 发明专利号: ZL 2014 1 0339906.6(授权公告日2015年08月19日).
[2] 章春笋, 刘敏. 一种布基微流控分析芯片的蜡网印加工方法. 发明专利号: ZL 2014 1 0487022.5(授权公告日2015年12月30日).
[3] 章春笋, 刘菲菲. 一种纸基微流控芯片增强型化学发光基因传感方法. 发明专利号: ZL 2014 1 0259179.2(授权公告日2016年03月30日).
[4] 章春笋, 张鹏. PDA 修饰的纸基微流控芯片及其在 DNA 比色检测中的应用.发明专利号: ZL 2015 1 0047078.3(授权公告日2016年04月27日).
[5] 章春笋, 邢达, 舒博文. 手持式 POCT 流式基因分析系统. 发明专利号: ZL 2015 1 0140830.9(授权公告日2016年05月11日).
[6] 章春笋, 刘瑞. 双性电极电致化学发光纸基微流控芯片及其成像传感应用. 发明专利号: ZL 2014 1 0494915.2(授权公告日2016年07月06日).
[7] 章春笋, 管文荣, 刘敏. 三碳电极电致化学发光布基微流控芯片及其制法和用途. 发明专利号: ZL 2015 1 0387790.8(授权公告日2016年08月24日).
[8] 章春笋, 刘瑞. 一种布芯片重力/毛细流动化学发光方法. 发明专利号: ZL 201510868060.X(授权公告日2017年11月24日).
[9] 章春笋, 邢达, 舒博文. 智能手机宽场荧光成像器. 实用新型专利号: ZL 2015 2 0180632.0(授权公告日2015年07月01日).
[10] 章春笋, 邢达, 舒博文. 热梯度微反应器. 实用新型专利号: ZL 20152 0179811.2(授权公告日2015年07月22日).
[11] 章春笋, 张鹏. 一种纸芯片重力/毛细流动化学发光方法. 发明专利申请号: 201510861233.5(申请日期2015年11月30日).
[12] 章春笋, 陈路. 手持式 POCT双性电极-电化学发光装置及其应用. 发明专利申请号: 201610344999.0(申请日期2016年5月20日).
[13] 章春笋, 刘敏. 一种闭合式双性电极电致化学发光布芯片及其制法和用途. 发明专利申请号: 201610390590.2(申请日期2016年6月1日).
[14] 章春笋, 刘瑞. 毛细微通道辅助线基微流控双性电极电化学发光装置及应用. 发明专利申请号: 201610703422.4(申请日期2016年8月22日).
[15] 章春笋, 刘敏.开放式U形双性电极电致化学发光布芯片及其制法和用途. 发明专利申请号: 201610753106.8(申请日期2016年8月29日).
[16] 章春笋, 李慧杰. 含蜡坝的重力/毛细流布芯片及其在葡萄糖传感中的应用. 发明专利申请号: 201610960195.3(申请日期2016年10月28日).
[17] 章春笋,刘翠玲, 一种闭合式多元双性电极电化学发光芯片及其应用.发明专利申请号: 201810127422.3(申请日期2018年2月8日).
获奖
[1] 2013年,“新型生物传感技术在功能分子检测和成像中的应用基础研究”获教育部高等学校科学研究优秀成果奖( 科学技术)二等奖 【第二完成人】
[2] 2010年,“光学与生命科学交叉科学中的前沿问题与关键技术研究”获广东省自然科学二等奖 【第四完成人】
[3] 2005年,“微尺度能量传递原理的基础研究”获广东省自然科学三等奖【第四完成人】
近期论文
查看导师最新文章
(温馨提示:请注意重名现象,建议点开原文通过作者单位确认)
[1] Cuiling Liu, Dan Wang, Chunsun Zhang*. A novel paperfluidic closed bipolarelectrode-electrochemiluminescence sensing platform: Potential formultiplex detection at crossing-channel closed bipolar electrodes. Sensors and Actuators B, 2018, 270, 341-352. (IF 5.667; 工程技术一区)
[2] Dan Wang, Cuiling Liu, Yi Liang, Yan Su, Qiuping Shang, Chunsun Zhang*. A simple and sensitive paper-based bipolar electrochemiluminescence biosensor for detection of oxidase-substrate biomarkers in serum. Journal of The Electrochemical Society, 2018, 165, B361-B369. (IF 3.662; 材料科学:膜一区)
[3] Huijie Li, Cuiling Liu, Dan Wang, Chunsun Zhang*. Programmable fluid transport on photolithographicallymicropatterned cloth devices: Towards the development of facile, multifunctional colorimetric diagnostic platforms. Sensors and Actuators B, 2018, 255: 2416-2430. (IF 5.667; 工程技术一区)
[4] Bowen Shu, Chunsun Zhang*, Da Xing*. A sample-to-answer, real-time convective polymerase chain reaction system for point-of-care diagnostics. Biosensors and Bioelectronics, 2017, 97: 360-368. (IF 8.173; 工程技术一区)
[5] Huijie Li, Cuiling Liu, Dan Wang, Chunsun Zhang*. Chemiluminescence cloth-based glucose test sensors (CCGTSs): a new class of chemiluminescence glucose sensors. Biosensors and Bioelectronics, 2017, 91: 268-275. (IF 8.173; 工程技术一区)
[6] Rui Liu, Cuiling Liu, Huijie, Min Liu, Dan Wang, Chunsun Zhang*. Bipolar electrochemiluminescence on thread: A new class of electroanalytical sensors. Biosensors and Bioelectronics, 2017, 94: 335-343. (IF 8.173; 工程技术一区)
[7] Min Liu, Dan Wang, Cuiling Liu, Rui Liu, Huijie Li, Chunsun Zhang*. Battery-triggered open wireless electrochemiluminescence in amicrofluidic cloth-based bipolar device. Sensors and Actuators B, 2017, 246: 327-335.(IF 5.667; 工程技术一区)
[8]Yong Yao, Huijie Li, Dan Wang, Cuiling Liu, Chunsun Zhang*.An electrochemiluminescence cloth-based biosensor with smartphone-based imaging for detection of lactate in saliva. Analyst, 2017, 142: 3715-3724.(IF 3.864; 化学二区)
[9] Huijie Li, Dan Wang, Cuiling Liu, Rui Liu, Chunsun Zhang*. Facile and sensitive chemiluminescence detection of H2O2 and glucose by a gravity/capillary flow and cloth-based low-cost platform. RSC Advances, 2017, 7: 43245-43254.(IF 2.936; 化学二区)
[10] Wenrong Guan, Min Liu, Chunsun Zhang*. Electrochemiluminescence detection in microfluidic cloth-based analytical devices. Biosensors and Bioelectronics, 2016, 75: 247-253 (IF 8.173; 工程技术一区)
[11] Min Liu, Rui Liu, Dan Wang, Cuiling Liu, Chunsun Zhang*. A low-cost, ultraflexible cloth-based microfluidic device for wireless electrochemiluminescence application. Lab on a Chip, 2016, 16(15): 2860-2870.(IF 5.995; 工程技术一区)
[12] Rui Liu, Peng Zhang, Huijie Li, Chunsun Zhang*. Lab-on-cloth integrated with gravity/capillary flow chemiluminescence (GCF-CL): towards simple, inexpensive, portable, flow system for measuring trivalent chromium in water. Sensors and Actuators B, 2016, 236: 35-43.(IF 5.667; 工程技术一区)
[13] Peng Zhang, Chunsun Zhang*, Bowen Shu. Micropatterned paper devices using amine-terminated polydiacetylene vesicles as colorimetric probes for enhanced detection of double-stranded DNA. Sensors and Actuators B, 2016, 236: 27-34. (IF 5.667; 工程技术一区)
[14] Lu Chen, Chunsun Zhang*, Da Xing*. Paper-based bipolar electrode-electrochemiluminescence (BPE-ECL) device with battery energy supply and smartphone read-out: A handheld ECL system for biochemical analysis at the point-of-care level. Sensors and Actuators B, 2016, 237: 308-317.(IF 5.667; 工程技术一区)
[15] Yong Yao, Chunsun Zhang*. A novel screen-printed microfluidic paper-based electrochemical device for detection of glucose and uric acid in urine. Biomedical Microdevices, 2016, 18(5): 92.(IF 2.077; 工程技术二区)
[16] Yong Yao, Chunsun Zhang*. A novel one-step fabricated, droplet-based electrochemical sensor for facile biochemical assays. Sensors, 2016, 16(8): 1231. (IF 2.475; 工程技术三区)
[17] Wenrong Guan, Chunsun Zhang*, Feifei Liu, Min Liu. Chemiluminescence detection for microfluidic cloth-based analytical devices (μCADs). Biosensors and Bioelectronics, 2015, 72: 114-120.(IF 8.173; 工程技术一区)
[18] Peijing Wu, Chunsun Zhang*. Low-cost, high-throughput fabrication of cloth-based microfluidic devices using a photolithographical patterning technique. Lab on a Chip, 2015,15: 1598-1608.(IF 5.995; 工程技术一区)
[19] Rui Liu, Chunsun Zhang*, Min Liu. Open bipolar electrode-electrochemiluminescence imaging sensing using paper-based microfluidics. Sensors and Actuators B, 2015, 216: 255-262.(IF 5.667; 工程技术一区)
[20] Feifei Liu, Chunsun Zhang*. A novel paper-based microfluidic enhanced chemiluminescence biosensor for facile, reliable and highly-sensitive gene detection of Listeria monocytogenes. Sensors and Actuators B, 2015, 209: 399-406.(IF 5.667; 工程技术一区)
[21] Min Liu, Chunsun Zhang*, Feifei Liu. Understanding wax screen-printing: A novel patterning process for microfluidic cloth-based analytical devices. Analytica Chimica Acta, 2015, 891: 234-246.(IF 5.123; 分析化学一区)
[22] Bowen Shu, Chunsun Zhang*, Da Xing*. A handheld flow genetic analysis system (FGAS): towards rapid, sensitive, quantitative and multiplex molecular diagnosis at the point-of-care level. Lab on a Chip, 2015,15: 2597-2605.(IF 5.995; 工程技术一区)
[29] Chunsun Zhang*, Yuyuan Li, Haiying Wang, Rapid amplification and detection of foodborne pathogenic rotavirus by continuous-flow reverse transcription-polymerase chain reaction integrated with online fluorescence analysis. Chinese Journal of Analytical Chemistry, 2011, 39(5): 645-651. (IF 0.824; 化学4区)
[30] Chunsun Zhang, Da Xing*. Single-molecule DNA amplification and analysis using microfluidics. Chemical Reviews, 2010, 110: 4910-4947.(IF 52.613; 化学一区)
[31] Chunsun Zhang, Da Xing*. Decreasing microfluidic evaporation loss using the HMDL method: open systems for nucleic acid amplification and analysis. Microfluidics and Nanofluidics, 2010, 9: 17-30.(IF 2.384; 工程技术二区)
[32] Chunsun Zhang, Da Xing*. Microfluidic gradient PCR (MG-PCR): a new method for microfluidic DNA amplification. Biomedical Microdevices, 2010, 12:1-12.(IF 2.077; 工程技术二区)
[33] Chunsun Zhang, Da Xing*. Parallel DNA amplification by convective polymerase chain reaction with various annealing temperatures on a thermal gradient device. Analytical Biochemistry, 2009, 387:102-112. (IF 2.275; 生物三区)
[34] Haiying Wang, Chunsun Zhang*, Yuyuan Li, Rapid detection of tobacco mosaic virus from crude samples on oscillatory-flow reverse transcription polymerase chain reaction microfluidics. Chinese Journal of Analytical Chemistry, 2009, 37 (9) : 1286-1290. (IF 0.824; 化学4区)
[35] Yuyuan Li, Da Xing*, Chunsun Zhang, Rapid detection of genetically modified organisms on a continuous-flow polymerase chain reaction microfluidics, Analytical Biochemistry, 2009, 385 (1): 42-49.(IF 2.275; 生物三区)
[36] Chunsun Zhang, Da Xing*, Yuyuan Li, Applications of laser technique for polymeras chain reaction microfluidic chips. Chinese Journal of Analytical Chemistry, 2008, 36(2): 259-265.(IF 0.824; 化学区)
[37] Chunsun Zhang, Da Xing*. Miniaturized PCR chips for nucleic acid amplification and analysis: latest advances and future trends. Nucleic Acids Research, 2007, 35: 4223-4237. (IF 11.561; 生物一区)
[38] Chunsun Zhang, Da Xing*, Yuyuan Li. Micropumps, microvalves, and micromixers within PCR microfluidic chips: Advances and trends. Biotechnology Advances, 2007, 25: 483–514. (IF 11.452; 工程技术1区)
[39] C. Zhang*, D. Xing, J. Xu, Continuous-flow PCR microfluidics for rapid DNA amplification using thin film heater with low thermal mass. Analytical Letters, 2007, 40(9): 1672-1685.(IF 1.206; 化学4区)
[40] Chunsun Zhang, Jinliang Xu*, Jianqin Wang, Hanping Wang, Continuous-flow polymerase chain reaction microfluidics by using spiral capillary channel embedded on copper. Analytical Letters, 2007, 40(3): 497-511. (IF 1.206; 化学4区)
[41] Chunsun Zhang, Jinliang Xu*, Wenli Ma, Wenling Zheng. PCR microfluidic devices for DNA amplification. Biotechnology Advances, 2006, 24: 243-284.(IF 11.452; 工程技术1区)
[42] Chunsun Zhang, Jinliang Xu*, Jianqin Wang, Hanping Wang, Experimental study of continuous-flow polymerase chain reaction microfluidics based on polytetrafluoroethylene capillary. Chinese Journal of Analytical Chemistry, 2006, 34(8): 1197-1202. (IF 0.824; 化学4区)
[43] C.S. Zhang, J.L. Xu*, The design development of continuous-flow polymerase chain reaction chip. Chinese Journal of Analytical Chemistry, 2005, 33(5): 729-734. (IF 0.824; 化学4区)
[44] C.S. Zhang, S.S. Fan*, D.Q. Liang, K.H. Guo. Effect of additives on formation of natural gas hydrate. Fuel, 2004, 83, 2115-2121.(IF 4.908; 工程技术2区)
京公网安备 11010802027423号