Lab chip

Micro chemical processing at IMM -from pioneering work to customer-specific services. Lab Chip 2 (2002) 14N-21N. [Pg.111]

Lindner, D., The pChem Lab project micro total analysis system R D at Sandia National Laboratories, Lab Chip 1 (2001) 15N-19N. [Pg.111]

Wiles, C., Watts, P., Haswell, S. )., Pombo-Villae, E., 1,4-Addition of enolates to a,ff-unsaturated ketones within a micro reactor. Lab Chip 2 (2002) 62-64. [Pg.113]

Garcia-Egido, E., Spikmans, V., Wong, S. Y. F., Warrington, B. H., Synthesis and analysis of combitwtorial libraries performed in an automated micro-reactor system. Lab Chip 3 (2003) (>7-72. [Pg.124]

Many of these results, most of them more than 10 years old, have attracted some renewed interest recently. In some pTAS and Lab-Chips small liquid volumes are transported as plugs in micro channels. Owing to the smallness of the volumes. [Pg.145]

The focus of the examples given in this chapter is clearly on micro reactors for chemical processing in contrast to p-TAS or Lab-Chip systems for bioanalytical applications. In the latter microfluidic systems, the fluidic requirements are somehow different from those in micro reactors. Typically, throughput plays only a minor role in p-TAS systems, in contrast to micro reactors, where often the goal is to achieve a maximum molar flux per unit volume of a specific product. Moreover, flow control plays a much greater role in p-TAS systems than in micro reactors. In... [Pg.169]

N., Quantitative 3-dimensionalprofilingof channel networkswithin transparent lab-on-a-chip microreactors usinga digital imagingmethod. Lab. Chip 1 ( 2001) 66-71. [Pg.372]

ZhangX-, Electrokineticcontrolofa chemicalreactioninalab-on-a-chipmicro-reactormeasurementandqualitative modeiing. Lab. Chip 2 ( 2002)102-112. [Pg.372]

WooTTON, R. C. R., Foett, R., de Mello, a. j.. On-chip generation and reaction of unstable intermediates -mondithic nanoreactors for diazonium chemistry azo dyes. Lab. Chip 2 (2002) 14N-21N. [Pg.568]

Kikutani, Y, Horiuchi, T., Uchiyama, K., Hisamoto, H., Tokeshi, M., Kitamori, T, Glass microchip with three-dimensional microchannel network for 2x2 parallel synthesis. Lab. Chip 2 (2002) 188-192. [Pg.569]

Ueno, K., Kitagawa, F., Kitamura, N., Photocyanation of pyrene across an oil/ water interface in a polymer microchannel chip. Lab. Chip 2 (2002) 231-234. [Pg.569]

Burns, J. R., Ramshaw, C., The intensification of rapid reactions in multiphase systems using slug flow in capillaries. Lab. Chip 1 (2001) 10-15. [Pg.574]

Demchenko AP (2005) The problem of self-calibration of fluorescence signal in microscale sensor systems. Lab Chip 5 1210-1223... [Pg.22]

Ling Y, Rubin J, Deng Y et al (2007) A cell-laden microfluidic hydrogel. Lab Chip 7 756-762... [Pg.163]

Sato K, Mawatari K, Kitamori T (2008) Microchip-based cell analysis and clinical diagnosis system. Lab Chip 8 1992-1998... [Pg.166]

Wang Z, Kim MC, Marquez M et al (2007) High-density microfluidic arrays for cell cytotoxicity analysis. Lab Chip 7 740-745... [Pg.166]

Chambers RD, Holling D, Spink RCH, Sandford G (2001) Elemental Fluorine - Part 13. Gas-Liquid Thin Film Microreactors for Selective Direct Fluori-nation. Lab Chip 1 132-137... [Pg.16]

Chambers RD, Fox MA, Sandford G (2005) Elemental fluorine - Part 18. Selective Direct Fluorination of 1,3-Ketoesters and 1,3-Diketones using Gas/ Liquid Microreactor Technology. Lab Chip 5 1132-1139 Cheng RP, Gellman SH, DeGrado WF (2001) Beta-Peptides From Structure to Function. Chem Rev 101 3219-3232... [Pg.16]

Lu H, Schmidt MA, Jensen KF (2001) Photochemical Reactions and On-Line UV Detection in Microfabricated Reactors. Lab Chip 1 22-28 Manz A, Harrison DJ, Verpoorte EMJ, Fettinger JC, Ludi H, Widmer HM (1991) Miniaturization of Chemical-Analysis Systems - A Look into next Century Technology or just a Fashionable Craze. Chimia 45 103-105 McCreedy T (1999) Reducing the Risks of Synthesis. Chem Ind 15 588-590 McCreedy T (2000) Fabrication Techniques and Materials Commonly Used for the Production of Microreactors and Micro Total Analytical Systems. Trac Trends Anal Chem 19 396-401... [Pg.19]

Watts P, Wiles C, Haswell SJ, Pombo-ViUar E, Styring P (2001) The Synthesis of Peptides Using Microreactors. Chem Comm 11 990-991 Watts P, Wiles C, Haswell S, Pombo-Villar E (2002a) Investigation of Racemi-sation in Peptide Synthesis within a Microreactor. Lab Chip 2 141-144 Watts P, Wiles C, Haswell S, Pombo-Villar E (2002b) Solution Phase Synthesis of Beta-Peptides Using Microreactors. Tetrahedron 58 5427-5439... [Pg.20]

Andersson H, van den Berg A (2004) Microfabrication and microfluidics for tissue engineering state of the art and future opportunities. Lab Chip 4 98-103... [Pg.36]

Fletcher PDI, Haswell SJ, Zhang X (2002b) Electrokinetic control of a chemical reaction in a lab-on-a-chip micro-reactor measurement and quantitative modeling. Lab Chip 2 102... [Pg.36]

Haber C (2006) Microfluidics in commercial applications an industry perspec-tiva. Lab Chip 6 1118-1821... [Pg.37]

Hau WLW, Trau DW, Sucher NJ, Wong M, Zohar Y (2003) Surface-chemistry technology for microfluidics. J Micromech Microeng 13 272 He P, Haswell SJ, Fletcher PDI (2004) Lab Chip 4 8... [Pg.37]

Munson MS, Hasenbank MS, Fu E, Yager P (2004) Suppression of non-specific adsorption using sheath flow. Lab Chip 4 438 145 Munson MS, Hawkins KR, Hasenbank MS, Yager P (2005) Diffusion-based analysis in a sheath flow microchannel the sheath flow T-sensor. Lab Chip 5 856-862... [Pg.37]

Yang YN, Li C Kameoka J, Lee KH, Craighead HG (2005) A polymeric microchip with integrated tips and in situ polymerized monolith for electrospray mass spectrometry. Lab Chip 5 869... [Pg.38]

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