Title :
A microbubble-powered bioparticle actuator
Author :
Maxwell, Rebecca Braff ; Gerhardt, Antimony L. ; Toner, Mehmet ; Gray, Martha L. ; Schmidt, Martin A.
Author_Institution :
Dept. of Mech. Eng., MIT, Cambridge, MA, USA
Abstract :
We present the results of a device that uses controllable microbubble actuation to manipulate bioparticles. In order to create a useful device for controlling the position of bioparticles, predictable microfluidic actuation is crucial. The goal of this project was to develop fundamental technology that can be used to manipulate single bioparticles (e.g., cells). We use a thermal bubble actuation method to accomplish this goal. Microbubbles have the advantages of relatively simple electronics and fabrication but can be difficult to control. In this paper, we describe two specific accomplishments: the use of micromachined nucleation cavities to precisely localize thermal bubbles and to achieve controllable bubble formation temperatures and bubble dissipation and the demonstration of controllable microbubbles in a new device for particle sorting.
Keywords :
biological techniques; bubbles; microactuators; microfluidics; micromanipulators; resistance heating; silicon; MEMS; Pt-SiO2; Si; Si bioparticle manipulation layer fabrication process; biological cells; bubble chambers; controllable bubble dissipation; controllable bubble formation temperatures; controllable microbubble actuation; controllable microbubbles; microbubble-powered bioparticle actuator; micromachined nucleation cavities; particle sorting; predictable microfluidic actuation; resistance heating; single bioparticle manipulation; thermal bubble actuation method; Actuators; Biomembranes; Fabrication; Laboratories; Materials science and technology; Microelectromechanical devices; Microfluidics; Sorting; Temperature control; Thermal expansion;
Journal_Title :
Microelectromechanical Systems, Journal of
DOI :
10.1109/JMEMS.2003.818457
