Biomedical Engineering Reference
In-Depth Information
9. Fair, R. B., V. Srinivasan, H. Ren, P. Paik, V. K. Pamula, and M. G. Pollack,
Electrowetting-based on-chip sample processing for integrated microfluidics,
Proceeding of IEEE International Electron Devices Meeting (IEDM)
, pp. 32.5.1-32.5.4,
2003.
10. Pollack, M. G., R. B. Fair, and A. D. Shenderov, Electrowetting-based actuation
of liquid droplets for microfluidic applications,
Applied Physics Letters
, vol. 77,
no. 11, 2000.
11. Cho, S. K., H. Moon, and C.-J. Kim, Creating, transporting, cutting, and merg-
ing liquid droplets by electrowetting-based actuation for digital microfluidic
circuits,
Journal of Microelectromechanical Systems
, vol. 12, no. 1, pp. 70-80, 2003.
12. Abdelgawad, M. and A. R. Wheeler, Rapid prototyping in copper substrates for
digital microfluidics.
Advanced Material
, vol. 19, pp. 133-137, 2007.
13. Fair, R. B., A. Khlystov, T. D. Tailor, V. Ivanov, R. D. Evans, P. B. Griffin,
V. Srinivasan, V. K. Pamula, M. G. Pollack, and J. Zhou, Chemical and biological
applications of digital-microfluidic devices,
IEEE Design and Test of Computers
,
vol. 24, pp. 10-24, 2007.
14. Su, F. and K. Chakrabarty, High-level synthesis of digital microfluidic biochips,
ACM Journal on Emerging Technologies in Computing Systems
, vol. 3, Article 16,
January 2008.
15. Su, F. and K. Chakrabarty, Unified high-level synthesis and module place-
ment for defect-tolerant microfluidic biochips,
Proceeding of IEEE/ACM Design
Automation Conference
, pp. 825-830, 2005.
16. Yuh, P.-H., C.-L. Yang, and C.-W. Chang, Placement of defect-tolerant digital
microfluidic biochips using the T-tree formulation,
ACM Journal on Emerging
Technologies in Computing Systems
, vol. 3, issue 3, 2007.
17. Ricketts, A. J., K. Irick, N. Vijaykrishnan, and M. J. Irwin, Priority scheduling in
digital microfluidics-based biochips,
Proceeding of IEEE Design, Automation and
Test in Europe (DATE) Conference
, pp. 329-334, 2006.
18. Pfeiffer, J., T. Mukherjee, and S. Hauan, Synthesis of multiplexed biofluidic
microchips,
IEEE Transactions on Computer-Aided Design of Integrated Circuits and
Systems
, vol. 2, pp. 321-333, 2006.
19. International Technology Roadmap for Semiconductors,
http://public.itrs.net/
20. Su, F., Synthesis, Testing, and Reconfiguration Techniques for Digital Microfluidic
Biochips, Ph.D. thesis, Duke University, Durham, NC, 2006.
21. Chen, X., D. F. Cui, C. Liu, H. Li, and J. Chen, Continuous flow microfluidic
device for cell separation, cell lysis and DNA purification,
Analytica Chimica
Acta
, vol. 584, pp. 237-243, 2007.
22. Pollack, M. G., R. B. Fair, and A. D. Shenderov, Electrowetting-based actuation
of liquid droplets for microfluidic applications,
Applied Physics Letters,
vol. 77,
pp. 1725-1726, 2000.
23. Srinvasan, V., V. K. Pamula, and R. B. Fair, Droplet-based microfluidic lab-on-
a-chip for glucose detection,
Analytica Chimica Acta
, vol. 507, no. 1, pp. 145-150,
2004.
24. Advanced Liquid Logic, Inc.,
http://www.liquid-logic.com
. (for general refer-
ence; not cited in text.)
25. Gong, J. and C. J. Kim, Two-dimensional digital microfluidic system by multi-
layer printed circuit board,
Proceeding of IEEE MEMS
, pp. 726-729, 2005.
