Bibliography provided by Adam Curtis - by Author

Bailey, F., Malinski, T., and Keichle, F. (1991). Carbon-fiber ultramicroelectrodes modified with conductive polymeric tetrakis (3-methoxy-4-hydroxyphenyl)porphyrin for determination of nickel in single biological cells . Analytical Chem. 63:395-398.

Boppart, S. A., Wheeler, B. C., and Wallace, C. S. (1992). A flexible perforated microelectrode array for extended neural recordings. Procs of Biomedical Engineering 39:37-41.

Clark, L. D., and Edell, D. J. (1967). Electrode spacing considerations for neural signal transducers. In IEEE/Engineering in Medicine and Biology Society (Boston Park Plaza,) pg 1-2.

Cowan, J. D., and Sharp, D. H. (1988). Neural Nets . Quarterly Revs. of Phophysics 223:365-427.

De Castro, E. S., Huber, E. W., Villarroel, D., Galiatsatos, C., Mark, J. E., and Heineman, W. R. (1987). Electrodes with polymer network films formed by y-irradiation cross-linking . Analytical Chemistry 59:134-139.

Droge, M. H., Gross, G. W., Hightower, M. H., and Czisny, L. E. (1986). Multielectrode analysis of coordinated, multisite, rhythmic burstingin cultured CNS monolayer networks. J. Neurosci. 6:1583-1592.

Edell, D. J., Churchill, J. N., and Gourley, I. M. (1982). Biocompatibility of a silicon based peripheral nerve electrode . Biomat., Med. Dev., Art. Org. 10(2):103-122.

Frieswijk, T. A., Bielen, J. A., Rutten, W. L. C., and Bergveld, P. (1997). Development of a solder bump technique for contacting a three-dimensional multi electrode array. Microsystem Technologies, pg 48-52.

Fromherz, P. (1999). Extracellular recording with transistors and the distribution of ionic conductances in a cell membrane. European Biophysics Journal With Biophysics Letters 28:254-258.

Fromherz, P. (1996). Interfacing neurons and silicon by electrical induction. Berichte Der Bunsen-Gesellschaft-Physical Chemistry Chemical Physics 100:1093-1102.

Fromherz, P., Offenhausser, A., Vetter, T., and Weis, J. (1991). A neuron-silicon junction: A retzius cell of the leech on an insulated-gate field-effect transistor. Science 252:1290-1293.

Ganouni, S. E., Forni, C., and Nieoullon, A. (1987). In vitro and in vivo characterization of the properties of a multi- fiber carbon electrode allowing long-term electrochemical detection of dopamine in freely moving animals . Brain Res. 404:239-256.

Gross, G. W. (1979). Simultaneous single unit recording in vitro with a photoetched laserdeinsulated gold multimicroelectrode surface . IEEE Trans. on Biomed. Engineering BME-26No. 5:273-279.

Gross, G. W., and Lucas, J. H. (1982). Long-term monitoring of spontaneous single unit activity from neuronal monolayer networks cultured on photoetched multielectrode surfaces . J. Electrophysiol. Tech. 9:55-67.

Gross, G. W., Williams, A. N., and Lucas, J. H. (1982). Recording of spontaneous activity with photoetched microelectrode surfaces from spinal cord neurons in culture . J. Neurosc. Methods 5:13-22.

Israel, D. A., Barry, W. H., Edell, D. J., and Mark, R. G. (1984). An array of microelectrodes to stimulate and record from cardiac cells in culture . Am. J. Physio. 247, pg H669- H674 , 147-162.

Janossy, V., Lukacs, B., Racz, A., Bodocs, L., Gyevai, A., Szabo, I & Toth,A. (1991). Multichannel recordings and data analysis from spinal cord explants and cell cultures.: Central Res. Institute Physics, H-1525 Budapest

Jimbo, Y., and Kawana, A. (1990). Electrical stimulation of cultured neural cells by planar electrode array. In Annual International Conference of the IEEE Engineering in Medicine and Biology Society Tokyo, Japan, pg 1741-1742.

Jobling, D. T., Smith, J.G. & Wheal, H.V. (1981). Active microelectrode array to record from the mammalian central nervous system in vitro. 19:553-560.

Klingler, J., and Fromherz, P. (1995). Profiles of Voltage and of Channel Density in a Planar Membrane Cable On Micromachined Silicon. Berichte Der Bunsen-Gesellschaft-Physical Chemistry Chemical Physics 99:958-964.

Kowalski, J. M., Albert, G. L., and Gross, G. W. (1990). Asymptotically synchronous chaotic orbits in systems of excitable elements. Phys. Rev. A. 42:6260-6263.

Lind, R., Connolly, P., Wilkinson, C.D.W. & Thomson, R.D. (1991). Finite-element analysis applied to extracellular microelectrode design. Sensors & Actuators B. 3: 23-30.

Lind, R., Connolly, P., Wilkinson, C. D. W., Breckenridge, L. J., and Dow, J. A. T. (1991). Single cell mobility and adhesion monitoring using extracellular electrodes. Biosensors & Bioelectronics 6:359-367.

Martinoia, S., Bove, M., Carlini, G., Ciccarelli, C., Grattarola, M., Storment, C., and Kovacs, C. (1993). A general-purpose system for long-term recording from a microelectrode array coupled to excitable cells. J. Neuroscience Methods 48:115-121.

McClurkin, J. W., OPtican, L.M., Richmond, B.J. & Gawne, T.J. (1991). Concurrent processing and complexity of temporally encoded neuronal messages in visual perception. 253:653-677.

Mercer, H. D. W., R.L. (1978). Photolithographic fabrication and physyilogical performance of a microelectrode array for neuronal stimulation. 25:494-500.

Novak, J. L., , and Wheeler, B. C. (1986). Recording from the Aplysia abdominal ganglion with a planar micro- electrode array . IEEE Trans. on Biomedical Engineering BME-33No. 2:196-202.

O'Shea, P., Goodwin, B., and Ridge, I. (1990). A vibrating electrode anslysis of extracellular ion currents in Acetabularia acetabulum . J. Cell Sci. 97:503-508.

Optican, L. M., Gawne, T.J., Richmond, B.J. & Joseph, P.J. (1991). Unbiased measures of transmitted information and channel capacity from multivariate beuronal data. Biol. Cybern. to be disclosed.

Pickard, R. S. (1979). Printed circuit microelectrodes. TINS 2:259-261.

Pickard, R. S. W., T.R. (1976). Printed circuit microelectrodes and their application to honeybee brain. 64:39-44.

Pine, J. (1980). Recording action potentials from cultured neurons with extracellularmicrocircuit electrodes . J. of Neuroscience Methods 2:19-31.

Prohaska, O. J., Olcaytug, F., Pfundner, P., and Dragaun, H. (1986). Thin-film multiple electrode probes: possibilities and limitations . IEEE Trans. on Biomedical Engineering BME-33 2:223-229.

Regehr, W. G., Pine, J. & Rutledge, D.B. (1988). Long-term in vitro silicon-based microelectrode-neuron connection. 35:1023-1032.

Regehr, W. G., Pine, J., Cohen, C.S., Mischke, M.D. & Tank, D.W. (1989). Sealing cultured invertebrate neurons to embedded dish electrodes facilitates long-term stimulation and recording. J. Neurosci. Methods. 30:91-106.

Richmond, B. J., and Optican, L. M. (1987). Temporal encoding of two-dimensional patterns by single units in primate inferior temporal cortex. II. Quantification of response waveform. J. Neurophysiol. 57:147-161.

Tank, D. W., Cohan, C. S., and Kater, S. B. (1986). Cell body capping of array electrodes improves measurements of extracellular voltages in micro-cultures of invertebrate neurons . IEEE Conf. on Synthetic Microstructures (Virginia, U.S.A.) , pg 474-480.

Tank, D. W., and Kleinfeld, D. (1986). The relation between electrode placement and the amplitude of extra cellularly-recorded action potentials. Biophysical J. 49:474-480.

Thomas, J., C.A, Springer, P. A., Loeb, G. E., Berwald-Netter, Y., and Okun, L. M. (1972). A miniature microelectrode array to monitor the bioelectric activityof cultured cells . Exp. Cell Res. 74:61-66.

Wise, K. D., Angel, J.B. & Starr, A. (1970). An integrated circuit approach to extracellular microelectrodes. 17: 238-246.