Controlling Epileptogenic Excitation Based on Neural Mass Model_Journal of Biomedical Engineering

Authors：

 MAZhen

Department of Information Engineering, Binzhou University, Binzhou 256600, China;

Corresponding author：

MAZhen, Email: mazhen_chen@263.net

Keywords：

neural mass model; epileptiform index; epilepsy seizure control; PID controller

DOI：

10.7507/1001-5515.20160044

Video：

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Abstract Full text Figures/Tables Video References Cited by

Overexcitation of neurons in brain can lead to epilepsy seizures, and the key to control epilepsy seizures is to keep the balance between excitation and inhibition. In this paper, epileptiform index is presented to denote the seizure degree and used as control variable of PID controller to control epilepsy seizures. Neural mass model (NMM) is used as a test-bed to simulate the change of seizure degree with the increase of excitatory strength and two control strategies. Experimental results showed that the increase of excitatory strength could lead to a substantial increase of epileptiform index and trigger seizures. PID controller which is used to decrease excitatory strength or increase inhibitory strength can keep excitation-inhibition balance and inhibit epilepsy seizures. Epileptiform index can describe the linear and nonlinear feature of electroencephalogram (EEG) comprehensively, and PID controller is simple and independent of underlying physiological structure, which lays the foundation for its application in the clinic.

Citation： MAZhen. Controlling Epileptogenic Excitation Based on Neural Mass Model. Journal of Biomedical Engineering, 2016, 33(2): 255-259. doi: 10.7507/1001-5515.20160044 Copy

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1. SANEI S, CHAMBERS J A. EEG signal processing[M]. Chichester:John Wiley & Sons Ltd, 2007. 161.
2. GANDHI T, PANIGRAHI B K, BHATIA M, et al. Expert model for detection of epileptic activity in EEG signature[J]. Expert Syst Appl, 2010, 37(4):3513-3520.
3. WENDLING F, BELLANGER J J, BARTOLOMEI F, et al. Relevance of nonlinear lumped-parameter models in the analysis of depth-EEG epileptic signals[J]. Biol Cybern, 2000, 83(4):367-378.
4. JANSEN B H, ZOURIDAKIS G, BRANDT M E. A neurophysiologically-based mathematical model of flash visual evoked potentials[J]. Biol Cybern, 1993, 68(3):275-283.
5. JANSEN B H, RIT V G. Electroencephalogram and visual evoked potential generation in a mathematical model of coupled cortical columns[J]. Biol Cybern, 1995, 73(4):357-366.
6. WENDLING F, BARTOLOMEI F, BELLANGER J J, et al. Interpretation of interdependencies in epileptic signals using a macroscopic physiological model of the EEG[J]. Clin Neurophysiol, 2001, 112(7):1201-1218.
7. WENDLING F, BARTOLOMEI F, BELLANGER J J, et al. Epileptic fast activity can be explained by a model of impaired GABAergic dendritic inhibition[J]. Eur J Neurosci, 2002, 15(9):1499-1508.
8. WENDLING F, HERNANDEZ A, BELLANGER J J, et al. Interictal to ictal transition in human temporal lobe epilepsy:insights from a computational model of intracerebral EEG[J]. J Clin Neurophysiol, 2005, 22(5):343-356.
9. BARTOLOMEI F, WENDLING F, BELLANGER J J, et al. Neural networks involving the medial temporal structures in temporal lobe epilepsy[J]. Clin Neurophysiol, 2001, 112(9):1746-1760.
10. DAVID O, FRISTON K J. A neural mass model for MEG/EEG:coupling and neuronal dynamics[J]. Neuroimage, 2003, 20(3):1743-1755.
11. WANG Junsong, WANG Meili, LI Xiaoli, et al. Closed-loop control of epileptiform activities in a neural population model using a proportional-derivative controller[J]. Chinese Physics B, 2015, 24(3):038701.
12. MA Zhen, ZHOU Weidong, GENG Shujuan, et al. Synchronization regulation in a model of coupled neural masses[J]. Biol Cybern, 2013, 107(2):131-140.
13. PINCUS S. Approximate entropy (ApEn) as a complexity measure[J]. Chaos, 1995, 5(1):110-117.
14. OLSON L D, PERRY M S. Localization of epileptic foci using multimodality neuroimaging[J]. Int J Neural Syst, 2013, 23(1):1230001.
15. YUAN Qi, ZHOU Weidong, YUAN Shasha, et al. Epileptic EEG classification based on kernel sparse representation[J]. Int J Neural Syst, 2014, 24(4):1450015.

Journal of Biomedical Engineering

Controlling Epileptogenic Excitation Based on Neural Mass Model

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