Abstract:
In this lecture, I will give an overview of the present state in the field of
microfluidics, and especially the aim for realizing a lab-on-a-chip.
Then, I'll present a novel approach towards the needs of a versatile microfluidic chip-based microfluidic system with unique properties and functionality. Like for microarrays and in contrast to many existing microfluidic technologies, the fluid handling is performed on the flat surface of a programmable chip, where fluidic tracks and functional blocks such as valves, dispensers, mixers, and sensing elements are chemically defined using standard lithographic techniques. The actuation of the fluid, the driving and adressing of the functional elements as well as possible sensors are based on electrically excited mechanical acoustic waves, propagating along the surface of a chip. The combination of such fluidic networks and our unique pumping technology results in fully programmable microfluidic processor chips. The whole system has no moving parts, and is easily fabricated employing standard semiconductor technologies. Moreover, due to the planar nature of the chip all functional blocks are readily accessible from the outside, e.g., by pipettes or spotting robots. This unique feature makes our programmable fluidic processors fully compatible to existing laboratory environments and most any chemical and biological processes and assays.
Typical areas for the application of this novel technology are the hybridization of DNA or proteomic microarrays, nano-titration stages, on-chip polymerase chain reactions, and cell assays, where single cell manipulation at the planar surface of a chip can be performed. Apart from giving a detailed introduction to the basics of our technology we present a variety of different applications.
Additional information can be found at http://Advalytix.de
This seminar is easily accessible to persons with disabilities. For more information or for assistance, please contact the Mathematics Department at 743-3500.