Inferring the Dynamics of “Hidden“ Neurons from Electrophysiological Recordings
Statistical analysis of electrophysiological recordings
obtained under, e.g. tactile, stimulation frequently suggests participation
in the network dynamics of experimentally unobserved “hidden"
neurons. Such interneurons making synapses to experimentally
recorded neurons may strongly alter their dynamical responses to
the stimuli. We propose a mathematical method that formalizes this
possibility and provides an algorithm for inferring on the presence
and dynamics of hidden neurons based on fitting of the experimental
data to spike trains generated by the network model. The model
makes use of Integrate and Fire neurons “chemically" coupled
through exponentially decaying synaptic currents. We test the method
on simulated data and also provide an example of its application to
the experimental recording from the Dorsal Column Nuclei neurons
of the rat under tactile stimulation of a hind limb.
[1] G. P. Moore, D. P. Perkel, and J. P. Segundo,"Statistical analysis and
functional interpretation of neural spike data". Annu Rev Physiol, vol.
28, pp. 493-522, 1966.
[2] D. H. Perkel, G. L. Gerstein, and G. P. Moore, "Neuronal spike trains
and stochastic point processes. II Simultaneous spike train". Biophys J,
vol. 7, pp. 419-440, 1967.
[3] E. R. Kandel, J. H. Schwartz, and T. M. Jessell, Principles of neural
science. 4th ed. New York: McGraw-Hill, 2000.
[4] F. Panetsos, A. Nunez, and C. Avendano, "Electrophysiological effects of
temporary differentiation on two characterized cell types in the nucleus
gracilis of the rat". Eur J Neurosci, vol. 9, pp. 563-572, 1997
[5] F. Panetsos, A. Nunez, C. Avendano, "Sensory information processing
in the dorsal column nuclei by neuronal oscillators". Neurosci, vol. 84,
pp. 635-639, 1998.
[6] A. Nunez, F. Panetsos, and C. Avendao."Rhythmic neuronal interactions
and synchronization in the rat dorsal column nuclei". Neurosci, vol. 100,
pp. 599-609, 2000.
[7] G. Gerstein, P. Bedenbaugh, and M. Aertse, "Neuronal assemblies".
IEEE Trans biomed engineering, vol. 36, no. 1, pp. 4-14, 1989.
[8] A. Aertsen and H. Preissl, Dynamics of activity and connectivity in
physiological neural networks. In: Schuster H.G. Ed., New York: VCH.
Nonlinear dynamics and neuronal networks, pp. 281-302, 1991.
[9] O. Sporns, G. Tonino, and G. M. Edelman, "Connectivity and complexity:
the relationship between neuroanatomy and brain dynamics". Neural
Network, vol. 13, pp. 909-922, 2000.
[10] V. A. Makarov, F. Panetsos, and O. De Feo, "A method for determining
neural connectivity and inferring the underlying network dynamics using
extracellular spike recordings". J Neurosci Methods, vol. 144, pp. 265-
279, 2005.
[11] N. Castellanos, V. A. Makarov, O. de Feo, A. Perez de Vargas, and F.
Panetsos, "Identification of functional neural circuits from extracellular
recordings using a novel mathematical method". Proc. of FENS, 2004.
[12] A. Pavlov, V. A. Makarov, I. Makarova, and F. Panetsos, "Sorting
of neural spikes: When wavelet based methods outperform principal
components analysis". Natural Computing, DOI 10.1007/s11047-006-
9014-8 (in press), 2006.
[13] R. Jolivet, T.J. Lewis, and W. Gerstner, "Generalized Integrate-and-Fire
models of neuronal activity approximate spike trains of a detailed model
to a high degree of accuracy". J Neurophysiol, vol. 92, pp. 959-976,
2004.
[14] R. B. Stein, "Some models of neuronal variability". Biophys J vol. 7,
pp. 37-68, 1967.
[15] C. Koch and I. Segev, Methods in neuronal modelling: From ions to
networks. MIT Press: Cambridge, Massachusetts, 1998.
[16] H. Motulsky and A. Christopoulos, Fitting models to biological data
using linear and nonlinear regression: A practical guide to curve fitting.
[1] G. P. Moore, D. P. Perkel, and J. P. Segundo,"Statistical analysis and
functional interpretation of neural spike data". Annu Rev Physiol, vol.
28, pp. 493-522, 1966.
[2] D. H. Perkel, G. L. Gerstein, and G. P. Moore, "Neuronal spike trains
and stochastic point processes. II Simultaneous spike train". Biophys J,
vol. 7, pp. 419-440, 1967.
[3] E. R. Kandel, J. H. Schwartz, and T. M. Jessell, Principles of neural
science. 4th ed. New York: McGraw-Hill, 2000.
[4] F. Panetsos, A. Nunez, and C. Avendano, "Electrophysiological effects of
temporary differentiation on two characterized cell types in the nucleus
gracilis of the rat". Eur J Neurosci, vol. 9, pp. 563-572, 1997
[5] F. Panetsos, A. Nunez, C. Avendano, "Sensory information processing
in the dorsal column nuclei by neuronal oscillators". Neurosci, vol. 84,
pp. 635-639, 1998.
[6] A. Nunez, F. Panetsos, and C. Avendao."Rhythmic neuronal interactions
and synchronization in the rat dorsal column nuclei". Neurosci, vol. 100,
pp. 599-609, 2000.
[7] G. Gerstein, P. Bedenbaugh, and M. Aertse, "Neuronal assemblies".
IEEE Trans biomed engineering, vol. 36, no. 1, pp. 4-14, 1989.
[8] A. Aertsen and H. Preissl, Dynamics of activity and connectivity in
physiological neural networks. In: Schuster H.G. Ed., New York: VCH.
Nonlinear dynamics and neuronal networks, pp. 281-302, 1991.
[9] O. Sporns, G. Tonino, and G. M. Edelman, "Connectivity and complexity:
the relationship between neuroanatomy and brain dynamics". Neural
Network, vol. 13, pp. 909-922, 2000.
[10] V. A. Makarov, F. Panetsos, and O. De Feo, "A method for determining
neural connectivity and inferring the underlying network dynamics using
extracellular spike recordings". J Neurosci Methods, vol. 144, pp. 265-
279, 2005.
[11] N. Castellanos, V. A. Makarov, O. de Feo, A. Perez de Vargas, and F.
Panetsos, "Identification of functional neural circuits from extracellular
recordings using a novel mathematical method". Proc. of FENS, 2004.
[12] A. Pavlov, V. A. Makarov, I. Makarova, and F. Panetsos, "Sorting
of neural spikes: When wavelet based methods outperform principal
components analysis". Natural Computing, DOI 10.1007/s11047-006-
9014-8 (in press), 2006.
[13] R. Jolivet, T.J. Lewis, and W. Gerstner, "Generalized Integrate-and-Fire
models of neuronal activity approximate spike trains of a detailed model
to a high degree of accuracy". J Neurophysiol, vol. 92, pp. 959-976,
2004.
[14] R. B. Stein, "Some models of neuronal variability". Biophys J vol. 7,
pp. 37-68, 1967.
[15] C. Koch and I. Segev, Methods in neuronal modelling: From ions to
networks. MIT Press: Cambridge, Massachusetts, 1998.
[16] H. Motulsky and A. Christopoulos, Fitting models to biological data
using linear and nonlinear regression: A practical guide to curve fitting.
@article{"International Journal of Biological, Life and Agricultural Sciences:63700", author = "Valeri A. Makarov and Nazareth P. Castellanos", title = "Inferring the Dynamics of “Hidden“ Neurons from Electrophysiological Recordings", abstract = "Statistical analysis of electrophysiological recordings
obtained under, e.g. tactile, stimulation frequently suggests participation
in the network dynamics of experimentally unobserved “hidden"
neurons. Such interneurons making synapses to experimentally
recorded neurons may strongly alter their dynamical responses to
the stimuli. We propose a mathematical method that formalizes this
possibility and provides an algorithm for inferring on the presence
and dynamics of hidden neurons based on fitting of the experimental
data to spike trains generated by the network model. The model
makes use of Integrate and Fire neurons “chemically" coupled
through exponentially decaying synaptic currents. We test the method
on simulated data and also provide an example of its application to
the experimental recording from the Dorsal Column Nuclei neurons
of the rat under tactile stimulation of a hind limb.", keywords = "Integrate and fire neuron, neural network models,
spike trains.", volume = "2", number = "3", pages = "98-6", }
