Micromachining in plastics using X-ray lithography for the fabrication of micro-electrophoresis devices

Micromachining was performed in polymethylmethacrylate (PMMA) using X-ray l ithography for the fabrication of miniaturized devices (microchips) for pot ential applications in chemical and genetic analyses. The devices were fabr icated using two different techniques: transfer mask technology and a Kapto n(R) mask. For both processes, the channel topography was transferred (1:1) to the appropriate substrate via the use of art optical mask. In the case of the transfer mask technique, the PMMA substrate was coated with a positi ve photoresist and a thin Au/Cr plating base. Following UV exposure, the re sist was developed and a thick overlayer (similar to 3 mu m) of Au electrop lated onto the PMMA substrate only where the resist was removed, which acte d as an absorber of the X-rays. In the other technique, a Kapton(R) film wa s used as the X-ray mask. In this case, the Kapton(R) film was UV exposed u sing the optical mask to define the channel topography and following develo pment of the resist, a thick Au overlayer (8 mu m) was electrodeposited ont o the Kapton(R) sheet. The PMMA wafer during X-ray exposure was situated di rectly underneath the Kapton(R) mask. In both cases, the PMMA wafer was exp osed to soft X-rays and developed to remove the exposed PMMA. The resulting channels were found to be 20 mu m in width (determined by optical mask) wi th channel depths of similar to 50 mu m (determined by x-ray exposure time) . In order to demonstrate the utility of this micromachining process, sever al components were fabricated in PMMA including capillary/chip connectors, injectors for fixed-volume sample introduction, separation channels for ele ctrophoresis and integrated fiber optic fluorescence detectors. These compo nents could be integrated into a single device to assemble a system appropr iate for the rapid analysis of various targets.