Dynamical Systems in Neuroscience:

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446 ReferencesGuckenheimer J. (1975) Isochrons and Phaseless Sets. Journal of Mathematical Biology, 1:259–273.Guevara M.R. and Glass L. (1982) Phase locking, periodic doubling bifurcations and chaos ina mathematical model of a periodically driven oscillator: a theory for the entrainment ofbiological oscillators and the generation of cardiac dysrhythmias. Math. Biol. 14: 1-23.Guttman R., Lewis S., Rinzel J. (1980) Control of repetitive firing in squid axon membrane asa model for a neuroneoscillator. J. Physiology. 305: 377-395.Hansel D., Mato G., and Meunier C. (1995) Synchrony in excitatory neural networks. NeuralComputations 7:307–335.Hansel D. and Mato G. (2003) Asynchronous States and the Emergence of Synchrony in LargeNetworks of Interacting Excitatory and Inhibitory Neurons. Neural Computation, 15:1–56.Hansel D., Mato G., Meunier C., and Neltner L. (1998) On Numerical Simulations of Integrateand-FireNeural Networks. Neural Computation, 10:467–483.Harris-Warrick R.M. and Flamm R.E. (1987) Multiple mechanisms of bursting in a conditionalbursting neuron. J. Neurosci., 7:2113–2128Hastings J.W. and Sweeney B.M. (1958) A persistent diurnal rhythms of luminescence inGonyaulax polyedra. Biol. Bull. 115:440-458.Hausser M., Spruston N., and Stuart G.J. (2000) Diversity and Dynamics of Dendritic Signaling.Science, 290:739–744Hausser M. and Mel B. (2003) Dendrites: bug or feature? Current Opinion in Neurobiology,13:372–383Heyward P., Ennis M., Keller A., and Shipley M.T. (2001) Membrane Bistability in OlfactoryBulb Mitral Cells The Journal of Neuroscience, 21:5311–5320Hille B. (2001) Ion Channels of Excitable Membranes. (2nd edition) Sinauer, Sunderland, MA.Hindmarsh J.L. and Rose R.M. (1982) A model of the nerve impulse using two first-orderdifferential equations. Nature 296:162–164Hines M.A. (1989) Program for simulation of nerve equations with branching geometries. Int JBiomed Comput 24:55–68.Hodgkin A.L. (1948) The local electric changes associated with repetitive action in a nonmedulatedaxon. Journal of Physiology 107:165–181.Hodgkin A.L. and Huxley A.F. (1952) A quantitative description of membrane current andapplication to conduction and excitation in nerve. Journal Physiol., 117:500–544.Holden L. and Erneux T. (1993a) Slow passage through a Hopf bifurcation: form oscillatory tosteady state solutions. SIAM Journal on Applied Mathematics 53:1045–1058Holden L. and Erneux T. (1993b) Understanding bursting oscillations as periodic slow passagesthrough bifurcation and limit points. J. Math. Biol. 31:351–365Hopf E. (1942) Abzweigung einer periodischen Losung von einer stationaren Losung eines Differetialsystems.Ber. Math.-Phys. Kl. Sachs, Aca. Wiss. Leipzig, 94:1–22.Hoppensteadt F.C. (1997) An Introduction to the Mathematics of Neurons. Second edition:Modeling in the Frequency Domain. Cambridge Univ. Press, Cambridge, U. K.
References 447Hoppensteadt F.C. (2000) Analysis and simulations of chaotic systems.Springer-Verlag, New York.Hoppensteadt F.C. and Izhikevich E.M. (1996) Synaptic Organizations and Dynamical Propertiesof Weakly Connected Neural Oscillators. II. Learning of Phase Information. BiologicalCybernetics, 75:129–135Hoppensteadt F.C. and Izhikevich E.M. (1996) Synaptic Organizations and Dynamical Propertiesof Weakly Connected Neural Oscillators: I. Analysis of Canonical Model. BiologicalCybernetics, 75:117–127Hoppensteadt F.C. and Izhikevich E.M. (1997) Weakly Connected Neural Networks. Springer-Verlag, NYHoppensteadt F.C. and Keener J.P. (1982) Phase Locking of Biological Clocks.Biology, 15:339–349.J. MAth.Hoppensteadt F.C. and Peskin C.S.(2002) Modeling and Simulation in Medicine and the LifeSciences. Second edition. Springer-Verlag, NYHughes S.W., Cope D.W., Toth T.L., Williams S.R., and Crunelli V. (1999) All thalamocorticalneurones possess a T-type Ca2+ ’window’ current that enables the expression of bistabilitymediatedactivities. The Journal of Physiology, 517:805–815.Huguenard J.R. and McCormick D.A. (1992) Simulation of the Currents Involved in RhythmicOscillations in Thalamic Relay Neurons. Journal of Neurophysiology, 68:1373–1383Hutcheon, B., Miura, R.M., Puil, E., (1996). Subthreshold membrane resonance in neocorticalneurons. Journal of Neurophysiology 76:683–697.Izhikevich E.M. (2003) Simple Model of Spiking Neurons IEEE Transactions on Neural Networks,14:1569- 1572.Izhikevich E.M. (2002) Resonance and Selective Communication Via Bursts in Neurons HavingSubthreshold Oscillations. BioSystems, 67:95-102Izhikevich E.M. (2001) Resonate-and-Fire Neurons. Neural Networks, 14:883-894Izhikevich E.M. (2001) Synchronization of Elliptic Bursters SIAM Review, 43:315-344Izhikevich E.M. (2000) Neural Excitability, Spiking, and Bursting.Bifurcation and Chaos. 10:1171-1266.International Journal ofIzhikevich E.M. (2000) Phase Equations For Relaxation Oscillators SIAM Journal on AppliedMathematics, 60:1789-1805Izhikevich E.M. (1999) Class 1 Neural Excitability, Conventional Synapses, Weakly ConnectedNetworks, and Mathematical Foundations of Pulse-Coupled Models. IEEE Transactions OnNeural Networks,10:499-507Izhikevich E.M. (1999) Weakly Connected Quasiperiodic Oscillators, FM Interactions, and Multiplexingin the Brain. SIAM Journal on Applied Mathematics, 59:2193-2223Izhikevich E.M. (1998) Phase Models With Explicit Time Delays. Physical Review E, 58:905-908Izhikevich E.M., Desai N.S., Walcott E.C., Hoppensteadt F.C. (2003) Bursts as a unit of neuralinformation: selective communication via resonance . Trends in Neuroscience 26:161-167Izhikevich E.M. and Hoppensteadt F.C. (2004) Classification of Bursting Mappings. Interna-
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Eugene M. IzhikevichThe Neuroscienc
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6.3.6 Saddle-node homoclinic orbit
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9.4.2 Integrators vs. Resonators .
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xPrefaceversely, cells having quite
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2 Introductionapical dendritessomar
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4 Introduction(a)spikes(b)spikes cu
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6 Introduction1.1.3 Why are neurons
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8 Introductionconcepts of dynamical
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10 Introductionspikingmoderesting m
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12 Introduction(a)spikinglimitcycle
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14 Introductionco-existence of rest
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16 Introduction1.2.4 Neuro-computat
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18 IntroductionspikeFigure 1.16: Ph
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20 Introductionwith coupled neurons
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22 IntroductionFigure 1.17: John Ri
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24 Introduction
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26 Electrophysiology of NeuronsInsi
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28 Electrophysiology of Neuronsouts
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30 Electrophysiology of NeuronsRest
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32 Electrophysiology of NeuronsFigu
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34 Electrophysiology of Neuronsm (V
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36 Electrophysiology of Neurons10.8
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38 Electrophysiology of Neurons2.3
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42 Electrophysiology of NeuronsDepo
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44 Electrophysiology of NeuronsV(x,
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46 Electrophysiology of Neurons1m (
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48 Electrophysiology of NeuronsPara
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52 Electrophysiology of Neuronsvolt
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54 Electrophysiology of Neurons
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56 One-Dimensional SystemsActivatio
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58 One-Dimensional Systemsinwardcur
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60 One-Dimensional Systems40bistabi
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62 One-Dimensional Systemsat every
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64 One-Dimensional Systems?F(V)>0+
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66 One-Dimensional SystemsUnstableE
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¡ ¡ ¡¡ ¡ ¡¡ ¡ ¡¡ ¡ ¡¡
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70 One-Dimensional Systems+ - - + +
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72 One-Dimensional Systemsλ(V-Veq)
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74 One-Dimensional Systemsbifurcati
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76 One-Dimensional Systems100806040
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78 One-Dimensional Systemsbifurcati
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80 One-Dimensional Systems20 mV100
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82 One-Dimensional Systemsmembrane
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84 One-Dimensional Systemssteady-st
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86 One-Dimensional Systemsspike rig
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88 One-Dimensional SystemsVF (V)1VV
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90 One-Dimensional Systems10.80.60.
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92 One-Dimensional Systems
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94 Two-Dimensional SystemsI Na,pneu
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96 Two-Dimensional Systemsdefines a
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98 Two-Dimensional Systems(f(x(t),y
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100 Two-Dimensional Systems0.70acti
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102 Two-Dimensional Systems0.70.6K
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104 Two-Dimensional Systemsy1.510.5
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106 Two-Dimensional SystemsFor exam
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108 Two-Dimensional SystemsIn gener
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110 Two-Dimensional Systemsv 2 v 2v
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112 Two-Dimensional SystemsV-nullcl
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114 Two-Dimensional SystemsV-nullcl
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116 Two-Dimensional Systemsheterocl
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118 Two-Dimensional Systems0.60.5n-
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120 Two-Dimensional Systemseigenval
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122 Two-Dimensional SystemsK + acti
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124 Two-Dimensional Systemsexcitati
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126 Two-Dimensional SystemsReview o
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128 Two-Dimensional SystemsabcdFigu
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130 Two-Dimensional SystemsFigure 4
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132 Two-Dimensional Systems
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134 Conductance-Based Models• If
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136 Conductance-Based Modelsinward(
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138 Conductance-Based Models1I=01I=
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140 Conductance-Based Modelsleak cu
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142 Conductance-Based Modelshyperpo
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144 Conductance-Based Models0I=0ina
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146 Conductance-Based Models0I=9.75
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148 Conductance-Based Models1I=651I
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150 Conductance-Based Modelshave co
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152 Conductance-Based Models1 sec10
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154 Conductance-Based Modelsvoltage
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156 Conductance-Based Models1h=0.89
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158 Conductance-Based Models5.2.2 E
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160 Conductance-Based Models1recove
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162 Conductance-Based Modelscurrent
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164 Conductance-Based Modelsmodels
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166 Conductance-Based Models
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168 Bifurcationssaddle-node bifurca
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170 Bifurcationssaddle-node bifurca
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172 Bifurcations0.5v 2V-nullclineK
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174 BifurcationsBoth types of the b
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176 BifurcationsV-nullcline0.5K + g
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178 Bifurcationsrstable limit cycle
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180 BifurcationsnVstable limit cycl
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¡ ¡¡ ¡¡ ¡ ¡¡ ¡ ¡182 Bifur
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¡ ¡ ¡¡ ¡ ¡¡ ¡ ¡¡ ¡ ¡184
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186 Bifurcationsmembrane potential,
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188 BifurcationsBifurcation of a li
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190 Bifurcationsstableunstablelimit
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192 Bifurcationsamplitude (max-min)
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194 Bifurcationshomoclinic orbithom
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196 Bifurcations0.80.60.4stable lim
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198 Bifurcationsfrequency (Hz)40030
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200 BifurcationsSaddle-Focus Homocl
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202 Bifurcationsc 1c 2xFigure 6.34:
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204 BifurcationseigenvaluesHopffold
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206 Bifurcationsfast nullclineslow
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208 Bifurcationswith fast and slow
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210 BifurcationsSupercritical Andro
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212 BifurcationsK + conductance tim
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214 BifurcationsIn contrast, if the
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216 Bifurcationsinvariant circlesad
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218 Bifurcationsbifurcationssaddle-
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220 BifurcationsExercises1. (Transc
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222 Bifurcationsv 2v 11a-11-1Figure
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224 Bifurcations19. [M.S.] A leaky
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226 Excitabilityspike?spikerestrest
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228 ExcitabilityAlternatively, the
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230 Excitability50 ms 20 mV 1 ms100
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232 ExcitabilityClass 3 excitable n
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234 Excitability0.20.150.10.05I 1I
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236 Excitabilitysaddle-node bifurca
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238 Excitability(a) resting spiking
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240 Excitabilityproperties integrat
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242 ExcitabilityThe existence of fa
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244 Excitability1coincidencedetecti
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246 Excitabilityspikeexcitatory pul
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248 Excitability(g)9 ms(f)(e)(d)(c)
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250 Excitabilitysquid axonmodel0 mV
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252 Excitability(a) integrator(b) r
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254 Excitability(a) integrator(b) r
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256 Excitabilitymembrane potential,
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258 Excitability0.1saddle-node bifu
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260 Excitability100 ms10 mVoscillat
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262 ExcitabilityBogdanov-Takens bif
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264 Excitabilitya pulse of current.
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266 Excitabilitymembrane potential
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268 Excitability(a)150100I K(M)(b)3
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270 Excitability50 mV300 msFigure 7
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272 Excitability20 mVADP100 msAHP-6
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274 ExcitabilityK + activation gate
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276 ExcitabilityBibliographical Not
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278 Excitability7. Show that the re
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280 Simple Modelsspikemembrane pote
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282 Simple Models1thresholdyz reset
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284 Simple Models1v reset =|b| 1/2b
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286 Simple Modelsbe an integrator o
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288 Simple Modelsintegrate-and-fire
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290 Simple Models(A) tonic spiking(
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292 Simple Modelsgeneral algorithm
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294 Simple Modelscha, cha — real
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296 Simple Modelslayer 5 neuronsimp
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298 Simple Modelsb=-240200saddle-no
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300 Simple Models(a)simple modellay
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302 Simple Models(a)burstingspiking
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304 Simple Models(a)dendriticspike2
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306 Simple Models(a)74 5 6 3210(b)C
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308 Simple Modelschattering neuron
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310 Simple ModelsLTS neuron (in vit
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312 Simple ModelsFS neuron (in vitr
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314 Simple Models(1) fast oscillati
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316 Simple Modelsthrough an appropr
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318 Simple Modelsthey are able to g
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320 Simple Modelsv r = −80 mV, an
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322 Simple Modelsshow in Fig. 7.36.
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324 Simple ModelsBibliographical No
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326 Simple ModelsExercises1. (Integ
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328 Simple Models17. [M.S.] Analyze
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330 Simple Modelsa35 mV350 msc-NAC
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332 Simple Modelsrat RTN neuronsimp
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334 Simple ModelsFigure 8.34: Class
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336 Simple Modelsspiny neuronlatenc
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338 Simple Models(a)stellate cellof
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340 Simple Modelsrat's mitral cell
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342 Bursting(a) cortical chattering
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344 Burstingmembranepotential (mV)-
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346 Burstingvoltage-gatedCa2+-gated
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348 Burstingslow dynamicsneuronvolt
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350 Burstingslow inactivation of in
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352 Bursting9.2.1 Fast-slow burster
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354 Burstingn-nullclinen slow =-0.0
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356 Bursting0maxmembrane potential,
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358 Bursting0membrane potential, V
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360 BurstingI=0I=4.5425 ms 25 mVI=5
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362 Burstingmembrane potential, V (
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364 Bursting9.3 ClassificationIn Fi
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366 Burstingbifurcation of spiking
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368 BurstingFigure 9.26: Putative
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370 Bursting108spikingslow variable
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372 Bursting(a)membrane potential,
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374 Burstingdepending on the type o
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376 BurstingsubcriticalAndronov-Hop
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378 Bursting(a)membrane potential,
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spiking380 Burstingfoldbifurcations
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382 BurstingspikingsupercriticalAnd
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384 Burstingaction potentials cut2
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386 Bursting9.4.3 BistabilitySuppos
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388 BurstingFigure 9.49: The instan
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esting390 Burstingspikesynchronizat
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392 BurstingReview of Important Con
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394 BurstingspikingrestingFigure 9.
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Page 452 and 453: 442 Referencesterneurons mediated b
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496 Synchronization (see www.izhike
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512 Solutions to Exercises, Chap. 1
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