MACROSCOPIC MODEL OF VISUAL PROCESSING IN BRAIN STRUCTURES IN NORMAL CONDITION AND DESCRIPTION OF THE TRANSITION TO EPILEPTIFORM REGIME

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Nujdel I. V., Sokolov М. Е., Yakhno V. G. MACROSCOPIC MODEL OF VISUAL PROCESSING IN BRAIN STRUCTURES IN NORMAL CONDITION AND DESCRIPTION OF THE TRANSITION TO EPILEPTIFORM REGIME. Izvestiya VUZ. Applied Nonlinear Dynamics, 2015, vol. 23, iss. 5, pp. 92-106. DOI: https://doi.org/10.18500/0869-6632-2015-23-5-92-106

This paper presents the functional model of signal processing in networks of similar interconnected active elements. On the one hand, it is a macroscopic model of the dynamic interactions between neural networks and its states can be considered as normal and abnormal modes of signal processing (for example, images). On the other hand, the model and the calculation results can be considered as a variant of modeling epilepsy. In this paper we develop an information macroscopic approach to the modeling of epilepsy, which in this sense is unique.

 

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Authors: 
Nujdel I. V., Institute of Applied Physics of the Russian Academy of Sciences, ul. Ul'yanova, 46, Nizhny Novgorod , 603950, Russia , nuidel@awp.nnov.ru, nira_appl@mail.ru
Sokolov М. Е., Institute of Applied Physics of the Russian Academy of Sciences, ul. Ul'yanova, 46, Nizhny Novgorod , 603950, Russia , sokolov.maxx@gmail.com
Yakhno V. G. , Institute of Applied Physics of the Russian Academy of Sciences, ul. Ul'yanova, 46, Nizhny Novgorod , 603950, Russia , yakhno@appl.sci-nnov.ru
Key words: 
Neural network emulators, neuromorphic model, modeling of sensory signal transformation in the thalamocortical neuronal ensembles, thalamocortical circuit, modeling of epilepsy, corticothalamic interactions.
DOI: 
10.18500/0869-6632-2015-23-5-92-106
Literature

1. Hodgkin A.L., Huxley A.F. // J. Physiol. 1952. Vol. 117. P. 500.

2. Gerstner W., Kistler W. Spiking Neuron Models: Single Neurons, Populations, Plasticity // Cambridge: Cambridge University Press, 2002.

3. Van Drongelen W., Lee H.C., Stevens R.L., Hereld M. // J. Clin. Neurophysiol. 2007. Vol. 24(2). P. 182.

4. Wilson H.R., Cowan J.D. // Biophys. J. 1972. Vol. 12(1). P. 1.

5. Sbitnev V.I., Drabkin G.M. // Biophysics. 1975. Т. 20. C. 669 ( in Russian).

6. Kudryashov A.V., Yakhno V.G. // Dynamics of Biological Systems. 1978. Iss. 2. P. 45 (in Russian).

7. Destexhe A., Sejnowski T.J. // Biol. Cybern. 2009. July. Vol. 101(1). P. 1.

8. Suffczynski P., Kalitzin S., Lopes Da Silva F.H. // Neuroscience. 2004. Vol. 126(2). P. 467.

9. Wendling F., Bartolomei F., Bellanger J.J., Bourien J., Chauvel P. // Brain. 2003. Vol. 126 (6). P. 1449.

10. Wendling F., Hernandez A., Bellanger J.J., Chauvel P., Bartolomei F. // J. Clin. Neurophysiol. 2005. Vol. 22 (5). P. 343.

11. Soltesz I., Staley K.J. Computational Neuroscience in Epilepsy. Elsevier, 2008.

12. Markram H. // Nat. Rev. Neurosci. 2006. Vol. 7(2). P. 153.

13. Prinz A.A., Bucher D., Marder E. // Nat. Neurosci. 2004. Vol. 7(12). P. 1345.

14. Herz A.V., Gollisch T., Machens C.K., Jaeger D. // Science. 2006. Vol. 314 (5796). P. 80.

15. Vergnes M., Marescaux C. et al. // Neurosci. Lett. 1982. Vol. 33. P. 97.

16. Coenen A., van Luijtelaar G. // Behav. Genetics. 2003. Vol. 33. P. 635.

17. Depaolis A., van Luijtelaar G. // Eds A. Pitkanen, P. Schwartzkroin, S. Moshe. Models of Seizures and Epilepsy // San Diego, CA: Elsevier, 2005. P. 233.

18. van Luijtelaar G., Sitnikova E. // Neurosci. Biobehav. Rev. 2006. Vol. 30. P. 983.

19. Meeren H., Pijn J., van Luijtelaar G., Coenen A., Lopes da Silva А. // Arch. Neurology. 2002. Vol. 62. P. 371.

20. Kuznetsova G.D., Popova A.V., Sokolov M.E. // Nonlinear dynamics of cognitive studies - 2011: Proceedings / Ros.akad.nauk, Institute of Applied Physics. Nizhny Novgorod: IAP RAS, 2011. P. 107 (in Russian).

21. Yahno V.G. // Proceedings / Nonlinear Waves 2002 / Eds A.V. Gaponov-Grekhov, V.I. Nekorkin. Nizhny Novgorod: IAP RAS, 2003. P. 90 (in Russian).

22. Shevelev I.A. // Priroda. 2001. No 12 (in Russian).

23. http://vivovoco.rsl.ru/VV/JOURNAL/NATURE/12_01/ALPHA.HTM

24. Hecht-Nielsen R. // Proceedings of the 6th International Conference on Molecular Electronics and Biocomputing. Future Electronic Devices Association of Japan, Okinawa, 28–30 November 1995.

25. Platt N., Spiegel E.A., Tresser C. // Phys. Rev. Lett. 1993. Vol. 70, No 3. P. 279.

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Nonlinear Dynamics and Neuroscience
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BibTeX

@article{Нуйдель -IzvVUZ_AND-23-5-92,
author = {I. V. Nujdel and М. Е. Sokolov and V. G. Yakhno },
title = {MACROSCOPIC MODEL OF VISUAL PROCESSING IN BRAIN STRUCTURES IN NORMAL CONDITION AND DESCRIPTION OF THE TRANSITION TO EPILEPTIFORM REGIME},
year = {2015},
journal = {Izvestiya VUZ. Applied Nonlinear Dynamics},
volume = {23},number = {5},
url = {https://old-andjournal.sgu.ru/en/articles/macroscopic-model-of-visual-processing-in-brain-structures-in-normal-condition-and},
address = {Саратов},
language = {russian},
doi = {10.18500/0869-6632-2015-23-5-92-106},pages = {92--106},issn = {0869-6632},
keywords = {Neural network emulators,neuromorphic model,modeling of sensory signal transformation in the thalamocortical neuronal ensembles,thalamocortical circuit,modeling of epilepsy,corticothalamic interactions.},
abstract = {This paper presents the functional model of signal processing in networks of similar interconnected active elements. On the one hand, it is a macroscopic model of the dynamic interactions between neural networks and its states can be considered as normal and abnormal modes of signal processing (for example, images). On the other hand, the model and the calculation results can be considered as a variant of modeling epilepsy. In this paper we develop an information macroscopic approach to the modeling of epilepsy, which in this sense is unique.   Download full version }}