A new CMOS/microfluidic interface for cells manipulation and separation in LoC devices

Proceedings of the 2nd Asia Symposium on Quality Electronic Design, ASQED 2010

Volumn , Issue , 2010, Pages 194-197

  Miled, Mohamed Amine ^a   Sawan, Mohamad ^a  

^a ÉCOLE POLYTECHNIQUE DE MONTRÉAL   (Canada)

Author keywords

Cells detection; Cells manipulation; CMOS; Lab on chip; Microfluidics

Indexed keywords

CAPACITIVE DETECTION; CAPACITIVE MEASUREMENTS; CMOS; DIELECTROPHORETIC MANIPULATION; FULLY INTEGRATED; HIGH SENSITIVITY; LAB-ON-CHIP; TUNABLE FREQUENCY;

FREQUENCY BANDS; MICROELECTRONICS;

MICROFLUIDICS;

EID: 77956523661     PISSN: None     EISSN: None     Source Type: Conference Proceeding    
DOI: 10.1109/ASQED.2010.5548238     Document Type: Conference Paper

References (9)

1. F. Gielen, A. J. deMello, T. Cass, and J. B. Edel, "Increasing the trapping efficiency of particles in microfluidic planar platforms by means of negative dielectrophoresis," J. Phys. Chem. B, vol.113, no.5, pp. 1493-1500, Jan. 2009.
2. G. Medoro, C. Nastruzzi, R. Guerrieri, R. Gambari, and N. Manaresi, "Lab on a chip for live-cell manipulation," IEEE Des. Test of Comput., vol.24, no.1, pp. 26-36, Jan. 2007.
3. N. Manaresi, A. Romani, G. Medoro, L. Altomare, A. Leonardi, M. Tartagni, and R. Guerrieri, "A cmos chip for individual cell manipulation and detection," Solid-State Circuits, IEEE Journal of, vol.38, no.12, pp. 2297-2305, Dec. 2003.
4. M. Miled and M. Sawan, "Reconfigurable dielectrophoretic device for neurotransmitters sensing and manipulation," in IEEE Int. Mixed-Signals, Sensors, and Syst. Test Workshop, IMS3TW '09, Jun. 2009, pp. 1 -4.
5. W. Zhan, J. Alvarez, L. Sun, and R. M. Crooks, "A multichannel microfluidic sensor that detects anodic redox reactions indirectly using anodic electrogenerated chemiluminescence," Analytical Chemistry, vol.75, no.6, pp. 1233-1238, 2003. [Online]. Available: http://pubs.acs.org/doi/abs/10.1021/ ac026294j (Pubitemid 36397152)
6. E. Ghafar-Zadeh, M. Sawan, and D. Therriault, "A 0.18-[mu]m cmos capacitive sensor lab-on-chip," Sensors and Actuators A: Physical, vol.141, no.2, pp. 454 - 462, 2008.
7. -, "Novel direct-write cmos-based laboratory-on-chip: Design, assembly and experimental results," J. Sensors and Actuators A: Physical, vol.134, no.1, pp. 27 - 36, 2007.
8. E. Ghafar-Zadeh and M. Sawan, "A hybrid microfluidic/cmos capacitive sensor dedicated to lab-on-chip applications," Biomedical Circuits and Systems, IEEE Transactions on, vol.1, no.4, pp. 270-277, Dec. 2007.
9. X. Wang, X.-B. Wang, F. F. Becker, and P. R. C. Gascoyne, "A theoretical method of electrical field analysis for dielectrophoretic electrode arrays using green's theorem," J. Physics D: Applied Physics, vol.29, no.6, pp. 1649-1660, 1996.