On-Chip Contactless Four-Electrode Conductivity Detection for Capillary Electrophoresis Devices

In this contribution, a capillary electrophoresis microdevice with an integrated on-chip contactless fourelectrode conductivity detector is presented. A 6-cm-long, 70-µm-wide, and 20-µm-deep channel was etched in a glass substrate that was bonded to a second glass substrate in order to form a sealed channel. Four contactless electrodes (metal electrodes covered by 30-nm silicon carbide) were deposited and patterned on the second glass substrate for on-chip conductivity detection. Contactless conductivity detection was performed in either a two-or a four-electrode configuration. Experimental results confirmed the improved characteristics of the fourelectrode configuration over the classical two-electrode detection setup. The four-electrode configuration allows for sensitive detection for varying carrier-electrolyte background conductivity without the need for adjustment of the measurement frequency. Reproducible electrophoretic separations of three inorganic cations (K + , Na + , Li + ) and six organic acids are presented. Detection as low as 5 µM for potassium was demonstrated. In the development and optimization of miniaturized analytical systems, a delicate combination of science and technology originating from microelectronic device fabrication, electrical engineering, and analytical chemistry is essential. In this multidisciplinary field, microtechnology experts combine the demands from analytical chemistry and electronic instrumentation in the design and fabrication of novel analytical devices. 1,2 Chemical analysis systems, such as high-performance liquid chromatography (HPLC) or capillary electrophoresis (CE), always consist of the combination of a separation and a detection system. For separation, CE or CE-based separation techniques are highly suitable for implementation on the microchip format. Electrokinetic control of fluid transport eliminates the need for external components such as pumps and valves. The separation efficiency is relatively independent of the separation path length and is, therefore, more compatible with miniaturization than, for instance, chromatographic techniques. As far as detection is concerned, laser-induced fluorescence (LIF) is, at present, the most widely used detection technique in miniaturized analysis systems because of its high sensitivity. The drawbacks of LIF are its limited compatibility with miniaturization and on-chip integration and the requirement for labeling of most (bio) chemically relevant compounds. External devices such as the relatively large laser and the photodetector system strongly prohibit further miniaturization. The development of alternative detection methods compatible with miniaturization and full onchip integration is highly desirable. Since electrode deposition is a well-established process in microfabrication, the implementation of detection techniques utilizing integrated electrodes has become an attractive approach. Successful coupling of conventional CE with potentiometry, 3 amperometry, 4,5 and conductometry 6-10 has been reported in the literature. In addition, both amperometric and potentiometric detection were also implemented in chip-based CE systems. [11][12][13] The primary advantage of amperometric and potentiometric detection over conductivity detection is the high selectivity induced by the electrochemical reactions that take place at the electrode surface. Only electrochemically active compounds * Corresponding author: (tel) +31 (0) 15 278 6518; (fax) +31 (0) 15 278 5755

Part IV Italy: Case 10 Tisens/Tesimo

The case of Tisens/Tesimo illustrates the critical role of governance in the course of a destination life cycle. In particular, it exemplifies how improving the effectiveness and efficiency of destination governance has the potential to relaunch stagnating or declining destinations. First, Tisens/Tesimo has managed to improve its effectiveness by developing a common strategy in a participatory manner. Second, improving efficiency in networking through an increase in trust also seems to have supported the process of recovery. However, the challenge is to establish cost-efficient collaboration while maintaining the dynamic and adaptive capacity associated with low levels of centralization. In achieving this balance, the destination raises issues about collaborative efficiency