1 |
Shepherd, G. Introduction to Synaptic Circuits in the Synaptic Organization of the Brain. Oxford University Press 5th edition (2004).
|
2 |
Parker, A.C., Friesz, A.K. & Pakdaman, A. Towards a Nanoscale Artificial Cortex. Proceedings of International Conference on Computing in Nanotechnology (CNAN'06), 26-29 (2006).
|
3 |
Fatoorechi, M. et al. A comparative study of electrical potential sensors and Ag/AgCl electrodes for characterizing spontaneous and event related electroencephalogram signals. J. Neurosci. Methods. 251, 7-16 (2015).
DOI
|
4 |
Guermandi, M., Cardu, R., Scarselli, E.F. & Guerrieri, R. Active electrode IC for EEG and electrical impedance tomography with continuous monitoring of contact impedance. IEEE Trans. Biomed. Circuits Syst. 9, 21-33 (2015).
DOI
|
5 |
Lopez, C.M. et al. An implantable 455-active-electrode 52-channel CMOS neural probe. IEEE J. Solid-State Circuits. 49, 248-261 (2014).
DOI
|
6 |
Chen, W.M. et al. A fully integrated 8-channel closedloop neural-prosthetic CMOS SOC for real-time epileptic seizure control. IEEE J. Solid-State Circuits. 49, 232-247 (2014).
DOI
|
7 |
Barsakcioglu, D.Y. et al. An analogue front-end model for developing neural spike sorting systems. IEEE Trans. Biomed. Circuits Syst. 8, 216-227 (2014).
DOI
|
8 |
Demosthenous, A., Pachnis, I., Jiang, D. & Donaldson, N. An integrated amplifier with passive neutralization of myoelectric interference from neural recording tripoles. IEEE Sens. J. 13, 3236-3248 (2013).
DOI
|
9 |
Chi, Y.M., Jung, T.P. & Cauwenberghs, G. Dry-contact and noncontact biopotential electrodes: Methodological review. IEEE Rev. Biomed. Eng. 3, 106-119 (2010).
DOI
|
10 |
Nelson, M.J. Review of signal distortion through metal microelectrode recording circuits and filters. J. Neurosci. Methods. 169, 141-157 (2008).
DOI
|
11 |
Mohseni, P. & Najafi, K. A fully integrated neural recording amplifier with DC input stabilization. IEEE Trans. Biomed. Eng. 51, 832-837 (2004).
DOI
|
12 |
Steyaert, M.S.J. & Sansen, W.M.C. A micropower low-noise monolithic instrumentation amplifier for medical purposes. IEEE J. Solid-State Circuits. 22, 1163-1168 (1987).
DOI
|
13 |
Wattanapanitch, W., Fee, M. & Sarpeshkar, R. An energy-efficient micro power neural recording amplifier. IEEE Trans. Biomed. Circuits Syst. 1, 136-147 (2007).
DOI
|
14 |
Zhang, F., Holleman, J. & Otis, B. Design of ultra-low power bio-potential amplifiers for bio-signal acquisition applications. IEEE Trans. Biomed. Circuits Syst. 6, 344-355 (2012).
DOI
|
15 |
Song, S. et al. A low-voltage chopper-stabilized amplifier for fetal ECG monitoring with a 1.41 power efficiency factor. IEEE Trans. Biomed. Circuits Syst. 9, 237-247 (2015).
DOI
|
16 |
Toth, L. & Tsividis, Y. Generalization of the principle of chopper stabilization. IEEE Trans. Circuits Syst. I, Fundam. Theory. 50, 975-983 (2003).
DOI
|
17 |
Spinelli, E., Haberman, M., Garcia, P. & Guerrero, F. A capacitive electrode with fast recovery feature. Physiol. Meas. 33, 1277-1288 (2012).
DOI
|
18 |
Javey, A. et al. Ballistic carbon nanotubes transistors. Nature 424, 654-657 (2003).
DOI
|
19 |
Franklin, A.D. & Chen, Z. Length scaling of carbon nanotube transistors. Nat. Nanotechnol. 5, 858-862 (2010).
DOI
|
20 |
Kim, Y.B. Integrated circuit design based on carbon nanotube field effect transistor. Trans. Electr. Electron. Mater. 12, 175-188 (2011).
DOI
|
21 |
Chi, Y.M., Maier, C. & Cauwenberghs, G. Ultra-high input impedance, low noise integrated amplifier for noncontact biopotential sensing. IEEE J. Emerging Sel. Top. Circuits Syst. 1, 526-535 (2011).
DOI
|