Micro total analysis systems : proceedings of the μTAS '94 Workshop, held at MESA Research Institute, University of Twente, The Netherlands, 21-22 November 1994

The use of silicon-based microsystems for chemical analysis is one of the most promising concepts in the recent developments in micro system technology (MST). It is expected that chemical sensors will be increasingly integrated in so-called miniaturized total analysis systems (uTAS), a concept first presented by Ciba-Geigy. In such systems, all steps in a chemical determination, from sampling to detection and data treatment, are integrated in one miniature instrument. uTAS offer a variety of advantages over conventional analysis systems such as improved analytical performance, reduced reagent and power consumption, small size, possibility of new and more complicated functions, higher reliability and lower fabrication costs. Application of uTAS may be found in fields like process industry, environmental monitoring, medical diagnostics, aeronautics, automotive industry, and more.

• The Challenge of Developing uTAS
• P. Bergveld. uTAS: Miniaturized Total Chemical Analysis Systems
• A. Manz, E.M.J. Verpoorte, D.E. Raymond, C.S. Effenhauser, N. Burggraf, H.M. Widmer. Chances of uTAS in Analytical Chemistry
• W.E. van der Linden. uTAS for Biochemical Analysis
• I. Karube. Detection Principles for uTAS
• H.-J. Ache. Microfabricated Liquid Handling Elements
• H. Sandmaier, R. Zengerle, A. Richter. Micromechanical Components for uTAS
• J.H. Fluitman, A. van den Berg, T.S. Lammerink. Material Science for Future (Bio)Chemical Microsystems: the Key Role of Tailoring Interfaces
• W. Gopel. Optical Microsystems for (Bio)Chemical Analysis
• O.S. Wolfbeis. Integration of Analytical Systems Incorporating Chemical Reactions and Electrophoretic Separation
• D.J. Harrison, K. Fluri, Zhongui Fan, K. Seiler. Flow Injection Microsystems - There is a Past but Where is the Future? J. Ruzicka. Micromachined Flow-Through Measurement Chambers Using LAPS Chemical Sensors
• L. Bousse, R. McReynolds. Development of a PCR Microreactor
• M.A. Northrup, C. Gonzales, S. Lehew, R. Hills. Application of Miniature Analyzers: From Microfluidic Components to uTAS
• J. Branebjerg, B. Fabius, P. Gravesen. Microanalysis Systems for Gases
• I. Lundstrom, A. Lloyd-Spetz, H. Sundgren, F. Winquist. Bonding and Assembling Methods for Realizing a uTAS
• S. Shoji, M. Esashi. Microsystems for Analysis in Flowing Solutions
• B.H. van der Schoot, E.M.J. Verpoorte, S. Jeanneret, A. Manz, N.F. de Rooij. Combined Blood Gas Sensor for pO2, pCO2 and pH
• Ph. Arquint, B.H. van der Schoot, N.F. de Rooij. A Fluid Handling and Injection Microsystem for a uTAS
• N. Croce, M.C. Carrozza, P. Dario. Design of an Adaptive Unsupervised Hybrid Microsystem for Artificial Olfaction
• F.A.M. Davide, C. di Natale, A. d'Amico. Integration of an Amperometric Glucose Sensor in a uTAS
• L. Forssen, H. Elderstig, L. Eng, M. Nordling. Electric Field Mediated Cell Manipulation, Characterisation and Cultivation in Highly Conductive Media
• G. Fuhr, B. Wagner. Electrochemical Microanalytical System for Ionometric Measurements
• W. Hoffmann, M. Bruns, B. Bustgens, E. Bychkov, H. Eggert, W. Keller, D. Maas, R. Rapp, R. Ruprecht, W. Schomburg, W. Suss. Modulator Potentiometric Measuring System for the Development and Comfortable Testing of Miniaturized Ion Sensors
• W. Hoffmann, R. Rapp, H.J. Ache. A Novel Sampling Technique for Total Analysis Systems
• W. Kunnecke, U. Bilitewski. A Micromachined Glucose Oxidase Enzyme Reactor
• T. Laurell, L. Rosengren, J. Drott. First Steps of uTAS in Latvia
• A. Lusis, J. Kleperis, V. Eglitis, A. Lloyd-Spetz, I. Lundstrom, H. Sundgren, F. Winquist, G. Strautmanis, I. Slaidins, P. Misans, P. Rozukalns, S. Sjulzics. Microreactor with Integrated Static Mixer and Analysis System
• H. Mensinger, Th. Richter, V. Hessel, J. Dopper, W. Ehrefeld. Microelectrode Arrays as Transducers for Microanalysis Systems
• H. Meyer, B. Naendorf. (Part contents).