This paper presents a schematic-based and system-oriented modeling and simulation framework to enable top-down designs of multifunctional biofluidic lab-on-a-chip systems. An analog hardware description language (Verilog-A) is used to integrate parameterized and closed-form models of elements with different functionalities (e.g., mixing, reaction, injection and separation). Both DC and transient analysis are performed on a practical competitive immunoassay chip to capture the influence of topology, element sizes, material properties and operational parameters on the chip performance. Accuracy (relative error generally less than 5%) and speedup (>100/spl times/) of the schematic-based simulation is obtained by comparison to continuum numerical simulation as well as experimental measurements. A redesign of the original LoC device using our framework to improve bio-analysis efficiency and minimize chip-area has been demonstrated.
[1]
Tamal Mukherjee,et al.
System-oriented dispersion models of general-shaped electrophoresis microchannels.
,
2004,
Lab on a chip.
[2]
Tamal Mukherjee,et al.
Microfluidic Injector Models Based On Neural Networks
,
2005
.
[3]
T. Mukherjee,et al.
A model for laminar diffusion-based complex electrokinetic passive micromixers.
,
2005,
Lab on a chip.
[4]
B. Mohammadi,et al.
Optimization of turn geometries for microchip electrophoresis
,
2001
.
[5]
S. Jacobson,et al.
Computer simulations of electrokinetic injection techniques in microfluidic devices
,
2000,
Analytical chemistry.
[6]
D. J. Harrison,et al.
Microchip systems for immunoassay: an integrated immunoreactor with electrophoretic separation for serum theophylline determination.
,
1998,
Clinical chemistry.