Arrayed-electrode design for moving electric field driven capillary electrophoresis chips

Capillary electrophoresis (CE) has been a powerful separation technique in biology and biochemistry. This technique has been implemented into microflu idic devices, i.e. CE chips, using microfabrication techniques. Based upon high electric fields, samples can be separated and detected quickly. This s tudy aimed to design arrayed-electrodes to generate a moving electric field for DNA separation in CE chips and simulate the electrode dimension effect s in the uniformity and distribution of the electric held. Additional alter nating electrode pairs can further reduce the required driving voltage by o rders of magnitude but yet generate the necessary electric field to separat e the samples. Finite element analysis was used to simulate the electric field characteris tics of the CE chips with different types of arrayed electrodes. The arraye d electrode styles studied were single-side electrodes, double-banked elect rodes, and combined electrodes. The characteristics of various electrode di mensions and intervals in the electric field were analyzed. Double-banked electrodes generate a more uniform electric field inside the channel than the single-side electrode design. Combined electrodes use a si ngle-side electrode layout but provide better uniformity and higher electri c field strength than a single-side electrode layout in certain high channe ls. This work has demonstrated techniques for simulating the electric field cha racteristics of different arrayed-electrode layouts inside different high c hannels for using and designing moving electric field driven CE chips, (C) 2001 Elsevier Science B.V. Ail rights reserved.