Design strategies for multi-channel low-noise recording systems

Analog Integrated Circuits and Signal Processing

Volumn 58, Issue 2, 2009, Pages 123-133

  Rieger, Robert ^a   Taylor, John T ^b  

^a NATIONAL SUN YAT SEN UNIVERSITY   (Taiwan)

^b University of Bath   (United Kingdom)

Author keywords

Bipolar design; CMOS design; Multi channel recording; Noise efficiency; Offset voltage

Indexed keywords

DATA COMPRESSION; IMPLANTS (SURGICAL); INTEGRATED CIRCUITS; INTEGRATED OPTICS; INTERFACES (COMPUTER); RECORDING INSTRUMENTS;

BIPOLAR DESIGN; CMOS DESIGN; MULTI-CHANNEL RECORDING; NOISE EFFICIENCY; OFFSET VOLTAGE;

DESIGN;

EID: 58149494385     PISSN: 09251030     EISSN: 15731979     Source Type: Journal    
DOI: 10.1007/s10470-008-9230-5     Document Type: Article

References (56)

1. B Popovic RB Stein 1993 Sensory nerve recording for closed-loop control to restore motor functions IEEE Transactions on Biomedical Engineering 40 10 1024 1031
2. MA Lebedev MAL Nicolelis 2006 Brain-machine interfaces: Past, present and future Trends in Neuroscience 29 9 536 546
3. R Rieger M Schuettler D Pal C Clarke P Langlois J Taylor N Donaldson 2006 Very low-noise eng amplifier system using CMOS technology IEEE Transactions on Neural Systems and Rehabilitation Engineering 14 4 427 437
4. RR Harrison C Charles 2003 A low-power low-noise CMOS amplifier for neural recording applications IEEE Journal of Solid-State Circuits 38 6 958 965
5. W Dabrowski P Grybos 2003 Development of integrated circuits for readout of microelectrode arrays to image neuronal activity in live retinal tissue IEEE Nuclear Science Symposium Conference Record 2 956 960
6. Sacristan, J., & Oses, T. (2004). Low noise amplifier for recording ENG signals in implantable systems. In Proc. IEEE ISCAS 2004, Vol. IV, pp. 33-36.
7. W Dabrowski P Grybos AM Litke 2004 A low noise multichannel integrated circuit for recording neuronal signals using microelectrode arrays Biosensors & Bioelectronics 19 749 761
8. P Mohseni K Najafi 2004 A fully integrated neural recording amplifier with DC input stabilization IEEE Transactions on Biomedical Engineering 51 5 832 837
9. MA Obeid L Nicolelis PD Wolf 2004 A low power multichannel analog front end for portable neural signal recordings Journal of Neuroscience Methods 133 27 32
10. Valchinov, S., & Pallikarakis, N. E. (2004). An active electrode for biopotential recording from small localized bio-sources. BioMedical Engineering OnLine, 3, 25.
11. X Uranga NB Navarro 2004 Integrated CMOS amplifier for ENG signal recording IEEE Transactions on Biomedical Engineering 51 12 2188 2194
12. JJ Pancrazio PP Bey Jr 1998 Description and demonstration of a CMOS amplifier-based-system with measurement and stimulation capability for bioelectrical signal transduction Biosensors & Bioelectronics 13 971 979
13. DT Kewley MD Hills 1997 Plasma-etched neural probes Sensors and Acuators 58 27 35
14. R Martins S Selberherr FA Vaz 1998 A CMOS IC for portable EEG acquisition system IEEE Transactions on Instrumentation and Measurement 47 5 1191 1196
15. J Ji KD Wise 1992 An implantable CMOS circuit interface for multiplexed microelectrode recording arrays IEEE Journal of Solid-State Circuits 27 3 433 443
16. Q Bai KD Wise 2001 Single-unit neural recording with active microelectrode arrays IEEE Transactions on Biomedical Engineering 48 8 911 920
17. Chan, P. K., Ng, K. A., & Zhang, X. L. (2004). A CMOS chopper-stabilized differential amplifier for biomedical integrated circuits. In Proc. 47th Int. Midwest Symp. Circuits and Systems, Vol. III, pp. 33-36.
18. Dagtekin, M., Liu, W., & Bashirullah, R. (2001). A multi channel chopper modulated neural recording system. In Proc. 23rd Annual EMBS International Conference, pp. 757-760.
19. Nielsen, J. H., & Lehmann, T. (2001). An implantable CMOS amplifier for nerve signals. In Proc. 8th IEEE Conf. Electronic Circuits and Systems (ICECS), Vol. 3, pp. 1183-1186.
20. Uranga, N. Lago, X., & Navarro, N. B. (2004). A low noise CMOS amplifier for ENG signals. In Proc. ISCAS, Vol. IV, pp. 1-14.
21. Olsson, R. H. III, Gulari, M. N., & Wise K. D. (2003). A fully-integrated bandpass amplifier for extracellular neural recording. In Proc. 1st IEEE EMBS Conf. Neural Engineering, pp. 165-168.
22. C van Metting Rijn A Peter CA Grimbergen 1990 Design of high quality miniature bioelectric amplifiers in thick film technology Proceedings of the 12th Annual International Conference on IEEE EMBS 12 3 1066 1067
23. Sansen, W., Steyaert, M., & Halonen, K. (1988). Micropower monolithic data-acquisition system. Digest of Technical Papers of ISSCC, pp. 256-257, 1988.
24. Steyaert, M. S. J., & Sansen, W. M. C. (1987). A micropower low-noise monolithic instrumentation amplifier for medical purposes. IEEE Journal of Solid-State Circuits, SC-22(6), 1163-1168.
25. Dorman, M. G., Prisbe, M. A., & Meindl, J. D. (1985). A monolithic signal processor for a neurophysiological telemetry system. IEEE Journal of Solid-State Circuits, SC-20(6), 1185-1192.
26. Chen, D., Harris, J. G., & Principe, J. C. (2004). A bio-amplifier with pulse output. In Proc. 26th Annual Int. Conf. EMBS, pp. 4071-4074.
27. Degrauwe, M., Vittoz, E., & Verbauwhede, I. (1985). A micropower CMOS-instrumentation amplifier. IEEE Journal of Solid-State Circuits, SC-20(3), 805-807.
28. R Rieger J Taylor 2003 Design of a low-noise preamplifier for nerve cuff electrode recordings IEEE Journal of Solid-State Circuits 38 8 1373 1379
29. Rieger, R., Pal, D. et al. (2005). 10-channel very low noise ENG amplifier system using CMOS technology. In Proc. ISCAS 05, Vol. 1, pp. 748-751.
30. Najafi, K., & Wise K. D. (1986). An implantable multielectrode array with on-chip signal processing. IEEE Journal of Solid-State Circuits, SC-21(6), 1035-1044.
31. Yazicioglu, R. F., Merken, P., Puers, R., & van Hoof, C. (2007). A 60 μW 60nV/Hz readout front-end for portable biopotential acquisition systems. IEEE JSSC, 42(5), 1100-1110.
32. Y Perelman R Ginosar 2007 An integrated system for multichannel neuronal recording with spike/LFP separation, integrated A/D conversion and threshold detection IEEE Transactions on Biomedical Engineering 54 1 130 137
33. S Fuchs DS Vogel 2002 Universal application-specific integrated circuit for bioelectric data acquisition Medical Engineering & Physics 24 695 701
34. Y Harb MS Hu A Abdelkerim MM Elhilali 2004 Low-power CMOS interface for recording and processing very low amplitude signals Analog Integrated Circuits & Signal Processing 39 39 54
35. Ananth, R. S., Lee, E. K., Li, T., & Lam, A. (2006). Low-power, implantable sensing system for signal detection from the central or peripheral nervous system. In Proc. ISCAS'06, pp. 2573-2576.
36. Perlin, E., Sodagar, A. M., & Wise, A. M. (2006). Neural recording front-end designs for fully implantable neuroscience applications and neural prosthetic microsystems. In Proc. 28th IEEE EMBS Annual Internat. Conf., pp. 2982-2985.
37. M Mojarradi D Binkley B Blalock R Andersen N Ulshoefer T Johnson L Del Castillo 2003 A miniaturized neuroprosthesis suitable for implantation into the brain IEEE Transactions on Neural Systems & Rehabilitation Engineering 11 1 38 42
38. Mohseni, P., & Najafi, K. (2005). A battery-powered 8-channel wireless FM IC for biopotential recording applications. In Proc. ISSCC 2005, pp. 560-617.
39. Donaldson, N. de N., Zhou, L., Perkins, T. A., Munih, M., Haugland, M., & Sinkjaer, T. (2003). Implantable telemeter for long-term electroneurographic recordings in animals and humans. Medical & Biological Engineering & Computing, 41(6), 654-664.
40. Pal, J. T., Rieger, R., & Langlois, P. (2006). Two preamplifiers for non-invasive on-chip recording of neural signals. In Proc. IEEE ISCAS '05, pp. 2727-2730.
41. Aziz, J. N. Y., Genov, R., Bardakjian, B. L., Derchansky, M., & Carlen, P. L. (2007). Brain-silicon interface for high-resolution in vitro neural recording. IEEE Transactions on Biomedical Circuits and Systems, 1(1), 56-62.
42. J Taylor N Donaldson J Winter 2004 Multiple-electrode nerve cuffs for low-velocity and velocity-selective neural recording Medical & Biological Engineering & Computing 42 5 634 643
43. S Solis-Bustos J Silva-Martinez F Maloberti E Sanchez-Sinencio 2000 A 60-dB dynamic-range CMOS sixth-order 2.4-Hz low-pass filter for medical applications IEEE Transactions on Analog and Digital Signal Processing 47 12 1391 1398
44. Fischer, J. H. (1982). Noise sources and calculation techniques for switched capacitor filters. IEEE JSSC, SC-17(4), 742-752.
45. I Obeid JC Morizio KA Moxon MAL Nicolelis PD Wolf 2003 Two multichannel integrated circuits for neural recording and signal processing IEEE Transactions on Biomedical Engineering 50 2 255 258
46. Jolly, R. D., & McCharles, R. H. (1982). A low-noise amplifier for switched capacitor filters. IEEE JSSC, SC-17(6), 1192-1194.
47. C Menolfi Q Huang 1997 A low-noise CMOS instrumentation amplifier for thermoelectric infrared detectors IEEE JSSC 32 7 968 976
48. J Hauptmann F Dielacher R Steiner CC Enz F Krummenacher 1992 A low-noise amplifier with automatic gain control and anticlipping control in CMOS technology IEEE JSSC 27 7 974 981
49. Kerns, D., Troyk, P., & DeMichele, G. (2006). A monolithic multi-channel amplifier for electrode arrays. In Proc. 28th IEEE EMBS Annual Int. Conf., pp. 2978-2981.
50. Ananth, R. S., & Lee, E. K. (2004). Design of a low-power, implantable electromyogram amplifier. In Proc. ISCAS, Vol. IV, pp. 9-12.
51. JH Nielsen T Lehmann 2003 An implantable CMOS amplifier for nerve signals Analog Integrated Circuits and Signal Processing 36 153 164
52. Nielsen, J. H., & Bruun, E. (2004). A low-power CMOS front-end for cuff-recorded nerve signals. In Proc. Norchip Conference, pp. 24-27.
53. Denison, T., Consoer, K., Kelly, A., Hachenburg, A., & Santa, W. (2007). A 2.2 μW 94nV/Hz, chopper-stabilized instrumentation amplifier for EEG detection in chronic implants. In Proc. ISSCC, pp. 162-163 and 594.
54. Enz, C. C., & Vittoz, E. A. (2006). Charge-based MOS transistor modeling. Wiley.
55. Johns, A., & Martin, K. (1997). Analog integrated circuit design. Wiley.
56. Rieger, R., Pan, Y.-Y., & Taylor, J. (2007). Design strategies for multi-channel low-noise recording systems. In Proc. ISCAS, pp. 561-564.