项楠 副教授

发布者:发布时间:2015-03-29浏览次数:5102


职称

副教授




政治面貌

中共党员




办公室

机械楼203 微流控实验室




E-mail

nan.xiang@seu.edu.cn




学习经历

2005年9月-2009年6月浙江大学,生物系统工程本科/学士

2009年9月-2014年12,东南大学,机械制造及其自动化研究生/博士

工作经历

2014年12月2017年11月,东南大学机械工程学院讲师

201712月-至今,东南大学,机械工程学院,副研究员(破格)/硕导

教授课程

机械制图

生物微流体技术  

研究方向

1. 医疗器械设计与制造

2. 微流控技术

3. 微细加工技术

获奖情况

2016年江苏省优秀博士学位论文

2017年江苏省'六大人才高峰'高层次人才计划

2018年南京市第十二届自然科学优秀学术论文一等奖

2016年东南大学优秀博士学位论文

2016年中泰国立奖教金三等奖

2013年研究生国家奖学金

2012年研究生国家奖学金

论文著作

[1] Xiang Nan*,Ni Zhonghua, Yi Hong*. Concentration‐controlledparticle focusing in spiral elasto‐inertial microfluidic devices. Electrophoresis, 2018, 39:417-424(SCIIF=2.744封面)

[2] TangWenlai, Tang Dezhi, Ni Zhonghua, XiangNan*, Yi Hong*. Microfluidic impedance cytometerwith inertial focusing and liquid electrodes for high-throughput cell countingand discrimination, Analytical Chemistry,2017, 89:3154-3161(SCIIF=6.320研究亮点)

[3] LiuLinbo, Chen Ke*, Huang Di, Wang Xin, XiangNan*, Ni Zhonghua. A novel ‘leadless’ dielectrophoresis chip with dotmatrix electrodes for patterning nanowires. Nanotechnology,2017, 28(28):285302(SCIIF=3.44封面英国物理学会旗下nanotechweb.org网站专题报道)

[4] Xiang Nan*, Zhang Xinjie, Dai Qing,Cheng Jie, Chen Ke, Ni Zhonghua*. Fundamentals of elasto-inertial particlefocusing in curved microfluidic channels, Lab on a Chip, 2016, 16(14):2626-2635 (SCIIF=6.045背封)

[5] ZhangXinjie, Xiang Nan (共一作), Tang Wenlai, HuangDi, Wang Xin, Yi Hong, Ni Zhonghua. A passive flow regulator with low thresholdpressure for high-throughput inertial isolation of microbeads. Labon a Chip, 2015, 15(17):3473-3480 (SCIIF=6.045封面)

[6] Wang Xin, Chen Ke, Liu Linbo, Xiang Nan*, Ni Zhonghua*.Dielectrophoresis-based multi-step nanowire assembly on a flexible superstrate.Nanotechnology, 2018, 29(2):025301.(SCIIF=3.44)

[7] TangWenlai, Tang Dezhi, Ni Zhonghua, Xiang Nan*, Yi Hong*. A portable single-cell analysis systemintegrating hydrodynamic trapping with broadband impedance spectroscopy, Science China Technological Sciences,2017, 60(11):1707-1715 (SCIIF=1.719)

[8]Zhang Xinjie, Zhu Zhixian, Ni Zhonghua, Xiang Nan*, Yi Hong*.Inexpensive, rapid fabrication of polymer-film microfluidic autoregulatoryvalve for disposable microfluidics. Biomedical Microdevices,2017, 19(2):21 (SCIIF=2.062)

[9] XiangNan*, Dai, Qing, Ni, Zhonghua*, Multi-trainelasto-inertial particle focusing in straight microfluidic channels, AppliedPhyscis Letters, 2016, 109(13):134101 (SCIIF=3.341)

[10] XiangNan*, Huang Di, Cheng Jie, Chen Ke, ZhangXinjie, Tang Wenlai, Ni Zhonghua*, Focusing dynamics of finite-sized particlesin confined microfluidic channels, Applied Physics Express,2016, 9:027001 (SCIIF=2.667)

[11] ZhangXinjie, Zhu Zhixian, Xiang Nan*, NiZhonghua*, A microfluidic gas damper for stabilizing gas pressure in portablemicrofluidic systems, Biomicrofluidics, 2016,10:054123 (SCIIF=2.535)

[12]Jiang Di, Tang Wenlai, Xiang Nan*, Ni Zhonghua*. Numerical simulation of particle focusingin a symmetrical serpentine microchannel, RSC Advances,2016,6: 57647-57657 (SCIIF=3.108)

[13] ZhangXinjie, Wang Xin, Chen Ke, Cheng Jie, XiangNan*, Ni Zhonghua*.Passive flow regulator for precisehigh-throughput flow rate control in microfluidic environments, RSCAdvances, 2016, 6(38):31639-31646 (SCIIF=3.108)

[14] HuangDi, Shi Xin, Qian Yi, Tang Wenlai, Liu Linbo, Xiang Nan*, Ni Zhonghua*. Rapid separation of human breast cancercells from blood using a simple spiral channel device, Analytical Methods,2016, 8(30):5940-5948 (SCIIF=1.9)

[15] ZhangXinjie, Huang Di, Tang Wenlai, Jiang Di, Chen Ke, Yi Hong, Xiang Nan*, Ni Zhonghua*. A low cost and quasi-commercial polymerfilm chip for high-throughput inertial cell isolation, RSC Advances, 2016,6(12):9734-9742 (SCIIF=3.108)

[16] Xiang Nan, Shi Zhiguo, Tang Wenlai,Huang Di, Zhang Xinjie, Ni Zhonghua*, Improved understanding of particle migrationmodes in spiral inertial microfluidic devices, RSC Advances, 2015, 5:77264-77273(SCIIF=3.108)

[17] Xiang Nan, Chen Ke, Dai Qing, Jiang Di, Sun Dongke,Ni Zhonghua. Inertia-induced focusing dynamics of microparticles throughout acurved microfluidic channel. Microfluidics and Nanofluidics,2015, 18(1):29-39 (SCIIF=2.344)

[18] Xiang Nan*, Ni Zhonghua*, High-throughputblood cell focusing and plasma isolation using spiral inertial microfluidicdevices, Biomedical Microdevices, 2015, 17:110-121 (SCIIF=2.062)

[19] DaiQing, Xiang Nan, Cheng Jie, NiZhonghua. Viscoelastic focusing of microparticles in circular cross-sectionalmicrochannels. Acta Physica Sinica, 2015, 64(15):154703 (SCIIF=0.624)

[20] Huang Di, Xiang Nan, Tang Wenlai, Zhang Xinjie, Ni Zhonghua.Microfluidics-Based Circulating Tumor Cells Separation. Progressin Chemistry, 2015, 27(7):882-912 (SCIIF=0.953)

[21] Tang Wenlai, Xiang Nan, Zhang Xinjie, Huang Di, Ni Zhonghua. Dynamicprocess and flow-rate regulation mechanism of particle inertial focusing inan asymmetric ally curved microchannel. Acta Physica Sinica, 2015,64(18):184703 (SCIIF=0.624)

[22] Chen Ke, Quan Yunlin, Song Chunfeng, Xiang Nan, Jiang Di, Sun Dongke, YangJuekuang, Yi Hong, Ni Zhonghua. Accurate control of individual metallicnanowires by light-induced dielectrophoresis: Size-based separation andarray-spacing regulation. Sensors and Actuators A-Physical,2015, 225:139-147 (SCIIF=2.499)

[23] Tang Wenlai, Xiang Nan, Huang Di, Zhang Xinjie, Gu Xingzhong, Ni Zhonghua.Microfluidics-Based Single-Cell Biophysical Characterization. Progressin Chemistry, 2014, 26(6):1050-1064 (SCIIF=0.953)

[24] Chen Ke, Xiang Nan, Quan Yunlin, Zhu Xiaolu, Sun Dongke, Yi Hong, NiZhonghua. Directed transport and location-designated rotation of nanowiresusing ac electric fields. Microfluidics and Nanofluidics,2014, 16(1-2):237-246 (SCIIF=2.344)

[25] Jiang Di, Sun Dongke, Xiang Nan, Chen Ke, Yi Hong, Ni Zhonghua. LatticeBoltzmann numerical simulation and experimental research of dynamic flow inan expansion-contraction microchannel. Biomicrofluidics, 2013, 7(3):034113(SCIIF=2.535)

[26] Xiang Nan, Yi Hong, Chen Ke, Sun Dongke, Jiang Di,Dai Qing, Ni Zhonghua. High-throughput inertial particle focusing in a curvedmicrochannel: Insights into the flow-rate regulation mechanism and processmodel. Biomicrofluidics, 2013, 7(4):044116 (SCIIF=2.535)

[27] Xiang Nan, Yi Hong, Chen Ke, Wang Shanfang, NiZhonghua. Investigation of the maskless lithography technique for the rapid andcost-effective prototyping of microfluidic devices in laboratories. Journal of Micromechanics and Microengineering, 2013,23(2):025016 (SCIIF=1.794)

[28] Xiang Nan, Chen Ke, Sun Dongke, Wang Shanfang, YiHong, Ni Zhonghua. Quantitative characterization of the focusing process anddynamic behavior of differently sized microparticles in a spiral microchannel. Microfluidicsand Nanofluidics, 2013, 14(1-2):89-99 (SCIIF=2.344)

[29] Sun Dongke, Jiang Di, Xiang Nan, Chen Ke, Ni Zhonghua. An Immersed Boundary-LatticeBoltzmann Simulation of Particle Hydrodynamic Focusing in a StraightMicrochannel.Chinese Physics Letters, 2013,30(7):074702 (SCIIF=0.8)

[30] Sun Dongke, Wang Yong,Jiang Di, Xiang Nan, Chen Ke, NiZhonghua. Dynamic self-assembly of particles in an expanding channel flow. Applied Physics Letters, 2013, 103(7):071905 (SCIIF=3.341)

[31] Sun Dongke, Xiang Nan, Chen Ke, Ni Zhonghua.Lattice Boltzmann modeling of particle inertial migration in a curved channel. ActaPhysica Sinica, 2013, 62(2):024703 (SCIIF=0.624)

[32] Sun Dongke, Xiang Nan, Jiang Di, Chen Ke, Yi Hong,Ni Zhonghua. Multi-relaxation time lattice Boltzmann simulation of inertialsecondary flow in a curved microchannel. ChinesePhysics B, 2013, 22(11):114704 (SCIIF=1.223)

[33] Xiang Nan, Zhu Xiaolu, Ni Zhonghua. Application ofInertial Effect in Microfluidic Chips. Progress in Chemistry, 2011,23(9):1945-1958 (SCIIF=0.953)

[34] ZhaoGutian, Cai Di, Wu Gengsheng, Tan Qiyan, Xiang Li, Zhang Yin, Xiang Nan. A Study of Structure andProperties of Molecularly Thin Methanol Film Using the Modified Surface ForcesApparatus, Microscopy Research and Technique,2014, 77(11):851-856 (SCI, IF=1.147)

[35] Guo Xitao, Wang Wenhui, Nan Haiyan, Yu Yuanfang, Jiang Jie, Zhao Weiwei,Li Jinhuan, Zafar Zainab, Xiang Nan,Ni Zhonghua, Hu Weida, You Yumeng, Ni Zhenhua. High-performancegraphene photodetector using interfacial gating, Optica, 2016,3(10):1066-1070 (SCI, IF=7.727)

科研项目

项目名称

项目类别

项目时间

工作类别

项目金额

形变和形状特性对生物粒子惯性迁移行为的影响机理研究
  国家自然科学基金青年项目 (51505082)2016/01-2018/12负责人

26万元  

复杂特性生物细胞惯性聚焦机理及其应用研究  江苏省自然科学基金青年项目 (BK20150606)2015/07-2018/06负责人

20万元  

第十四批“六大人才高峰”高层次人才计划 (C类) 人才项目2017负责人

4万元  

面向稀有循环肿瘤细胞的非标记精准检测仪器研制 自然科学基金委重大科研仪器研制项目(81727801) 2018/01-2022/12 参加 (排名第二)

690万元  

全血中稀有循环肿瘤细胞的精准表征方法研究 国家自然科学基金面上项目(51775111) 2018/01-2021/12 参加 (排名第二)

62万元  

稀有细胞精准电阻抗表征的装置开发研究 东南大学高水平论文专项 2017/03-2018/12负责人

11万元  

基于惯性微流控技术的生物细胞聚焦机理及分选应用研究 流体动力与机电系统国家重点实验室开放基金 (GZKF-201501)2015/12-2017/12负责人

5万元  

新型螺旋流道芯片粒子聚焦机理的理论和实验研究 新进教师科研启动经费2015/01-2015/12负责人

10万元  

基于惯性及介电泳技术的循环肿瘤细胞多级分选装置研究  国家自然科学基金面上项目 (81572906)2016/01-2018/12参加(排名第二)

77.6万  

单根精度纳米线的高柔性与大规模操控技术研究  国家自然科学基金面上项目 (51375089)2014/01-2017/12参加(排名第三)

90万元  

基于惯性微流控技术的微纳米粒子操控机理的研究  国家自然科学基金科学部主任基金 (51145009)2012/01-2012/12参加(排名第二)

10万元  

基于惯性微流控技术的微纳米粒子分选方法研究  高等学校博士学科点专项科研基金博导类课题 (20110092110003)2012/01-2014/12参加(排名第二)

12万元  

基于Dean惯性流的微纳米粒子自组装芯片研究  江苏省自然科学基金面上项目 (BK2011336)2011/07-2014/07参加(排名第二)

15万元  

专利

专利号

专利名称

专利类型

PCT/CN2017/104365

ZL 201711414340.9

ZL 201711248886.1

ZL 201710872818.6

ZL 201710816147.1

ZL 201710816183.8

ZL 201710461769.7

ZL 201710238945.0

ZL 201710235635.3

ZL 201710227189.1

ZL 201710153375.5

ZL 201710126436.9

ZL 201610346327.3

ZL 201510041153.5

ZL 201610057507.X

ZL 201510766988.7

ZL 201610299263.6

ZL 201010600719.0

ZL 201110407831.7

ZL 201210175163.4

ZL 201510280209.2

ZL 201410154420.5

ZL 201410348579.0

ZL 201310410606.8

ZL 201310372705.1

ZL 201310066617.9

ZL 201010591577.6

一种肿瘤细胞高通量分选富集微流控芯片

包括微流控芯片的循环肿瘤细胞检测仪器

微米粒子高通量富集微流控芯片

一种分选细胞的微流控器件及其使用方法

微流控注射器滤头及其使用方法

注射器流量稳定装置

一种微流控移液器枪头

一种基于光诱导介电泳技术和纳米孔的DNA测序装置和测序方法

一种高通量微米粒子循环分选与浓缩装置及其制作方法

一种肿瘤细胞高通量分选富集微流控芯片

一种能实现细胞中心位置聚焦和检测的微流控芯片

一种制作银纳米线柔性透明导电薄膜的方法

一种微流控气体阻尼器及调节方法

一种微型被动流量调节阀及其制作工艺

3D实体电极介电泳纳米线操控系统

一种夹片式微流控器件及制造方法

一种血管支架耦合系统血流动力学性能测试装置

一种多模式微混合器芯片及高通量混合和柔性混合方法

一种微米级粒子高通量分选的微流控器件及其制作方法

一种基于无掩模光刻的变高度微流道制作方法

一种集成细胞聚焦与检测的方法及其微型化系统

一种集成细胞分选及检测的微流控芯片系统

一种分离式微米级粒子自动组装、分选器件及其制作方法

一种稀有细胞多级分选微流控器件

单细胞多参数表征微流控芯片检测系统

生物微粒高通量分选和计数检测的集成芯片系统及应用

选通开关阵列及其应用方法

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