中文
Earlier issues
Announcement
More
Progress in Chemistry 2005, Vol. 17 Issue (04): 573-580   Next Articles

• Review •

High Throughput Microanalysis

Chen Yi**   

  1. Laboratory of Analytical Chemistry for Life Science, Institute of Chemistry, Chinese Academy of Sciences,Beijing 100080,China
  • Received: Revised: Online: Published:
  • Contact: Chen  Yi
PDF ( 1811 ) Cited
Export

EndNote

Ris

BibTeX

Development of high throughput microanalysis (HTMA) is proposed, which is a key issue in analytical chemistry and is essential to break through the bottle-neck emerged in life science since the outburst of post-genomic projects. Some theoretical possibilities are inspected, with also a brief discussion on the developing HTMA including channel and dot array technologies. Surface plasma resonance imaging is specially introduced as a promising, label-free and multifunctional HTMA method.
Key words: high throughput, microanalysis, chip-based methods, surface plasma resonance, imaging

CLC Number: 

[ 1 ] 陈义(Chen Y) . 分析化学的明天: 科学发展前沿与挑战(Tomorrow of Analytical Chemistry : Frontier and Challenge) (庄乾坤、梁文平主编) ( eds. Zhuang Q K, Liang W P) . 北京(Beijing) : 科学出版社(Science Press) , 2003. 78 —91
[ 2 ] Olefirowicz T M, Ewing A G. Anal . Chem. , 1990 , 62 : 1872
[ 3 ] Sims C E , Meredith G D , Krasieva T B , et al . Anal . Chem. ,1998 , 70 : 4570 —4577
[ 4 ] Castro A , Shera E B. Appl . Opt . , 1995 , 34 : 3218 —3222
[ 5 ] Anderson N L , Anderson N G. Electrophoresis , 1998 , 19 :1853 —1861
[ 6 ] Huang X C , Quesada M A , Mathies R A. Anal . Chem. , 1992 ,64 : 2149 —2154
[ 7 ] Shi Y, Simpson P C , Scherer J R , et al . Anal . Chem. , 1999 ,71 : 5354 —5361
[ 8 ] Carrilho E. Electrophoresis , 2000 , 21 : 55 —65
[ 9 ] http://www.affymetrix.com
[10] Ekins R , Chu F W. Trends in Biotechnology , 1999 , 17 : 217 —218
[11] Sheridan C. Nature Biotechnology , 2005 , 23 : 3 —4
[12] Kim S H , Tamrazi A , Carlson K E , Katzenellenbogen J A. Mol .Cell Proteomics , 2005 , 4 : 267 —277
[13] Albala J S. Expert Rev. Mol . Diagn. , 2001 , 1 : 145 —152
[14] Figeys D , Pinto D. Electrophoresis , 2001 , 22 : 208 —216
[15] Heuschkel M O , Fejtl M, Raggenbass M, et al . J . Neurosci .Meth. , 2002 ,114 : 135 —148
[16] Zhou W, Beck B F , Adams A L. Environmental Geology , 2002 ,42 : 922 —928
[17] Doescher M S , Evans U , Colavita P E , et al . Electrochemical and Solid2State Letters , 2003 , 6 : C112 —C115
[18] Guttman A , Rónai Z. Electrophoresis , 2000 , 21 : 2058 —2061
[19] Becker H , Lowack K, Manz A. J . Micromech. Microeng. ,1998 , 8 : 24 —28
[20] Michels D A , Hu S , Schoenherr R M, et al . Mol . Cell .Proteomics , 2002 , 1 : 69 —74
[21] Chen X X, Wu H K, Mao C D , Whitesides G M. Anal Chem. ,2002 , 74 : 1772 —1778
[22] Yang C , Zhang L , Liu H , Zhang W, Zhang Y. J . Chromatogr.A , 2003 , 1018 : 97 —103
[23] Wang Y, Zhang J , Liu C L , et al . Analytica Chimica Acta ,2005 , 530 : 227 —235
[24] Evans C R , Jorgenson J W. Anal . Bioanal . Chem. , 2004 , 378 :1952 —61
[25] 陈义( Chen Y) . 毛细管电泳技术及应用( Capillary Electrophoresis : Technology and Applications) . 北京(Beijing) :化学工业出版社(Chemical Industry Presss) ,2000
[26] Barme I , Bruin GJ . Methods Mol . Biol . , 2001 , 162 : 383 —392
[27] Herr A E , Molho J I , Drouvalakis K A , et al . Anal . Chem. ,2003 , 75 : 1180 —1187
[28] http://www.lcms.com/reviews.htm
[29] Bernet P , Blaser D , Berger S , Sch?r M. Chimia , 2004 , 58 :196 —199
[30] Patel D J , Suri A K, Jiang F , et al . J . Mol . Biol . , 1997 , 272 :645 —664
[31] http://www.molecular-beacons.org
[32] Homola J . Anal . Bioanal . Chem. , 2003 , 377 : 528 —539
[33] Ritchie R H. Phys. Rev. , 1957 , 106 : 874 —881
[34] Turbadar T. Proc. Phys. Soc. London , 1959 , 73 : 40 —44
[35] Powell C J , Swan J B. Phys. Rev. , 1960 , 118 : 640 —643
[36] Otto A. Z. Phys. , 1968 , 216 : 398 —410
[37] Kretschmann E , R?ther H. Z. Naturforsch. A , 1968 , 23A:2135 —2136
[38] Lubbers D W, Opitz N. Z. Naturforsch. C , 1975 , 30 : 532 —533
[39] Liedberg B , Nylander C , Lundstrêm I. Sens. Actuators , 1983 ,4 : 299 —304
[40] Lee HJ , Goodrich T T , Corn R M. Anal . Chem. , 2001 , 73 :5525 —5531
[41] Yeatman E , Ash E. Electron. Lett . , 1987 , 23 : 1091 —1092
[42] Hickel W, Kamp D , Knoll W. Nature (London) , 1989 , 339 : 186
[43] Rothenh? usler B , Knoll W. J . Opt . Soc. Am. B , 1988 , 5 :1401 —1405 ; Nature , 1988 , 332 : 615 —617
[44] Nelson B P , Frutos A G, Brockman J M, Corn R M. Anal .Chem. , 1999 , 71 : 3928 —3934
[45] Jordan C E , Corn R M. Anal . Chem. , 1997 , 69 : 1449 —1456
[46] Jordan C E , Frutos A G, Thiel A J , Corn R M. Anal . Chem. ,1997 , 69 : 4939 —4947
[47] Goodrich T T , Lee H J , Corn R M. J . Am. Chem. Soc. , 2004 ,126 : 4086 —4087
[48] Goodrich T T , Lee H J , Corn R M. J . Am. Chem. Soc. , 2004 ,76 : 6173 —6178
[49] Wegner G J , Wark A W, Lee H J , et al . Anal . Chem. , 2004 ,76 : 5677 —5684
[50] Wang Z , Zheng Q Y, Chen Y. Analytical Letter , 2001 , 34 :2609 —2619
[51] Wang Z , Chen Y. Carbohydrate Research , 2001 , 332 : 209 —213
[52] Chen Y, Huang H , Shen G, Liu W, Yu X, Qi L. Molecular and Cellular Proteomics , 2004 , 3 : S165
[53] Raether H. Surface Plasmon on Smooth and Rough Surfaces and on Gratings. Berlin , New York : Springer-Verlag , 1988
[54] Grigorenko A N , Beloglazov A A , Nikitin P I , et al . Optics Communications , 2000 , 174 : 151 —155
[55] Nikitin P I , Grigorenko A N , Beloglazov A A , et al . Sensors and Actuators , 2000 , 85 : 189 —193
[56] Kabshin A V , Nikitin P I. Quantum Electronics , 1997 , 27 :653 —654
[57] 黄昊文(Huang H W) . 中国科学院化学研究所博士论文(Doctorial Thesis of Institute of Chemistry , Chinese Academy of Sciences) , 2004
[1] Jing He, Jia Chen, Hongdeng Qiu. Synthesis of Traditional Chinese Medicines-Derived Carbon Dots for Bioimaging and Therapeutics [J]. Progress in Chemistry, 2023, 35(5): 655-682.
[2] Zixuan Liao, Yuhui Wang, Jianping Zheng. Research Advance of Carbon-Dots Based Hydrophilic Room Temperature Phosphorescent Composites [J]. Progress in Chemistry, 2023, 35(2): 263-373.
[3] Anchen Fu, Yanjia Mao, Hongbo Wang, Zhijuan Cao. Development and Application of Dioxetane-based Chemiluminescent Probes [J]. Progress in Chemistry, 2023, 35(2): 189-205.
[4] Dang Zhang, Xi Wang, Lei Wang. Biomedical Applications of Enzyme-Powered Micro/Nanomotors [J]. Progress in Chemistry, 2022, 34(9): 2035-2050.
[5] Feng Lu, Ting Zhao, Xiaojun Sun, Quli Fan, Wei Huang. Design of NIR-Ⅱ Emissive Rare-earth Nanoparticles and Their Applications for Bio-imaging [J]. Progress in Chemistry, 2022, 34(6): 1348-1358.
[6] Zhen Wang, Xi Li, Yuanyuan Li, Qi Wang, Xiaomei Lu, Quli Fan. Activatable NIR-Ⅱ Probe for Tumor Imaging [J]. Progress in Chemistry, 2022, 34(1): 198-206.
[7] Xuechuan Wang, Yansong Wang, Qingxin Han, Xiaolong Sun. Small-Molecular Organic Fluorescent Probes for Formaldehyde Recognition and Applications [J]. Progress in Chemistry, 2021, 33(9): 1496-1510.
[8] Huifeng Xu, Yongqiang Dong, Xi Zhu, Lishuang Yu. Novel Two-Dimensional MXene for Biomedical Applications [J]. Progress in Chemistry, 2021, 33(5): 752-766.
[9] Yecheng Dang, Yangzhen Feng, Dugang Chen. Red/Near-Infrared Biothiol Fluorescent Probes [J]. Progress in Chemistry, 2021, 33(5): 868-882.
[10] Chao Zhao, Zongwei Cai. Mass Spectrometry Imaging and Omics for Environmental Toxicology Research [J]. Progress in Chemistry, 2021, 33(4): 503-511.
[11] Fei Ren, Jianbing Shi, Bin Tong, Zhengxu Cai, Yuping Dong. Near Infrared Fluorescent Dyes with Aggregation-Induced Emission [J]. Progress in Chemistry, 2021, 33(3): 341-354.
[12] Yunxue Wu, Hengyi Zhang, Yu Liu. Application of Azobenzene Derivative Probes in Hypoxia Cell Imaging [J]. Progress in Chemistry, 2021, 33(3): 331-340.
[13] Pingping Zhao, Junxing Yang, Jianhui Shi, Jingyi Zhu. Construction and Application of Dendrimer-Based SPECT Imaging Agent [J]. Progress in Chemistry, 2021, 33(3): 394-405.
[14] Yuanyuan Liu, Yun Guo, Xiaogang Luo, Genyan Liu, Qi Sun. Detection of Metal Ions, Small Molecules and Large Molecules by Near-Infrared Fluorescent Probes [J]. Progress in Chemistry, 2021, 33(2): 199-215.
[15] Yafang Sun, Ziping Zhou, Tong Shu, Lisheng Qian, Lei Su, Xueji Zhang. Multicolor Luminescent Gold Nanoclusters: From Structure to Biosensing and Bioimaging [J]. Progress in Chemistry, 2021, 33(2): 179-187.
Viewed
Full text


Abstract

High Throughput Microanalysis