Interspike interval attractors from chaotically driven neuron models. (English) Zbl 0891.60096
Summary: Sequences of intervals between firing times (interspike intervals (ISI)) from single neuron models with chaotic forcing are investigated. We analyze how the dynamical properties of the chaotic input determine those of the output ISI sequence, and assess how various biophysical parameters affect this input-output relationship. The attractors constructed from delay embeddings of ISI and of the chaotic input are compared from the points of view of geometry and nonlinear forecastability. For the three integrate-and-fire (IF) models investigated, the similarity between these attractors is high only when the mean firing rate is high, and when firings occur over a large range of the input signal. When these conditions are satisfied, ISIs are related to input values at which firings occur by a simple map, and their distribution can be derived from that of input signal values. Attractor reconstruction is found to be more sensitive to mean firing rate than to ISI distribution. At low firing rates, for which the input is under sampled and ISI become larger than the short-term prediction horizon, or when the dynamics do not allow a smooth invertible mapping between signal and ISI, information is lost. Our results, relevant to all dynamical systems generating events, show that information about continuous-time dynamics is difficult to retrieve at low event rates, and that information about inputs can be isolated only under restricted conditions.
MSC:
| 60K35 | Interacting random processes; statistical mechanics type models; percolation theory |
| 82C32 | Neural nets applied to problems in time-dependent statistical mechanics |
Keywords:
neuron models; delay embeddings; mean firing rate; attractor reconstruction; low firing ratesReferences:
| [1] | Lasota, A.; Mackey, M. C.; Tyrcha, J., The statistical dynamics of recurrent biological events, J. Math. Biol., 30, 775-800 (1992) · Zbl 0763.92001 |
| [2] | Rapp, P. E.; Albano, A. M.; Zimmerman, I. D.; Jiménez-Montano, M. A., Phase-randomized surrogates can produce spurious identifications of non-random structure, Phys. Lett. A, 192, 27-33 (1994) |
| [3] | Shaw, R., The Dripping Faucet as a Model Chaotic System (1984), Aerial Press: Aerial Press Santa Cruz, CA |
| [4] | Tuckwell, H., Stochastic Processes in the Neurosciences (1989), Society for Industrial and Applied Mathematics: Society for Industrial and Applied Mathematics Philadelphia, PA · Zbl 0675.92001 |
| [5] | Sayers, B. McA., Inferring significance from biological signals, (Clynes, M.; Milsum, J., Biomedical Engineering Systems (1970), McGraw-Hill: McGraw-Hill New York), 84-164, Ch. 4 |
| [6] | Eckhorn, R.; Grusser, O.-J.; Kröller, J.; Pellnitz, K.; Pöpel, B., Efficiency of different neuronal codes: Information transfer calculations for three different neuronal systems, Biol. Cybern., 22, 49-60 (1976) · Zbl 0321.92006 |
| [7] | Bialek, W.; Rieke, F.; de Ruyter van Steveninck, R. R.; Warland, D., Reading a neural code, Science, 252, 1854-1857 (1991) |
| [8] | Abbott, L. F., Decoding neuronal firing and modelling neural networks, Quart. Rev. Biophys., 27, 291-331 (1994) |
| [9] | Gabbiani, F.; Koch, C., Coding of time-varying signals in spike trains of integrate-and-fire neurons with random threshold, Neural Comput., 8, 44-66 (1996) |
| [10] | Holden, A. V., Models of the Stochastic Activity of Neurones, (Lecture Notes in Biomathematics, Vol. 12 (1976), Springer: Springer Berlin) · Zbl 0353.92001 |
| [11] | Takens, F., Detecting strange attractors in turbulence, (Rand, D. A.; Young, L.-S., Dynamical Systems and Turbulence. Dynamical Systems and Turbulence, Lecture Notes in Mathematics, Vol. 898 (1981), Springer: Springer Berlin), 366-381, (Warwick, 1980) · Zbl 0513.58032 |
| [12] | Sauer, T.; Yorke, J. A.; Casdagli, M., Embedology, J. Statist. Phys., 65, 579-616 (1991) · Zbl 0943.37506 |
| [13] | Sauer, T., Reconstruction of dynamical systems from interspike intervals, Phys. Rev. Lett., 72, 3811-3814 (1994) |
| [14] | Glass, L.; Mackey, M. C., A simple model for phase locking of biological oscillators, J. Math. Biol., 7, 339-352 (1979) · Zbl 0397.92006 |
| [15] | Keener, J. P.; Hoppensteadt, F. C.; Rinzel, J., Integrate and fire models of nerve membrane response to oscillatory input, SIAM J. Appl. Math., 41, 503-517 (1981) · Zbl 0476.92010 |
| [16] | FitzHugh, R., mathematical models of excitation and propagation in nerve, (Schwann, H. P., Biological Engineering (1962), McGraw-Hill: McGraw-Hill New York), 1-85, Ch. 1 |
| [17] | Nagumo, J.; Arimoto, S.; Yoshizawa, S., An active pulse transmission line simulating nerve axon, (Proc. IRE., 50 (1962)), 2061-2070 |
| [18] | Rapp, P. E.; Zimmerman, I. D.; Albano, A. M.; deGuzman, G. C.; Greenbaun, N. N., Dynamics of spontaneous neural activity in the simian motor cortex: The dimension of chaotic neurons, Phys. Lett. A, 110, 335-338 (1985) |
| [19] | Takahashi, N.; Hanyu, Y.; Musha, T.; Kubo, R.; Matsumoto, G., Global bifurcation structure in periodically stimulated giant axons of squid, Physica D, 43, 318-334 (1990) · Zbl 0704.92007 |
| [20] | Preissl, H.; Aertsen, A.; Palm, G., Are fractal dimensions a good measure for neuronal activity, (Eckmiller, R.; Hartmann, R.; Hausske, G., Parallel Processing in Neural Systems and Computers (1990), Elsevier: Elsevier Amsterdam), 83-86 |
| [21] | Longtin, A., Nonlinear forecasting of spike trains from sensory neurons, Int. J. Bifurc. and Chaos, 3, 3, 651-660 (1993) · Zbl 0875.92026 |
| [22] | Schiff, S. J.; Jerger, K.; Chang, T.; Sauer, T.; Aitken, P. G., Stochastic versus deterministic variability in simple neuronal circuits: II. hippocampal slice, Biophys. J., 67, 684-691 (1994) |
| [23] | J.P. Segundo, G. Sugihara, P. Dixon, M. Stiber and L. Bersier, The spike trains of inhibited pacemaker neurons seen through the magnifying glass of nonlinear analyses, preprint.; J.P. Segundo, G. Sugihara, P. Dixon, M. Stiber and L. Bersier, The spike trains of inhibited pacemaker neurons seen through the magnifying glass of nonlinear analyses, preprint. |
| [24] | an der Heiden, U.; Mackey, M. C., The dynamics of production and destruction: Analytical insight into complex behavior, J. Math. Biol., 16, 75-101 (1982) · Zbl 0523.93038 |
| [25] | Alström, P.; Levinsen, M. T., Phase-locking structure of integrate-and-fire models with threshold modulation, Phys. Lett. A, 128, 187-192 (1988) |
| [26] | Pierson, D.; Moss, F., Detecting periodic unstable points in noisy chaotic and limit cycle attractors with applications to biology, Phys. Rev. Lett., 75, 2124-2127 (1995) |
| [27] | Aihara, K.; Numajiri, T.; Matsumoto, G.; Kotani, M., Structures of attractors in periodically forced neural oscillators, Phys. Lett. A, 116, 313-317 (1986) |
| [28] | Chialvo, D. R.; Jalife, J., Non-linear dynamics of cardiac excitation and impulse propagation, Nature, 330, 749-752 (1987) |
| [29] | Farmer, J. D.; Sidorowich, J. J., Predicting chaotic time series, Phys. Rev. Lett., 59, 845-848 (1987) |
| [30] | Longtin, A.; Racicot, D. M., Assesment of linear and nonlinear correlations between neural firing events, (Cutler, C. D.; Kaplan, D. T., Nonlinear Dynamics and Time Series: Building a Bridge between the Natural and Statistical Sciences. Nonlinear Dynamics and Time Series: Building a Bridge between the Natural and Statistical Sciences, Fields Institute Communications, Vol. II (1997), American Mathematical Society: American Mathematical Society Providence, RI) · Zbl 0871.92010 |
| [31] | Tsonis, A. A.; Elsner, J. B., Nonlinear prediction as a way of distinguishing chaos from random fractal sequences, Nature, 359, 217-220 (1992) |
| [32] | Theiler, J.; Eubank, S.; Longtin, A.; Galdrikian, B.; Farmer, J. D., Testing for nonlinearity in time series: The method of surrogate data, Physica D, 58, 77-94 (1992) · Zbl 1194.37144 |
| [33] | Racicot, D. M.; Longtin, A., Reconstructing dynamics from neural spike trains, (Proc. IEEE 17th Ann. Conf. Engr. Med. Biol. Soc. (1995)) |
| [34] | Wales, D. J., Calculating the rate of loss of information from chaotic time series by forecasting, Nature, 350, 485-488 (1991) |
| [35] | Rinzel, J., Electrical excitability of cells, theory and experiment: Review of the Hodgkin-Huxley foundation and an update, Bull. Math. Biol., 52, 5-23 (1990) |
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