Nerve cell ensembles growing in culture on microelectrode arrays allow long-term, multisite monitoring of spontaneous and evoked action potential (spike) activity. These ensembles generate complex spatio-temporal spike patterns and constitute evolving non-linear and non-station-ary dynamical systems. They provide effective platforms for observations of the "internal dynamics" of neuronal networks, especially pattern generation and the evolution of network organization. Nerves cells in cultures form many small neuronal clusters (termed nacelles) in which substantial membrane contact is achieved. We propose that such morphological clusters generate subthreshold interactions that can lead to noise-induced membrane potential oscillations with frequent ignition to spiking. Recruitment of several nacelles and dispersed neurons then leads to dynamically organized circuits capable of reliably generating and maintaining a specific burst pattern. The observed coexistence of different burst patterns suggests network substructures (circuits) with autonomous activity. Entrainment of all circuits to a global pattern is thought to represent a network "decision state" with automatic fault-tolerant output. Such phenomena suggest that not only the redundancy of connections but also the form of the message are important factors in the creation of fault-tolerance.
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References
1.
Arbib, M. A. , Erdi, P. and J. Szentagothai.1998. Neural Organization. MIT Press, Cambridge MA.
2.
Braitenberg V and A. Schiitz.1991. Anatomy of the Cortex, Springer.
3.
Cohen, A. H. , Rossignol, S. and S. Grillner.1988. Neural Control of Rhythmic Movements in Vertebrates. J. Wiley & Sons, New York.
4.
De la Prida L. M. , N. Stollenwerk, and J. V Sanches-Andreas.1997. Bursting as a source of predictability in biological neural network activity. Physica D110:323-331.
5.
Douglas, R. J. , Koch, C., Mahowald, M., Martin, C.A.C., and H. H. Suarez.1995. Recurrent excitation in neocortical circuits. Science269:981-985.
6.
Edelman, G. M.1987. Neural Darwinism. Basic Books Inc., N.Y.
7.
Freeman, W J.1975. Mass Action in the Nervous System. Academic Press, New York.
8.
Freeman, W J.1992. Neural networks and chaos. INNS Above Threshold1(3):8-10
9.
Gerstein, G. L. and M. R. Turner.1990. Neural assemblies as building blocks of cortical computation. In: Computational Neuroscience, E. L. Schwartz, ed., MIT Press, Cambridge, Mass., pp. 179-191.
10.
Gopal, K. V and G. W Gross.1996b. Auditory cortical neurons in vitro: Initial pharmacological studies. Acta Otolaryngologica, 116:697-704.
11.
Gross, G. W. and J. M. Kowalski.1991. Experimental and theoretical analysis of random nerve cell network dynamics. In P. Antognetti, & V Milutinovic (eds.), Neural Networks: Concepts, Applications, and Implementations, Vol. 4 Prentice Hall, Englewood, N.J. (pp. 47-110).
12.
Gross, G. W , Rhoades, B. K. and R. J. Jordan.1992. Neuronal networks for biochemical sensing. Sensors and Actuators6:1-8.
13.
Gross, G. W , Rhoades, B. K., Reust, D. L. and F. U. Schwalm.1993. Stimulation of monolayer networks in culture through thin film indium-tin oxide recording electrodes. J Neurosci Meth50:131-143.
14.
Gross, G. W and F. U. Schwalm. 1994. A closed chamber for long-term electrophysiological and microscopical monitoring of monolayer neuronal networks. J. Neurosci. Meth.52:73-85.
15.
Gross, G. W1994. Internal dynamics of randomized mammalian neuronal networks in culture. In: D. A. Stenger, & T. M. McKenna (eds.) Enabling Technologies for Cultured Neural Networks. Academic Press, N.Y. (pp. 277-317).
16.
Gross, G. W , A. Harsch, B. K. Rhoades, and W Goepel (1997) Odor, drug, and toxin analysis with neuronal networks in vitro: extracellular array recording of network responses. Biosensors & Bioelectronics12:373-393.
17.
Gross, G. W. and J.M. Kowalski.1998. In: Computing Anticipatory Systems (D.M. Dubois, ed.). AIP Conf. Proc437:577-594.
18.
Gross, G. W , J. M. Kowalski, and B.K. Rhoades.1999. Spontaneous and evoked oscillations in cultured mammalian neuronal networks. In: Oscillations in Neural Systems (D. Levine, V Brown, T. Shirey, eds). Erlbaum Associates, New York. pp 3-29.
19.
Habets, A. M. M. , A. M. J. Van Dongene, E Van Huizen, and M. A. Corner.1987. Spontaneous neuronal firing patterns in fetal rat cortical networks during development in vitro: A quantitative analysis. Exp. Brain Res.69:43-52.
20.
Hooper S. L. and M. Moulins.1989. Switching of a neuron from one network to another by sensory-induced changes in membrane properties. Science244:187-189.
21.
Hubel D. H. and T. N. Wiesel.1962. Receptive fields, binocular interaction and functional architecture in the cat's striate cortex. J Physiol (London) 160:106-154.
22.
Kim, C. and K.D. Wise.1996. A 64-site multishank CMOS low profile neural stimulating probe. IEEE Journal of Solid State Circuits31:1230-1238.
23.
Kowalski, J. M. , Albert, G. L., Rhoades, B. K. and G. W Gross.1992. Neuronal networks with spontaneous, correlated bursting activity: theory and simulations. Neural Networks, 5:805-822.
24.
Kuperstein, M. and D. A. Whittington.1981. A practical 24-channel microelectrode for neural recording in vivo. IEEE Transact. Biomed. Eng.BME-28:288-293.
25.
Levitan, I. B. and L. K. Kaczmarek.1991. The Neuron: Cell and Molecular Biology. Oxford University Press, N.Y., Ch 16.
26.
Lisman, J. E.1997. Bursts as a unit of neural information: making unreliable synapses reliable. TINS20 (1):38-43.
27.
MacGregor, R. J.1993. Theoretical Mechanics of Biological Neural Networks. Academic Press, Boston, pg 206-206.
28.
Mead, C.1990. Neuromorphic electronic systems. Proc. IEEE78:1629-1636
29.
Mitchison, G.1992. Axonal trees and cortical architecture. Trends in Neurosci15:122-126.
30.
Montoro, R. J. , Lopez-Barneo, J., and Jassik-Gerschenfeld, D. (1988) Differential burst firing modes in neurons of the mammalian visual cortex in vitro. Brain Res.460:168-172.
31.
Mountcastle, V B.1957.Modalities and typographic properties of single neurones of the cat's sensory cortex. J. Neurophysiol. 20:408-434.
32.
Mountcastle, V B.1982. An organizing principle for cerebral function: The unit module and the distributed system. In "The Mindful Brain" (H.O. Schmitt, ed.) MIT Press, Cambridge, MA.
33.
Najafi, J. JI. K. and K. D. Wise.1990. A scaled electronically-configurable multichannel recording array. Sensors and ActuatorsA21-A23:589-591.
34.
Palm, M.1981. Evidence, information, and surprise. Biol. Cybernet. 42:57-68
35.
Provine, R. R.1971. Embryonic spinal cord: synchrony and spatial distribution of polyneuronal burst discharges. Brain Res.29, 155-158.
36.
Provine, R. R. and L. Rogers.1977. Development of spinal cord bioelectric activity in spinal chick embryos and its behavioral implications. J Neurobiol. 8, 217-228.
37.
Rhoades, B. K. and G. W. Gross.1994. Potassium and calcium channel dependence of bursting in cultured neuronal networks. Brain Res.643:310-318.
38.
Simmers, J. , Meyrand, P. and M. Moulins.1995. Dynamic network of neurons. American Scientists83:262-268.
39.
Sporns, O. , Tononi, G. and G. M. Edelman.1991. Modeling perceptual grouping and figure-ground segregation of means of active re-entrant connections. PNAS88:129-133.
40.
Sporns, O. , Gally, J. A., Reeke, G. N. Jr. and G. M. Edelman.1989. Reentrant signaling among simulated neuronal groups leads to coherency in their oscillations. Proc. Natl. Acad. Sci.86:
41.
Szentagothai, J.1975. The module concept in cerebral cortex architecture. Brain Research95:475-496.
42.
Takens, F1981. Detecting strange attractors in turbulence. In D. A. Rand and L.-S. Young (eds) Dynamical Systems and Turbulence, Lecture Notes in Mathematics Vol. 898, Springer Verlag, pp 366-381.
43.
Wise, K. D. and J. B. Angell.1975. A low capacitance multielectrode probe for use in extracellular neurophysiology. IEEE Transact. Biomed. Eng., BME 22:212-219.
44.
Zucker, R. S.1988. Frequency dependent changes in excitatory synaptic efficacy. In <btl>"Mechanisms of Epileptogenesis"</btl> (M. A. Dichter ed.) pp 153-157. Plenum Press, New York.
