Fabricating a dielectrophoretic microfluidic device using 3D-printed moulds and silver conductive paint

Dielectrophoresis is an electric field-based technique for moving neutral particles through a fluid. When used for particle separation, dielectrophoresis has many advantages compared to other methods, like providing label-free operation with greater control of the separation forces. In this paper, we design, build, and test a low-voltage dielectrophoretic device using a 3D printing approach. This lab-on-a-chip device fits on a microscope glass slide and incorporates microfluidic channels for particle separation. First, we use multiphysics simulations to evaluate the separation efficiency of the prospective device and guide the design process. Second, we fabricate the device in PDMS (polydimethylsiloxane) by using 3D-printed moulds that contain patterns of the channels and electrodes. The imprint of the electrodes is then filled with silver conductive paint, making a 9-pole comb electrode. Lastly, we evaluate the separation efficiency of our device by introducing a mixture of 3 mu m and 10 mu m polystyrene particles and tracking their progression. Our device is able to efficiently separate these particles when the electrodes are energized with +/- 12 V at 75 kHz. Overall, our method allows the fabrication of cheap and effective dielectrophoretic microfluidic devices using commercial off-the-shelf equipment.

Automated summary

Dielectrophoresis is a technique that uses an electric field to manipulate neutral particles in a fluid. This paper presents the design, fabrication, and testing of a low-voltage dielectrophoretic device using 3D printing. The device, which fits on a microscope glass slide, incorporates microfluidic channels for particle separation. The authors demonstrate the separation efficiency of the device by introducing a mixture of polystyrene particles and tracking their progression under specific electric field conditions.