IJTAG-Based Fault Recovery and Robust Microelectrode-Cell Design for MEDA Biochips

Abstract

A digital microfluidic biochip (DMFB) is an attractive platform for immunoassays, point-of-care clinical diagnostics, DNA sequencing, and other laboratory procedures in biochemistry. A recent generation of biochips uses a micro-electrode-dot-array (MEDA) architecture, which provides fine-grained controllability of droplets and seamlessly integrates microelectronics and microfluidics using CMOS technology. In order to ensure robust fluidic operations and high confidence in the outcome of biochemical experiments, chip testing, fault diagnosis, and fault recovery are critical for MEDA biochips. In this article, we present an effective fault-recovery solution based on the homogeneous structure of MEDA. Since the microelectrode cells (MCs) in an MEDA biochip are identical, we add multiplexers for reconfigurability, whereby an MC with faulty components can use the hardware resources in a neighboring MC. In addition, we use the IEEE 1687 (also known as IJTAG) network to reduce the number of control signals needed for the multiplexers, and to provide flexible subscan chain access for the fault-recovery control flow. A comprehensive set of simulation results demonstrates the effectiveness of the proposed fault-recovery solution for MEDA biochips.