A general and exact routing methodology for Digital Microfluidic Biochips

Advances in microfluidic technologies have led to the emergence of Digital Microfluidic Biochips (DMFBs), which are capable of automating laboratory procedures in biochemistry and molecular biology. During the design and use of these devices, droplet routing represents a particularly critical challenge. Here, various design tasks have to be addressed for which, depending on the corresponding scenario, different solutions are available. However, all these developments eventually result in an “inflation” of different design approaches for routing of DMFBs - many of them addressing a very dedicated routing task only. In this work, we propose a comprehensive routing methodology which (1) provides one (generic) solution capable of addressing a variety of different design tasks, (2) employs a “push-button”-scheme that requires no (manual) composition of partial results, and (3) guarantees minimality e.g., with respect to the number of timesteps or the number of required control pins. Experimental evaluations demonstrate the benefits of the solution, i.e., the applicability for a wide range of design tasks as well as improvements compared to specialized solutions presented in the past.