| Models |
1. |
2 Distinct Classes of L2 and L3 Pyramidal Neurons in Human Temporal Cortex (Deitcher et al 2017)
|
2. |
2D model of olfactory bulb gamma oscillations (Li and Cleland 2017)
|
3. |
3D model of the olfactory bulb (Migliore et al. 2014)
|
4. |
3D olfactory bulb: operators (Migliore et al, 2015)
|
5. |
3D-printer visualization of NEURON models (McDougal and Shepherd, 2015)
|
6. |
A 1000 cell network model for Lateral Amygdala (Kim et al. 2013)
|
7. |
A 3D population model of midget retinal ganglion cells at the human fovea (Italiano et al, 2022)
|
8. |
A cerebellar model of phase-locked tACS for essential tremor (Schreglmann et al., 2021)
|
9. |
A cortico-cerebello-thalamo-cortical loop model under essential tremor (Zhang & Santaniello 2019)
|
10. |
A detailed Purkinje cell model (Masoli et al 2015)
|
11. |
A fast model of voltage-dependent NMDA Receptors (Moradi et al. 2013)
|
12. |
A Fast Rhythmic Bursting Cell: in vivo cell modeling (Lee 2007)
|
13. |
A focal seizure model with ion concentration changes (Gentiletti et al., accepted)
|
14. |
A Layer V CCS type pyramidal cell, inhibitory synapse current conduction (Kubota Y et al., 2015)
|
15. |
A Markov model of human Cav2.3 channels and their modulation by Zn2+ (Neumaier et al 2020)
|
16. |
A Model Circuit of Thalamocortical Convergence (Behuret et al. 2013)
|
17. |
A model for a nociceptor terminal and terminal tree (Barkai et al., 2020)
|
18. |
A model for interaural time difference sensitivity in the medial superior olive (Zhou et al 2005)
|
19. |
A model of closed-loop motor unit including muscle spindle feedback (Kim, 2020)
|
20. |
A model of optimal learning with redundant synaptic connections (Hiratani & Fukai 2018)
|
21. |
A model of slow motor unit (Kim, 2017)
|
22. |
A model of the T-junction of a C-fiber sensory neuron (Sundt et al. 2015)
|
23. |
A model of unitary responses from A/C and PP synapses in CA3 pyramidal cells (Baker et al. 2010)
|
24. |
A model of ventral Hippocampal CA1 pyramidal neurons of Tg2576 AD mice (Spoleti et al. 2021)
|
25. |
A multi-compartment model for interneurons in the dLGN (Halnes et al. 2011)
|
26. |
A network model of the vertebrate retina (Publio et al. 2009)
|
27. |
A network of AOB mitral cells that produces infra-slow bursting (Zylbertal et al. 2017)
|
28. |
A neurite to measure ePSP and AP amplitude after passive spread (DeMaegd & Stein, 2021)
|
29. |
A set of reduced models of layer 5 pyramidal neurons (Bahl et al. 2012)
|
30. |
A simplified cerebellar Purkinje neuron (the PPR model) (Brown et al. 2011)
|
31. |
A single column thalamocortical network model (Traub et al 2005)
|
32. |
A single kinetic model for all human voltage-gated sodium channels (Balbi et al, 2017)
|
33. |
A two networks model of connectivity-dependent oscillatory activity (Avella OJ et al. 2014)
|
34. |
A two-layer biophysical olfactory bulb model of cholinergic neuromodulation (Li and Cleland 2013)
|
35. |
Accurate and fast simulation of channel noise in conductance-based model neurons (Linaro et al 2011)
|
36. |
Acetylcholine Boosts Dendritic NMDA Spikes in a CA3 Pyramidal Neuron Model (Humphries et al., 2021)
|
37. |
Action Potential initiation and backpropagation in Neocortical L5 Pyramidal Neuron (Hu et al. 2009)
|
38. |
Action potential initiation in the olfactory mitral cell (Shen et al 1999)
|
39. |
Action potential of mouse urinary bladder smooth muscle (Mahapatra et al 2018)
|
40. |
Action potential reconstitution from measured current waveforms (Alle et al. 2009)
|
41. |
Action potential-evoked Na+ influx are similar in axon and soma (Fleidervish et al. 2010)
|
42. |
Action potential-evoked Na+ influx similar in axon and soma (Fleidervish et al. 2010) (Python)
|
43. |
Active dendrites and spike propagation in a hippocampal interneuron (Saraga et al 2003)
|
44. |
Active dendrites shape signaling microdomains in hippocampal neurons (Basak & Narayanan 2018)
|
45. |
Active dendritic action potential propagation (Casale & McCormick 2011)
|
46. |
Activity dependent conductances in a neuron model (Liu et al. 1998)
|
47. |
Activity dependent regulation of pacemaker channels by cAMP (Wang et al 2002)
|
48. |
Activity patterns in a subthalamopallidal network of the basal ganglia model (Terman et al 2002)
|
49. |
Afferent Integration in the NAcb MSP Cell (Wolf et al. 2005)
|
50. |
Age-dependent excitability of CA1 pyramidal neurons in APPPS1 Alzheimer's model (Vitale et al 2021)
|
51. |
Alcohol action in a detailed Purkinje neuron model and an efficient simplified model (Forrest 2015)
|
52. |
Alcohol excites Cerebellar Golgi Cells by inhibiting the Na+/K+ ATPase (Botta et al.2010)
|
53. |
Allen Institute: Gad2-IRES-Cre VISp layer 5 472447460
|
54. |
Allen Institute: Gad2-IRES-Cre VISp layer 5 473561729
|
55. |
Allen Institute: Htr3a-Cre VISp layer 2/3 472352327
|
56. |
Allen Institute: Htr3a-Cre VISp layer 2/3 472421285
|
57. |
Allen Institute: Nr5a1-Cre VISp layer 2/3 473862496
|
58. |
Allen Institute: Nr5a1-Cre VISp layer 4 329322394
|
59. |
Allen Institute: Nr5a1-Cre VISp layer 4 472306544
|
60. |
Allen Institute: Nr5a1-Cre VISp layer 4 472442377
|
61. |
Allen Institute: Nr5a1-Cre VISp layer 4 472451419
|
62. |
Allen Institute: Nr5a1-Cre VISp layer 4 472915634
|
63. |
Allen Institute: Nr5a1-Cre VISp layer 4 473834758
|
64. |
Allen Institute: Nr5a1-Cre VISp layer 4 473863035
|
65. |
Allen Institute: Nr5a1-Cre VISp layer 4 473871429
|
66. |
Allen Institute: Ntsr1-Cre VISp layer 4 472430904
|
67. |
Allen Institute: Pvalb-IRES-Cre VISp layer 2/3 472306616
|
68. |
Allen Institute: Pvalb-IRES-Cre VISp layer 5 471085845
|
69. |
Allen Institute: Pvalb-IRES-Cre VISp layer 5 472349114
|
70. |
Allen Institute: Pvalb-IRES-Cre VISp layer 5 472912177
|
71. |
Allen Institute: Pvalb-IRES-Cre VISp layer 5 473465774
|
72. |
Allen Institute: Pvalb-IRES-Cre VISp layer 5 473862421
|
73. |
Allen Institute: Pvalb-IRES-Cre VISp layer 6a 471081668
|
74. |
Allen Institute: Pvalb-IRES-Cre VISp layer 6a 472301074
|
75. |
Allen Institute: Pvalb-IRES-Cre VISp layer 6a 473860269
|
76. |
Allen Institute: Rbp4-Cre VISp layer 5 472424854
|
77. |
Allen Institute: Rbp4-Cre VISp layer 6a 473871592
|
78. |
Allen Institute: Rorb-IRES2-Cre-D VISp layer 2/3 472299294
|
79. |
Allen Institute: Rorb-IRES2-Cre-D VISp layer 2/3 472434498
|
80. |
Allen Institute: Rorb-IRES2-Cre-D VISp layer 4 473863510
|
81. |
Allen Institute: Rorb-IRES2-Cre-D VISp layer 5 471087975
|
82. |
Allen Institute: Rorb-IRES2-Cre-D VISp layer 5 473561660
|
83. |
Allen Institute: Scnn1a-Tg2-Cre VISp layer 4 472300877
|
84. |
Allen Institute: Scnn1a-Tg2-Cre VISp layer 4 472427533
|
85. |
Allen Institute: Scnn1a-Tg2-Cre VISp layer 4 472912107
|
86. |
Allen Institute: Scnn1a-Tg2-Cre VISp layer 4 473465456
|
87. |
Allen Institute: Scnn1a-Tg2-Cre VISp layer 5 472306460
|
88. |
Allen Institute: Scnn1a-Tg3-Cre VISp layer 4 329321704
|
89. |
Allen Institute: Scnn1a-Tg3-Cre VISp layer 4 472363762
|
90. |
Allen Institute: Scnn1a-Tg3-Cre VISp layer 4 473862845
|
91. |
Allen Institute: Scnn1a-Tg3-Cre VISp layer 4 473872986
|
92. |
Allen Institute: Scnn1a-Tg3-Cre VISp layer 5 472455509
|
93. |
Allen Institute: Scnn1a-Tg3-Cre VISp layer 5 473863578
|
94. |
Allen Institute: Scnn1a-Tg3-Cre VISp layer 5 473871773
|
95. |
Allen Institute: Sst-IRES-Cre VISp layer 2/3 471086533
|
96. |
Allen Institute: Sst-IRES-Cre VISp layer 2/3 472304676
|
97. |
Allen Institute: Sst-IRES-Cre VISp layer 4 472304539
|
98. |
Allen Institute: Sst-IRES-Cre VISp layer 5 472299363
|
99. |
Allen Institute: Sst-IRES-Cre VISp layer 5 472450023
|
100. |
Allen Institute: Sst-IRES-Cre VISp layer 5 473835796
|
101. |
Allen Institute: Sst-IRES-Cre VISp layer 6a 472440759
|
102. |
Altered complexity in layer 2/3 pyramidal neurons (Luuk van der Velden et al. 2012)
|
103. |
Ambient glutamate shapes AMPA receptor responses to simulated transients (Balmer et al. 2021)
|
104. |
Amyloid beta (IA block) effects on a model CA1 pyramidal cell (Morse et al. 2010)
|
105. |
Amyloid-beta effects on release probability and integration at CA3-CA1 synapses (Romani et al. 2013)
|
106. |
AOB mitral cell: persistent activity without feedback (Zylbertal et al., 2015)
|
107. |
AP back-prop. explains threshold variability and rapid rise (McCormick et al. 2007, Yu et al. 2008)
|
108. |
AP initiation and propagation in type II cochlear ganglion cell (Hossain et al 2005)
|
109. |
AP initiation, propagation, and cortical invasion in a Layer 5 pyramidal cell (Anderson et 2018)
|
110. |
AP shape and parameter constraints in optimization of compartment models (Weaver and Wearne 2006)
|
111. |
Application of a common kinetic formalism for synaptic models (Destexhe et al 1994)
|
112. |
Arteriolar networks: Spread of potential (Crane et al 2001)
|
113. |
Artificial neuron model (Izhikevich 2003, 2004, 2007)
|
114. |
Availability of low-threshold Ca2+ current in retinal ganglion cells (Lee SC et al. 2003)
|
115. |
Axon-somatic back-propagation in a detailed model of cat spinal motoneuron (Balbi et al, 2015)
|
116. |
Axonal NaV1.6 Sodium Channels in AP Initiation of CA1 Pyramidal Neurons (Royeck et al. 2008)
|
117. |
Axonal spheroids and conduction defects in Alzheimer’s disease (Yuan, Zhang, Tong, et al 2022)
|
118. |
Axonal subthreshold voltage signaling along hippocampal mossy fiber (Kamiya 2022)
|
119. |
Balance of excitation and inhibition (Carvalho and Buonomano 2009)
|
120. |
Basal ganglia network model of subthalamic deep brain stimulation (Hahn and McIntyre 2010)
|
121. |
Basket cell extrasynaptic inhibition modulates network oscillations (Proddutur et al., 2013)
|
122. |
BCM-like synaptic plasticity with conductance-based models (Narayanan Johnston, 2010)
|
123. |
Biochemically detailed model of LTP and LTD in a cortical spine (Maki-Marttunen et al 2020)
|
124. |
Biophysical and phenomenological models of spike-timing dependent plasticity (Badoual et al. 2006)
|
125. |
Biophysically detailed model of somatosensory thalamocortical circuit (Borges et al accepted)
|
126. |
Biophysically realistic neural modeling of the MEG mu rhythm (Jones et al. 2009)
|
127. |
Biophysically realistic neuron models for simulation of cortical stimulation (Aberra et al. 2018)
|
128. |
Boolean network-based analysis of the apoptosis network (Mai and Liu 2009)
|
129. |
Brain networks simulators - a comparative study (Tikidji-Hamburyan et al 2017)
|
130. |
Broadening of activity with flow across neural structures (Lytton et al. 2008)
|
131. |
Bursting and resonance in cerebellar granule cells (D'Angelo et al. 2001)
|
132. |
Bursting respiratory net: clustered architecture gives large phase diff`s (Fietkiewicz et al 2011)
|
133. |
Ca+/HCN channel-dependent persistent activity in multiscale model of neocortex (Neymotin et al 2016)
|
134. |
Ca-dependent K Channel: kinetics from rat muscle (Moczydlowski, Latorre 1983) NEURON
|
135. |
CA1 interneuron: K currents (Lien et al 2002)
|
136. |
CA1 network model for place cell dynamics (Turi et al 2019)
|
137. |
CA1 network model: interneuron contributions to epileptic deficits (Shuman et al 2020)
|
138. |
CA1 oriens alveus interneurons: signaling properties (Minneci et al. 2007)
|
139. |
CA1 pyr cell: Inhibitory modulation of spatial selectivity+phase precession (Grienberger et al 2017)
|
140. |
CA1 pyramidal cell: reconstructed axonal arbor and failures at weak gap junctions (Vladimirov 2011)
|
141. |
CA1 pyramidal neuron (Combe et al 2018)
|
142. |
CA1 pyramidal neuron (Migliore et al 1999)
|
143. |
CA1 pyramidal neuron synaptic integration (Bloss et al. 2016)
|
144. |
CA1 pyramidal neuron synaptic integration (Li and Ascoli 2006, 2008)
|
145. |
CA1 pyramidal neuron to study INaP properties and repetitive firing (Uebachs et al. 2010)
|
146. |
CA1 pyramidal neuron: as a 2-layer NN and subthreshold synaptic summation (Poirazi et al 2003)
|
147. |
CA1 pyramidal neuron: action potential backpropagation (Gasparini & Migliore 2015)
|
148. |
CA1 pyramidal neuron: calculation of MRI signals (Cassara et al. 2008)
|
149. |
CA1 pyramidal neuron: conditional boosting of dendritic APs (Watanabe et al 2002)
|
150. |
CA1 pyramidal neuron: dendritic Ca2+ inhibition (Muellner et al. 2015)
|
151. |
CA1 pyramidal neuron: Dendritic Na+ spikes are required for LTP at distal synapses (Kim et al 2015)
|
152. |
CA1 pyramidal neuron: dendritic spike initiation (Gasparini et al 2004)
|
153. |
CA1 pyramidal neuron: depolarization block (Bianchi et al. 2012)
|
154. |
CA1 pyramidal neuron: effects of Ih on distal inputs (Migliore et al 2004)
|
155. |
CA1 pyramidal neuron: effects of Lamotrigine on dendritic excitability (Poolos et al 2002)
|
156. |
CA1 pyramidal neuron: effects of R213Q and R312W Kv7.2 mutations (Miceli et al. 2013)
|
157. |
CA1 pyramidal neuron: functional significance of axonal Kv7 channels (Shah et al. 2008)
|
158. |
CA1 pyramidal neuron: h channel-dependent deficit of theta oscill. resonance (Marcelin et al. 2008)
|
159. |
CA1 pyramidal neuron: Ih current (Migliore et al. 2012)
|
160. |
CA1 pyramidal neuron: integration of subthreshold inputs from PP and SC (Migliore 2003)
|
161. |
CA1 pyramidal neuron: nonlinear a5-GABAAR controls synaptic NMDAR activation (Schulz et al 2018)
|
162. |
CA1 pyramidal neuron: Persistent Na current mediates steep synaptic amplification (Hsu et al 2018)
|
163. |
CA1 pyramidal neuron: rebound spiking (Ascoli et al.2010)
|
164. |
Ca1 pyramidal neuron: reduction model (Marasco et al. 2012)
|
165. |
CA1 pyramidal neuron: schizophrenic behavior (Migliore et al. 2011)
|
166. |
CA1 pyramidal neuron: signal propagation in oblique dendrites (Migliore et al 2005)
|
167. |
CA1 Pyramidal Neuron: slow Na+ inactivation (Migliore 1996)
|
168. |
CA1 pyramidal neuron: synaptic plasticity during theta cycles (Saudargiene et al. 2015)
|
169. |
CA1 pyramidal neuron: Synaptic Scaling (Magee, Cook 2000)
|
170. |
CA1 pyramidal neuron: synaptically-induced bAP predicts synapse location (Sterratt et al. 2012)
|
171. |
CA1 pyramidal neurons: binding properties and the magical number 7 (Migliore et al. 2008)
|
172. |
CA1 pyramidal neurons: effect of external electric field from power lines (Cavarretta et al. 2014)
|
173. |
CA1 pyramidal neurons: effects of a Kv7.2 mutation (Miceli et al. 2009)
|
174. |
CA1 pyramidal neurons: effects of Alzheimer (Culmone and Migliore 2012)
|
175. |
CA1 pyramidal neurons: effects of Kv7 (M-) channels on synaptic integration (Shah et al. 2011)
|
176. |
CA1 stratum radiatum interneuron multicompartmental model (Katona et al. 2011)
|
177. |
CA3 hippocampal pyramidal neuron with voltage-clamp intrinsic conductance data (Traub et al 1991)
|
178. |
CA3 Network Model of Epileptic Activity (Sanjay et. al, 2015)
|
179. |
CA3 pyramidal cell: rhythmogenesis in a reduced Traub model (Pinsky, Rinzel 1994)
|
180. |
CA3 pyramidal neuron (Lazarewicz et al 2002)
|
181. |
CA3 Pyramidal Neuron (Migliore et al 1995)
|
182. |
CA3 pyramidal neuron (Safiulina et al. 2010)
|
183. |
CA3 pyramidal neuron: firing properties (Hemond et al. 2008)
|
184. |
Ca3 pyramidal neuron: membrane response near rest (Hemond et al. 2009)
|
185. |
CA3 pyramidal neurons: Kv1.2 mediates modulation of cortical inputs (Hyun et al., 2015)
|
186. |
Calcium and potassium currents of olfactory bulb juxtaglomerular cells (Masurkar and Chen 2011)
|
187. |
Calcium dynamics depend on dendritic diameters (Anwar et al. 2014)
|
188. |
Calcium response prediction in the striatal spines depending on input timing (Nakano et al. 2013)
|
189. |
Calcium spikes in basal dendrites (Kampa and Stuart 2006)
|
190. |
Calcium waves and mGluR-dependent synaptic plasticity in CA1 pyr. neurons (Ashhad & Narayanan 2013)
|
191. |
Calcium waves in neuroblastoma cells (Fink et al. 2000)
|
192. |
Calculating the consequences of left-shifted Nav channel activity in sick cells (Joos et al 2018)
|
193. |
Carbon nanotubes as electrical interfaces to neurons (Giugliano et al. 2008)
|
194. |
Cardiac action potentials and pacemaker activity of sinoatrial node (DiFrancesco & Noble 1985)
|
195. |
Cardiac Atrial Cell (Courtemanche et al 1998)
|
196. |
Cardiac sarcomere dynamics (Negroni and Lascano 1996)
|
197. |
Cell splitting in neural networks extends strong scaling (Hines et al. 2008)
|
198. |
Cell-type specific integration of feedforward and feedback synaptic inputs (Ridner et al, accepted)
|
199. |
Cellular and Synaptic Mechanisms Differentiate Mitral & Superficial Tufted Cells (Jones et al 2020)
|
200. |
Central Nervous System tadpole model in Matlab and NEURON-Python (Ferrario et al, accepted)
|
201. |
Cerebellar cortex oscil. robustness from Golgi cell gap jncs (Simoes de Souza and De Schutter 2011)
|
202. |
Cerebellar Golgi cell (Solinas et al. 2007a, 2007b)
|
203. |
Cerebellar Golgi cells, dendritic processing, and synaptic plasticity (Masoli et al 2020)
|
204. |
Cerebellar granule cell (Masoli et al 2020)
|
205. |
Cerebellar nuclear neuron (Sudhakar et al., 2015)
|
206. |
Cerebellar purkinje cell: interacting Kv3 and Na currents influence firing (Akemann, Knopfel 2006)
|
207. |
Cerebellar purkinje cell: K and Ca channels regulate APs (Miyasho et al 2001)
|
208. |
Cerebellar Purkinje Cell: resurgent Na current and high frequency firing (Khaliq et al 2003)
|
209. |
Cerebellum granule cell FHF (Dover et al. 2016)
|
210. |
Cerebellum Purkinje cell: dendritic ion channels activated by climbing fibre (Ait Ouares et al 2019)
|
211. |
Changes of ionic concentrations during seizure transitions (Gentiletti et al. 2016)
|
212. |
Channel density variability among CA1 neurons (Migliore et al. 2018)
|
213. |
Chirp stimulus responses in a morphologically realistic model (Narayanan and Johnston, 2007)
|
214. |
Circadian rhythmicity shapes astrocyte morphology and neuronal function in CA1 (McCauley et al 2020)
|
215. |
Cl- homeostasis in immature hippocampal CA3 neurons (Kolbaev et al 2020)
|
216. |
Classic model of the Tritonia Swim CPG (Getting, 1989)
|
217. |
CN bushy, stellate neurons (Rothman, Manis 2003)
|
218. |
CN Octopus Cell: Ih current (Bal, Oertel 2000)
|
219. |
CN pyramidal fusiform cell (Kanold, Manis 2001)
|
220. |
Coincidence detection in avian brainstem (Simon et al 1999)
|
221. |
Coincident glutamatergic depolarization effects on Cl- dynamics (Lombardi et al, 2021)
|
222. |
Coincident signals in Olfactory Bulb Granule Cell spines (Aghvami et al 2019)
|
223. |
Comparison of DA-based Stochastic Algorithms (Pezo et al. 2014)
|
224. |
Compartmental model of a mitral cell (Popovic et al. 2005)
|
225. |
Compartmentalization of GABAergic inhibition by dendritic spines (Chiu et al. 2013)
|
226. |
Competition for AP initiation sites in a circuit controlling simple learning (Cruz et al. 2007)
|
227. |
Complex CA1-neuron to study AP initiation (Wimmer et al. 2010)
|
228. |
Computational analysis of NN activity and spatial reach of sharp wave-ripples (Canakci et al 2017)
|
229. |
Computational model of bladder small DRG neuron soma (Mandge & Manchanda 2018)
|
230. |
Computational model of cerebellar tDCS (Zhang et al., 2021)
|
231. |
Computational modeling of gephyrin-dependent inhibitory transsynaptic signaling (Lupascu et al 2020)
|
232. |
Computational neuropharmacology of CA1 pyramidal neuron (Ferrante et al. 2008)
|
233. |
Computational Surgery (Lytton et al. 2011)
|
234. |
Computer model of clonazepam's effect in thalamic slice (Lytton 1997)
|
235. |
Computer models of corticospinal neurons replicate in vitro dynamics (Neymotin et al. 2017)
|
236. |
Computer simulations of neuron-glia interactions mediated by ion flux (Somjen et al. 2008)
|
237. |
Concentration dependent nonlinear K+ and Cl- leak current (Huang et al. 2015)
|
238. |
Conditions for synaptic specificity in maintenance phase of synaptic plasticity (Huertas et al, '22)
|
239. |
Conditions of dominant effectiveness of distal dendrites (Korogod, Kulagina 1998)
|
240. |
Conductance based model for short term plasticity at CA3-CA1 synapses (Mukunda & Narayanan 2017)
|
241. |
Conduction in uniform myelinated axons (Moore et al 1978)
|
242. |
Constructed Tessellated Neuronal Geometries (CTNG) (McDougal et al. 2013)
|
243. |
Contrast invariance by LGN synaptic depression (Banitt et al. 2007)
|
244. |
Control of oscillations and spontaneous firing in dopamine neurons (Rumbell & Kozloski 2019)
|
245. |
Controlling KCa channels with different Ca2+ buffering models in Purkinje cell (Anwar et al. 2012)
|
246. |
Convergence regulates synchronization-dependent AP transfer in feedforward NNs (Sailamul et al 2017)
|
247. |
Cooling reverses pathological spontaneous firing caused by mild traumatic injury (Barlow et al 2018)
|
248. |
Correcting space clamp in dendrites (Schaefer et al. 2003 and 2007)
|
249. |
Cortical Basal Ganglia Network Model during Closed-loop DBS (Fleming et al 2020)
|
250. |
Cortical feedback alters visual response properties of dLGN relay cells (Martínez-Cañada et al 2018)
|
251. |
Cortical Layer 5b pyr. cell with [Na+]i mechanisms, from Hay et al 2011 (Zylbertal et al 2017)
|
252. |
Cortical model with reinforcement learning drives realistic virtual arm (Dura-Bernal et al 2015)
|
253. |
Cortical network model of posttraumatic epileptogenesis (Bush et al 1999)
|
254. |
Cortical pyramidal neuron, phase response curve (Stiefel et al 2009)
|
255. |
Current Dipole in Laminar Neocortex (Lee et al. 2013)
|
256. |
Current flow during PAP in squid axon at diameter change (Joyner et al 1980)
|
257. |
Cycle skipping in ING Type 1 / Type 2 networks (Tikidji-Hamburyan & Canavier 2020)
|
258. |
D2 dopamine receptor modulation of interneuronal activity (Maurice et al. 2004)
|
259. |
DBS of a multi-compartment model of subthalamic nucleus projection neurons (Miocinovic et al. 2006)
|
260. |
DCN fusiform cell (Ceballos et al. 2016)
|
261. |
Deconstruction of cortical evoked potentials generated by subthalamic DBS (Kumaravelu et al 2018)
|
262. |
Demyelinated and remyelinating axon conductances (Hines, Shrager 1991)
|
263. |
Dendritic action potentials and computation in human layer 2/3 cortical neurons (Gidon et al 2020)
|
264. |
Dendritic action potentials and computation in human layer 2/3 cortical neurons (Gidon et al 2020)
|
265. |
Dendritic Discrimination of Temporal Input Sequences (Branco et al. 2010)
|
266. |
Dendritic Impedance in Neocortical L5 PT neurons (Kelley et al. 2021)
|
267. |
Dendritic L-type Ca currents in motoneurons (Carlin et al 2000)
|
268. |
Dendritic Na+ spike initiation and backpropagation of APs in active dendrites (Nevian et al. 2007)
|
269. |
Dendritic signals command firing dynamics in a Cerebellar Purkinje Cell model (Genet et al. 2010)
|
270. |
Dendritic tip geometry effects electrical properties (Tsutsui, Oka 2001)
|
271. |
Dendritica (Vetter et al 2001)
|
272. |
Dendro-dendritic synaptic circuit (Shepherd Brayton 1979)
|
273. |
Dentate Basket Cell: spatial summation of inhibitory synaptic inputs (Bartos et al 2001)
|
274. |
Dentate granule cell: mAHP & sAHP; SK & Kv7/M channels (Mateos-Aparicio et al., 2014)
|
275. |
Dentate gyrus (Morgan et al. 2007, 2008, Santhakumar et al. 2005, Dyhrfjeld-Johnsen et al. 2007)
|
276. |
Dentate Gyrus Feed-forward inhibition (Ferrante et al. 2009)
|
277. |
Dentate gyrus granule cell: calcium and calcium-dependent conductances (Aradi and Holmes 1999)
|
278. |
Dentate gyrus granule cell: subthreshold signal processing (Schmidt-Hieber et al. 2007)
|
279. |
Dentate gyrus network model (Santhakumar et al 2005)
|
280. |
Dentate gyrus network model (Tejada et al 2014)
|
281. |
Dentate gyrus network model pattern separation and granule cell scaling in epilepsy (Yim et al 2015)
|
282. |
Depolarization Enhacement of Dendritic Spike Propagation (Bock et al 2022)
|
283. |
Detailed passive cable model of Dentate Gyrus Basket Cells (Norenberg et al. 2010)
|
284. |
Determinants of the intracellular and extracellular waveforms in DA neurons (Lopez-Jury et al 2018)
|
285. |
DG adult-born granule cell: nonlinear a5-GABAARs control AP firing (Lodge et al, accepted)
|
286. |
DG granule cell: I-A model (Beck et al 1992)
|
287. |
Diameter, Myelination and Na/K pump interactions affect axonal resilience to high frequency spiking
|
288. |
Differential modulation of pattern and rate in a dopamine neuron model (Canavier and Landry 2006)
|
289. |
Direct recruitment of S1 pyramidal cells and interneurons via ICMS (Overstreet et al., 2013)
|
290. |
Discharge hysteresis in motoneurons (Powers & Heckman 2015)
|
291. |
Discrete event simulation in the NEURON environment (Hines and Carnevale 2004)
|
292. |
Disentangling astroglial physiology with a realistic cell model in silico (Savtchenko et al 2018)
|
293. |
Distal inhibitory control of sensory-evoked excitation (Egger, Schmitt et al. 2015)
|
294. |
Distance-dependent inhibition in the hippocampus (Strüber et al. 2017)
|
295. |
Distance-dependent synaptic strength in CA1 pyramidal neurons (Menon et al. 2013)
|
296. |
Distinct current modules shape cellular dynamics in model neurons (Alturki et al 2016)
|
297. |
Distinct integration properties of noisy inputs in active dendritic subunits (Poleg-Polsky 2019)
|
298. |
Dopamine neuron of the vent. periaqu. gray and dors. raphe nucleus (vlPAG/DRN) (Dougalis et al 2017)
|
299. |
Dopaminergic subtantia nigra neuron (Moubarak et al 2019)
|
300. |
Dorsal root ganglion (DRG) neuronal model (Amir, Devor 2003)
|
301. |
Dorsal root ganglion (DRG) neuronal model (Kovalsky et al. 2009)
|
302. |
Double cable myelinated axon (Layer 5 pyramidal neuron; Cohen et al 2020)
|
303. |
DRG neuron models investigate how ion channel levels regulate firing properties (Zheng et al 2019)
|
304. |
Drosophila 3rd instar larval aCC motoneuron (Gunay et al. 2015)
|
305. |
Drosophila projection neuron electrotonic structure (Gouwens and Wilson 2009)
|
306. |
Drosophila T4 neuron (Gruntman et al 2018)
|
307. |
DRt neuron model (Sousa et al., 2014)
|
308. |
Duration-tuned neurons from the inferior colliculus of vertebrates (Aubie et al. 2012)
|
309. |
Dynamical model of olfactory bulb mitral cell (Rubin, Cleland 2006)
|
310. |
Early-onset epileptic encephalopathy (Miceli et al. 2015)
|
311. |
Effect of ionic diffusion on extracellular potentials (Halnes et al 2016)
|
312. |
Effect of the initial synaptic state on the probability to induce LTP and LTD (Migliore et al. 2015)
|
313. |
Effect of voltage sensitive fluorescent proteins on neuronal excitability (Akemann et al. 2009)
|
314. |
Effects of Chloride accumulation and diffusion on GABAergic transmission (Jedlicka et al 2011)
|
315. |
Effects of Dopamine Modulation and KIR Inactivation in NAc Medium Spiny Neurons (Steephen 2011)
|
316. |
Effects of electric fields on cognitive functions (Migliore et al 2016)
|
317. |
Effects of increasing CREB on storage and recall processes in a CA1 network (Bianchi et al. 2014)
|
318. |
Effects of KIR current inactivation in NAc Medium Spiny Neurons (Steephen and Manchanda 2009)
|
319. |
Effects of neural morphology on global and focal NMDA-spikes (Poleg-Polsky 2015)
|
320. |
Effects of spinal cord stimulation on WDR dorsal horn network (Zhang et al 2014)
|
321. |
Effects of synaptic location and timing on synaptic integration (Rall 1964)
|
322. |
Effects of the membrane AHP on the Lateral Superior Olive (LSO) (Zhou & Colburn 2010)
|
323. |
Efficient Method for Computing Synaptic Conductance (Destexhe et al 1994)
|
324. |
Efficient simulation of 3D reaction-diffusion in models of neurons (McDougal et al, 2022)
|
325. |
Electrically-coupled Retzius neurons (Vazquez et al. 2009)
|
326. |
Electrostimulation to reduce synaptic scaling driven progression of Alzheimers (Rowan et al. 2014)
|
327. |
Electrotonic transform and EPSCs for WT and Q175+/- spiny projection neurons (Goodliffe et al 2018)
|
328. |
eLIF and mAdExp: energy-based integrate-and-fire neurons (Fardet and Levina 2020)
|
329. |
ELL Medium Ganglion cell (Muller et al 2019)
|
330. |
Emergence of physiological oscillation frequencies in neocortex simulations (Neymotin et al. 2011)
|
331. |
Encoding and retrieval in a model of the hippocampal CA1 microcircuit (Cutsuridis et al. 2009)
|
332. |
Energy-efficient information transfer at thalamocortical synapses (Harris et al 2019)
|
333. |
Engaging distinct oscillatory neocortical circuits (Vierling-Claassen et al. 2010)
|
334. |
Enhancing the HH eqs: simulations based on the first publication in Biophys J (Moore 2015)
|
335. |
Ephaptic interactions in olfactory nerve (Bokil et al 2001)
|
336. |
Escape response latency in the Giant Fiber System of Drosophila melanogastor (Augustin et al 2019)
|
337. |
Estimation and Production of Time Intervals (Migliore et al 2001)
|
338. |
Evaluation of passive component of propagating AP in mossy fiber axons (Ohura & Kamiya 2018)
|
339. |
Excitability of PFC Basal Dendrites (Acker and Antic 2009)
|
340. |
Excitability of the soma in central nervous system neurons (Safronov et al 2000)
|
341. |
Excitation Properties of Computational Models of Unmyelinated Peripheral Axons (Pelot et al., 2021)
|
342. |
Excitatory and inhibitory interactions in populations of model neurons (Wilson and Cowan 1972)
|
343. |
Excitatory synaptic interactions in pyramidal neuron dendrites (Behabadi et al. 2012)
|
344. |
Extracellular Action Potential Simulations (Gold et al 2007)
|
345. |
Extracellular fields for a three-dimensional network of cells using NEURON (Appukuttan et al 2017)
|
346. |
Extracellular stimulation of myelinated axon (Reilly 2016)
|
347. |
Facilitation by residual calcium (Stockbridge, Hines 1982)
|
348. |
Factors contribution to GDP-induced [Cl-]i transients (Lombardi et al 2019)
|
349. |
Fast AMPA receptor signaling (Geiger et al 1997)
|
350. |
Fast sodium channel gating in mossy fiber axons (Schmidt-Hieber et al. 2010)
|
351. |
Fast Spiking Basket cells (Tzilivaki et al 2019)
|
352. |
Fast-spiking cortical interneuron (Golomb et al. 2007)
|
353. |
Febrile seizure-induced modifications to Ih (Chen et al 2001)
|
354. |
Feedforward heteroassociative network with HH dynamics (Lytton 1998)
|
355. |
Feedforward inhibition in pyramidal cells (Ferrante & Ascoli 2015)
|
356. |
FHF2KO and Wild-Type Mouse Cardiomyocyte Strands (Park et al 2020)
|
357. |
Firing neocortical layer V pyramidal neuron (Reetz et al. 2014; Stadler et al. 2014)
|
358. |
Firing patterns of CA3 hippocampal neurons (Soldado-Magraner et al. 2019)
|
359. |
Fluctuating synaptic conductances recreate in-vivo-like activity (Destexhe et al 2001)
|
360. |
Fly lobular plate VS cell (Borst and Haag 1996, et al. 1997, et al. 1999)
|
361. |
Four cortical interneuron subtypes (Kubota et al. 2011)
|
362. |
Four-pathway phenomenological synaptic plasticity model (Ebner et al. 2019)
|
363. |
Frog second-order vestibular neuron models (Rossert et al. 2011)
|
364. |
Fronto-parietal visuospatial WM model with HH cells (Edin et al 2007)
|
365. |
Fully Implicit Parallel Simulation of Single Neurons (Hines et al. 2008)
|
366. |
Functional impact of dendritic branch point morphology (Ferrante et al., 2013)
|
367. |
Functional properties of dendritic gap junctions in Cerebellar Golgi cells (Szoboszlay et al. 2016)
|
368. |
Functional structure of mitral cell dendritic tuft (Djurisic et al. 2008)
|
369. |
Gamma genesis in the basolateral amygdala (Feng et al 2019)
|
370. |
Gamma oscillations in hippocampal interneuron networks (Bartos et al 2002)
|
371. |
Gamma oscillations in hippocampal interneuron networks (Wang, Buzsaki 1996)
|
372. |
Gap junction subtypes (Appukuttan et al 2016)
|
373. |
GC model (Beining et al 2017)
|
374. |
Generalized Carnevale-Hines algorithm (van Elburg and van Ooyen 2009)
|
375. |
Geometry-induced features of current transfer in neuronal dendrites (Korogod, Kulagina 1998)
|
376. |
Glutamate diffusion and AMPA receptor activation in the cerebellar glomerulus (Saftenku 2005)
|
377. |
Glutamate mediated dendritic and somatic plateau potentials in cortical L5 pyr cells (Gao et al '20)
|
378. |
Goldfish Mauthner cell (Medan et al 2017)
|
379. |
GPi/GPe neuron models (Johnson and McIntyre 2008)
|
380. |
H-currents effect on the fluctuation of gamma/beta oscillations (Avella-Gonzalez et al., 2015)
|
381. |
High frequency oscillations in a hippocampal computational model (Stacey et al. 2009)
|
382. |
High frequency oscillations induced in three gap-junction coupled neurons (Tseng et al. 2008)
|
383. |
Hippocampal basket cell gap junction network dynamics (Saraga et al. 2006)
|
384. |
Hippocampal CA1 microcircuit model including somatic and dendritic inhibition
|
385. |
Hippocampal CA1 NN with spontaneous theta, gamma: full scale & network clamp (Bezaire et al 2016)
|
386. |
Hippocampal CA3 thorny and a-thorny principal neuron models (Linaro et al in review)
|
387. |
Hippocampal Mossy Fiber bouton: presynaptic KV7 channel function (Martinello et al 2019)
|
388. |
Hippocampus CA1 Interneuron Specific 3 (IS3) in vivo-like virtual NN simulations (Luo et al 2020)
|
389. |
Hippocampus CA1 pyramidal model with Na channel exhibiting slow inactivation (Menon et al. 2009)
|
390. |
Hippocampus temporo-septal engram shift model (Lytton 1999)
|
391. |
HMM of Nav1.7 WT and F1449V (Gurkiewicz et al. 2011)
|
392. |
Hodgkin-Huxley model of persistent activity in PFC neurons (Winograd et al. 2008) (NEURON python)
|
393. |
Hodgkin-Huxley model of persistent activity in prefrontal cortex neurons (Winograd et al. 2008)
|
394. |
Hodgkin-Huxley models of different classes of cortical neurons (Pospischil et al. 2008)
|
395. |
Homeostatic synaptic plasticity (Rabinowitch and Segev 2006a,b)
|
396. |
Hopfield and Brody model (Hopfield, Brody 2000)
|
397. |
Hopfield and Brody model (Hopfield, Brody 2000) (NEURON+python)
|
398. |
Human Cortical L5 Pyramidal Cell (Rich et al. 2021)
|
399. |
Human L2/3 pyramidal cells with low Cm values (Eyal et al. 2016)
|
400. |
Human L5 Cortical Circuit (Guet-McCreight)
|
401. |
Human layer 2/3 cortical microcircuits in health and depression (Yao et al, 2022)
|
402. |
Human somatosensory and motor axon pair to compare thresholds (Gaines et al 2018)
|
403. |
Hyperexcitability from Nav1.2 channel loss in neocortical pyramidal cells (Spratt et al accepted)
|
404. |
Ih levels roles in bursting and regular-spiking subiculum pyramidal neurons (van Welie et al 2006)
|
405. |
Ih tunes oscillations in an In Silico CA3 model (Neymotin et al. 2013)
|
406. |
Impact of dendritic atrophy on intrinsic and synaptic excitability (Narayanan & Chattarji, 2010)
|
407. |
Impact of dendritic size and topology on pyramidal cell burst firing (van Elburg and van Ooyen 2010)
|
408. |
Impedance spectrum in cortical tissue: implications for LFP signal propagation (Miceli et al. 2017)
|
409. |
In silico hippocampal modeling for multi-target pharmacotherapy in schizophrenia (Sherif et al 2020)
|
410. |
Increased computational accuracy in multi-compartmental cable models (Lindsay et al. 2005)
|
411. |
Inferior Olive, subthreshold oscillations (Torben-Nielsen, Segev, Yarom 2012)
|
412. |
Inferring connection proximity in electrically coupled networks (Cali et al. 2007)
|
413. |
Influence of dendritic structure on neocortical neuron firing patterns (Mainen and Sejnowski 1996)
|
414. |
Information transmission in cerebellar granule cell models (Rossert et al. 2014)
|
415. |
Infraslow intrinsic rhythmogenesis in a subset of AOB projection neurons (Gorin et al 2016)
|
416. |
Inhibition of bAPs and Ca2+ spikes in a multi-compartment pyramidal neuron model (Wilmes et al 2016)
|
417. |
Input Fluctuations effects on f-I curves (Arsiero et al. 2007)
|
418. |
Interacting synaptic conductances during, distorting, voltage clamp (Poleg-Polsky and Diamond 2011)
|
419. |
Interaural time difference detection by slowly integrating neurons (Vasilkov Tikidji-Hamburyan 2012)
|
420. |
Interneuron Specific 3 Interneuron Model (Guet-McCreight et al, 2016)
|
421. |
Intracortical synaptic potential modulation by presynaptic somatic potential (Shu et al. 2006, 2007)
|
422. |
Intrinsic sensory neurons of the gut (Chambers et al. 2014)
|
423. |
Inverse stochastic resonance of cerebellar Purkinje cell (Buchin et al. 2016)
|
424. |
Ion channel modeling with whole cell and a genetic algorithm (Gurkiewicz and Korngreen 2007)
|
425. |
Ionic mechanisms of dendritic spikes (Almog and Korngreen 2014)
|
426. |
Irregular oscillations produced by cyclic recurrent inhibition (Friesen, Friesen 1994)
|
427. |
Irregular spiking in NMDA-driven prefrontal cortex neurons (Durstewitz and Gabriel 2006)
|
428. |
JitCon: Just in time connectivity for large spiking networks (Lytton et al. 2008)
|
429. |
Kernel method to calculate LFPs from networks of point neurons (Telenczuk et al 2020)
|
430. |
Ketamine disrupts theta modulation of gamma in a computer model of hippocampus (Neymotin et al 2011)
|
431. |
Kinetic NMDA receptor model (Kampa et al 2004)
|
432. |
Kinetic synaptic models applicable to building networks (Destexhe et al 1998)
|
433. |
Knox implementation of Destexhe 1998 spike and wave oscillation model (Knox et al 2018)
|
434. |
KV1 channel governs cerebellar output to thalamus (Ovsepian et al. 2013)
|
435. |
L5 PFC microcircuit used to study persistent activity (Papoutsi et al. 2014, 2013)
|
436. |
L5 PFC pyramidal neurons (Papoutsi et al. 2017)
|
437. |
L5 pyr. cell spiking control by oscillatory inhibition in distal apical dendrites (Li et al 2013)
|
438. |
L5 pyramidal neuron myelination increases analog-digital facilitation extent (Zbili & Debanne 2020)
|
439. |
L5b PC model constrained for BAC firing and perisomatic current step firing (Hay et al., 2011)
|
440. |
Large scale model of the olfactory bulb (Yu et al., 2013)
|
441. |
Lateral dendrodenditic inhibition in the Olfactory Bulb (David et al. 2008)
|
442. |
Layer 5 Pyramidal Neuron (Shai et al., 2015)
|
443. |
Layer V PFC pyramidal neuron used to study persistent activity (Sidiropoulou & Poirazi 2012)
|
444. |
Layer V pyramidal cell functions and schizophrenia genetics (Mäki-Marttunen et al 2019)
|
445. |
Layer V pyramidal cell model with reduced morphology (Mäki-Marttunen et al 2018)
|
446. |
LCN-HippoModel: model of CA1 PCs deep-superficial theta firing dynamics (Navas-Olive et al 2020)
|
447. |
Learning spatial transformations through STDP (Davison, Frégnac 2006)
|
448. |
Leech Mechanosensory Neurons: Synaptic Facilitation by Reflected APs (Baccus 1998)
|
449. |
LFP in striatum (Tanaka & Nakamura 2019)
|
450. |
LGMD - ON excitation to dendritic field C
|
451. |
LGMD impedance (Dewell & Gabbiani 2019)
|
452. |
LGMD Variability and logarithmic compression in dendrites (Jones and Gabbiani, 2012, 2012B)
|
453. |
LGMD with 3D morphology and active dendrites (Dewell & Gabbiani 2018)
|
454. |
Library of biophysically detailed striatal projection neurons (Lindroos and Hellgren Kotaleski 2020)
|
455. |
Lillie Transition: onset of saltatory conduction in myelinating axons (Young et al. 2013)
|
456. |
Linear vs non-linear integration in CA1 oblique dendrites (Gómez González et al. 2011)
|
457. |
Local variable time step method (Lytton, Hines 2005)
|
458. |
Locust olfactory network with GGN and full KC population in the mushroom body (Ray et al 2020)
|
459. |
Long time windows from theta modulated inhib. in entorhinal–hippo. loop (Cutsuridis & Poirazi 2015)
|
460. |
Long-Term Inactivation of Na+ Channels as a Mech of Adaptation in CA1 Pyr Cells (Upchurch et al '22)
|
461. |
Look-Up Table Synapse (LUTsyn) models for AMPA and NMDA (Pham et al., 2021)
|
462. |
Low Threshold Calcium Currents in TC cells (Destexhe et al 1998)
|
463. |
LTP in cerebellar mossy fiber-granule cell synapses (Saftenku 2002)
|
464. |
Mammalian Ventricular Cell (Beeler and Reuter 1977)
|
465. |
Mapping function onto neuronal morphology (Stiefel and Sejnowski 2007)
|
466. |
Mathematical model for windup (Aguiar et al. 2010)
|
467. |
Maximal firing rate in midbrain dopamine neurons (Knowlton et al., accepted)
|
468. |
MEC layer II stellate cell: Synaptic mechanisms of grid cells (Schmidt-Hieber & Hausser 2013)
|
469. |
Mechanisms of fast rhythmic bursting in a layer 2/3 cortical neuron (Traub et al 2003)
|
470. |
Mechanisms of magnetic stimulation of central nervous system neurons (Pashut et al. 2011)
|
471. |
Mechanisms underlying subunit independence in pyramidal neuron dendrites (Behabadi and Mel 2014)
|
472. |
Medial vestibular neuron models (Quadroni and Knopfel 1994)
|
473. |
MEG of Somatosensory Neocortex (Jones et al. 2007)
|
474. |
Membrane electrical properties of mouse CA1 pyramidal cells during strong inputs (Bianchi et al 22)
|
475. |
Membrane potential changes in dendritic spines during APs and synaptic input (Palmer & Stuart 2009)
|
476. |
Mice Somatosensory L2/3 Pyramidal cells (Iascone et al 2020)
|
477. |
Microcircuits of L5 thick tufted pyramidal cells (Hay & Segev 2015)
|
478. |
Midbrain dopamine neuron: firing patterns (Canavier 1999)
|
479. |
Mirror Neuron (Antunes et al 2017)
|
480. |
Mitral cell activity gating by respiration and inhibition in an olfactory bulb NN (Short et al 2016)
|
481. |
MNTB Neuron: Kv3.1 currents (Wang et al 1998)
|
482. |
Model of arrhythmias in a cardiac cells network (Casaleggio et al. 2014)
|
483. |
Model of CA1 activity during working memory task (Spera et al. 2016)
|
484. |
Model of peripheral nerve with ephaptic coupling (Capllonch-Juan & Sepulveda 2020)
|
485. |
Model of repetitive firing in Grueneberg ganglion olfactory neurons (Liu et al., 2012)
|
486. |
Model of SK current`s influence on precision in Globus Pallidus Neurons (Deister et al. 2009)
|
487. |
Model of the cerebellar granular network (Sudhakar et al 2017)
|
488. |
Model of the Xenopus tadpole swimming spinal network (Roberts et al. 2014)
|
489. |
Model of Type 3 firing in neurons (Clay et al 2008)
|
490. |
Modeling a Nociceptive Neuro-Immune Synapse Activated by ATP and 5-HT in Meninges (Suleimanova et al., 2020)
|
491. |
Modeling dentate granule cells heterosynaptic plasticity using STDP-BCM rule (Jedlicka et al. 2015)
|
492. |
Modeling local field potentials (Bedard et al. 2004)
|
493. |
Modeling single neuron LFPs and extracellular potentials with LFPsim (Parasuram et al. 2016)
|
494. |
Modelling platform of the cochlear nucleus and other auditory circuits (Manis & Compagnola 2018)
|
495. |
Modelling reduced excitability in aged CA1 neurons as a Ca-dependent process (Markaki et al. 2005)
|
496. |
Models of Na channels from a paper on the PKC control of I Na,P (Baker 2005)
|
497. |
ModelView: online structural analysis of computational models (McDougal et al. 2015)
|
498. |
Modulation of hippocampal rhythms by electric fields and network topology (Berzhanskaya et al. 2013)
|
499. |
Modulation of temporal integration window (Migliore, Shepherd 2002)
|
500. |
Molecular layer interneurons in cerebellum encode valence in associative learning (Ma et al 2020)
|
501. |
Morphological determinants of action potential dynamics in substantia nigra (Moubarak et al 2022)
|
502. |
Motoneuron pool input-output function (Powers & Heckman 2017)
|
503. |
Motor cortex microcircuit simulation based on brain activity mapping (Chadderdon et al. 2014)
|
504. |
Motor system model with reinforcement learning drives virtual arm (Dura-Bernal et al 2017)
|
505. |
Multi-comp. CA1 O-LM interneuron model with varying dendritic Ih distributions (Sekulic et al 2015)
|
506. |
Multi-timescale adaptive threshold model (Kobayashi et al 2009) (NEURON)
|
507. |
Multicompartmental cerebellar granule cell model (Diwakar et al. 2009)
|
508. |
Multiplexed coding in Purkinje neuron dendrites (Zang and De Schutter 2021)
|
509. |
Multiplication by NMDA receptors in Direction Selective Ganglion cells (Poleg-Polsky & Diamond 2016)
|
510. |
MultiScale Optimized Neuronal Intramembrane Cavitation (SONIC) model (Lemaire et al. 2019)
|
511. |
Multiscale simulation of the striatal medium spiny neuron (Mattioni & Le Novere 2013)
|
512. |
Multitarget pharmacology for Dystonia in M1 (Neymotin et al 2016)
|
513. |
Muscle spindle feedback circuit (Moraud et al, 2016)
|
514. |
Myelinated axon conduction velocity (Brill et al 1977)
|
515. |
MyFirstNEURON (Houweling, Sejnowski 1997)
|
516. |
Na+ channel dependence of AP initiation in cortical pyramidal neuron (Kole et al. 2008)
|
517. |
Na+ Signals in olfactory bulb neurons (granule cell model) (Ona-Jodar et al. 2017)
|
518. |
NAcc medium spiny neuron: effects of cannabinoid withdrawal (Spiga et al. 2010)
|
519. |
Nav1.6 sodium channel model in globus pallidus neurons (Mercer et al. 2007)
|
520. |
Neocort. pyramidal cells subthreshold somatic voltage controls spike propagation (Munro Kopell 2012)
|
521. |
Neocortical Layer I: I-A and I-K (Zhou, Hablitz 1996)
|
522. |
Neocortical pyramidal neuron: deep; effects of dopamine (Durstewitz et al 2000)
|
523. |
Nerve terminal currents at lizard neuromuscular junction (Lindgren, Moore 1989)
|
524. |
Network recruitment to coherent oscillations in a hippocampal model (Stacey et al. 2011)
|
525. |
Networks of spiking neurons: a review of tools and strategies (Brette et al. 2007)
|
526. |
Neural Query System NQS Data-Mining From Within the NEURON Simulator (Lytton 2006)
|
527. |
NeuroGPU example on L5_TTPC1_cADpyr232_1 (Ben-Shalom 2022)(Ramaswamy et al., 2015)
|
528. |
Neuromusculoskeletal modeling with neural and finite element models (Volk et al, 2021)
|
529. |
NEURON + Python (Hines et al. 2009)
|
530. |
NEURON interfaces to MySQL and the SPUD feature extraction algorithm (Neymotin et al. 2008)
|
531. |
Neuronal dendrite calcium wave model (Neymotin et al, 2015)
|
532. |
Neuronal morphology goes digital ... (Parekh & Ascoli 2013)
|
533. |
Neurophysiological impact of inactivation pathways in A-type K+ channels (Fineberg et al 2012)
|
534. |
Nigral dopaminergic neurons: effects of ethanol on Ih (Migliore et al. 2008)
|
535. |
NMDA receptor saturation (Chen et al 2001)
|
536. |
NMDA receptors enhance the fidelity of synaptic integration (Li and Gulledge 2021)
|
537. |
NMDA spikes in basal dendrites of L5 pyramidal neurons (Polsky et al. 2009)
|
538. |
NN activity impact on neocortical pyr. neurons integrative properties in vivo (Destexhe & Pare 1999)
|
539. |
Nonlinear dendritic processing in barrel cortex spiny stellate neurons (Lavzin et al. 2012)
|
540. |
Norepinephrine stimulates glycogenolysis in astrocytes to fuel neurons (Coggan et al 2018)
|
541. |
Normal ripples, abnormal ripples, and fast ripples in a hippocampal model (Fink et al. 2015)
|
542. |
Novel Na current with slow de-inactivation (Tsutsui, Oka 2002)
|
543. |
O-LM interneuron model (Lawrence et al. 2006)
|
544. |
Olfactory bulb cluster formation (Migliore et al. 2010)
|
545. |
Olfactory bulb granule cell: effects of odor deprivation (Saghatelyan et al 2005)
|
546. |
Olfactory bulb mitral and granule cell column formation (Migliore et al. 2007)
|
547. |
Olfactory bulb mitral and granule cell: dendrodendritic microcircuits (Migliore and Shepherd 2008)
|
548. |
Olfactory bulb mitral cell gap junction NN model: burst firing and synchrony (O`Connor et al. 2012)
|
549. |
Olfactory bulb mitral cell: synchronization by gap junctions (Migliore et al 2005)
|
550. |
Olfactory Bulb Network (Davison et al 2003)
|
551. |
Olfactory Computations in Mitral-Granule cell circuits (Migliore & McTavish 2013)
|
552. |
Olfactory Mitral Cell (Bhalla, Bower 1993)
|
553. |
Olfactory Mitral Cell (Davison et al 2000)
|
554. |
Olfactory Mitral cell: AP initiation modes (Chen et al 2002)
|
555. |
Olfactory Mitral Cell: I-A and I-K currents (Wang et al 1996)
|
556. |
Olfactory Periglomerular Cells: I-h kinetics (Cadetti, Belluzzi 2001)
|
557. |
Optical stimulation of a channelrhodopsin-2 positive pyramidal neuron model (Foutz et al 2012)
|
558. |
Optimal balance predicts/explains amplitude and decay time of iPSGs (Kim & Fiorillo 2017)
|
559. |
Orientation preference in L23 V1 pyramidal neurons (Park et al 2019)
|
560. |
Oscillating neurons in the cochlear nucleus (Bahmer Langner 2006a, b, and 2007)
|
561. |
Paradoxical effect of fAHP amplitude on gain in dentate gyrus granule cells (Jaffe & Brenner 2018)
|
562. |
Parallel network simulations with NEURON (Migliore et al 2006)
|
563. |
Parallel odor processing by mitral and middle tufted cells in the OB (Cavarretta et al 2016, 2018)
|
564. |
Parallelizing large networks in NEURON (Lytton et al. 2016)
|
565. |
Parametric computation and persistent gamma in a cortical model (Chambers et al. 2012)
|
566. |
Parvalbumin-positive basket cells differentiate among hippocampal pyramidal cells (Lee et al. 2014)
|
567. |
Phase response curve of a globus pallidal neuron (Fujita et al. 2011)
|
568. |
Phase response curves firing rate dependency of rat purkinje neurons in vitro (Couto et al 2015)
|
569. |
Phase response theory in sparsely + strongly connected inhibitory NNs (Tikidji-Hamburyan et al 2019)
|
570. |
Phenomenological models of NaV1.5: Hodgkin-Huxley and kinetic formalisms (Andreozzi et al 2019)
|
571. |
PIR gamma oscillations in network of resonators (Tikidji-Hamburyan et al. 2015)
|
572. |
Pleiotropic effects of SCZ-associated genes (Mäki-Marttunen et al. 2017)
|
573. |
Potjans-Diesmann cortical microcircuit model in NetPyNE (Romaro et al 2021)
|
574. |
pre-Bötzinger complex variability (Fietkiewicz et al. 2016)
|
575. |
Preserving axosomatic spiking features despite diverse dendritic morphology (Hay et al., 2013)
|
576. |
Presynaptic calcium dynamics at neuromuscular junction (Stockbridge, Moore 1984)
|
577. |
Principles governing the operation of synaptic inhibition in dendrites (Gidon & Segev 2012)
|
578. |
Prosthetic electrostimulation for information flow repair in a neocortical simulation (Kerr 2012)
|
579. |
Purkinje cell: Synaptic activation predicts voltage control of burst-pause (Masoli & D'Angelo 2017)
|
580. |
Purkinje neuron network (Zang et al. 2020)
|
581. |
Pyramidal neuron coincidence detection tuned by dendritic branching pattern (Schaefer et al 2003)
|
582. |
Pyramidal neuron conductances state and STDP (Delgado et al. 2010)
|
583. |
Pyramidal Neuron Deep: attenuation in dendrites (Stuart, Spruston 1998)
|
584. |
Pyramidal Neuron Deep: K+ kinetics (Korngreen, Sakmann 2000)
|
585. |
Pyramidal neuron, fast, regular, and irregular spiking interneurons (Konstantoudaki et al 2014)
|
586. |
Pyramidal Neuron: Deep, Thalamic Relay and Reticular, Interneuron (Destexhe et al 1998, 2001)
|
587. |
Pyramidal neurons with mutated SCN2A gene (Nav1.2) (Ben-Shalom et al 2017)
|
588. |
Rat LGN Thalamocortical Neuron (Connelly et al 2015, 2016)
|
589. |
Rat subthalamic projection neuron (Gillies and Willshaw 2006)
|
590. |
Reaction-diffusion in the NEURON simulator (McDougal et al 2013)
|
591. |
Realistic amplifier model (Oláh et al. 2021)
|
592. |
Reciprocal regulation of rod and cone synapse by NO (Kourennyi et al 2004)
|
593. |
Reconstructing cerebellar granule layer evoked LFP using convolution (ReConv) (Diwakar et al. 2011)
|
594. |
Recording from rod bipolar axon terminals in situ (Oltedal et al 2007)
|
595. |
Recurrent discharge in a reduced model of cat spinal motoneuron (Balbi et al, 2013)
|
596. |
Reduced-morphology model of CA1 pyramidal cells optimized + validated w/ HippoUnit (Tomko et al '21)
|
597. |
Regulation of a slow STG rhythm (Nadim et al 1998)
|
598. |
Regulation of firing frequency in a midbrain dopaminergic neuron model (Kuznetsova et al. 2010)
|
599. |
Regulation of motoneuron excitability by KCNQ/Kv7 modulators (Lombardo & Harrington 2016)
|
600. |
Regulation of the firing pattern in dopamine neurons (Komendantov et al 2004)
|
601. |
Reinforcement learning of targeted movement (Chadderdon et al. 2012)
|
602. |
Rejuvenation model of dopamine neuron (Chan et al. 2007)
|
603. |
Resonance properties through Chirp stimulus responses (Narayanan Johnston 2007, 2008)
|
604. |
Response properties of neocort. neurons to temporally modulated noisy inputs (Koendgen et al. 2008)
|
605. |
Retinal Ganglion Cell: I-A (Benison et al 2001)
|
606. |
Retinal Ganglion Cell: I-CaN and I-CaL (Benison et al. 2001)
|
607. |
Retinal Ganglion Cell: I-K (Skaliora et al 1995)
|
608. |
Retinal Ganglion Cell: I-Na,t (Benison et al 2001)
|
609. |
Retinal ganglion cells responses and activity (Tsai et al 2012, Guo et al 2016)
|
610. |
Retinal Photoreceptor: I Potassium (Beech, Barnes 1989)
|
611. |
Rhesus Monkey Layer 3 Pyramidal Neurons: V1 vs PFC (Amatrudo, Weaver et al. 2012)
|
612. |
Rhesus Monkey Layer 3 Pyramidal Neurons: Young vs aged PFC (Coskren et al. 2015)
|
613. |
Rhesus Monkey Young and Aged L3 PFC Pyramidal Neurons (Rumbell et al. 2016)
|
614. |
Ribbon Synapse (Sikora et al 2005)
|
615. |
Rod photoreceptor (Barnes and Hille 1989, Publio et al. 2006, Kourennyi and Liu et al. 2004)
|
616. |
Role for short term plasticity and OLM cells in containing spread of excitation (Hummos et al 2014)
|
617. |
Role of afferent-hair cell connectivity in determining spike train regularity (Holmes et al 2017)
|
618. |
Role of Ih in firing patterns of cold thermoreceptors (Orio et al., 2012)
|
619. |
Role of the AIS in the control of spontaneous frequency of dopaminergic neurons (Meza et al 2017)
|
620. |
Salamander retinal ganglian cells: morphology influences firing (Sheasby, Fohlmeister 1999)
|
621. |
Salamander retinal ganglion cell: ion channels (Fohlmeister, Miller 1997)
|
622. |
Schiz.-linked gene effects on intrinsic single-neuron excitability (Maki-Marttunen et al. 2016)
|
623. |
SCN1A gain-of-function in early infantile encephalopathy (Berecki et al 2019)
|
624. |
SCZ-associated variant effects on L5 pyr cell NN activity and delta osc. (Maki-Marttunen et al 2018)
|
625. |
Selective control of cortical axonal spikes by a slowly inactivating K+ current (Shu et al. 2007)
|
626. |
Sensorimotor cortex reinforcement learning of 2-joint virtual arm reaching (Neymotin et al. 2013)
|
627. |
Sensory-evoked responses of L5 pyramidal tract neurons (Egger et al 2020)
|
628. |
Shaping NMDA spikes by timed synaptic inhibition on L5PC (Doron et al. 2017)
|
629. |
Shaping of action potentials by different types of BK channels (Jaffe et al., 2011)
|
630. |
Short term plasticity at the cerebellar granule cell (Nieus et al. 2006)
|
631. |
Short term plasticity of synapses onto V1 layer 2/3 pyramidal neuron (Varela et al 1997)
|
632. |
Signal integration in a CA1 pyramidal cell (Graham 2001)
|
633. |
Signal integration in LGN cells (Briska et al 2003)
|
634. |
Simple and accurate Diffusion Approximation algor. for stochastic ion channels (Orio & Soudry 2012)
|
635. |
Simulated cortical color opponent receptive fields self-organize via STDP (Eguchi et al., 2014)
|
636. |
Simulated light response in rod photoreceptors (Liu and Kourennyi 2004)
|
637. |
Simulations of modulation of HCN channels in L5PCs (Mäki-Marttunen and Mäki-Marttunen accepted)
|
638. |
Simulations of motor unit discharge patterns (Powers et al. 2011)
|
639. |
Single compartment Dorsal Lateral Medium Spiny Neuron w/ NMDA and AMPA (Biddell and Johnson 2013)
|
640. |
Single compartment: nonlinear a5-GABAAR controls synaptic NMDAR activation (Schulz et al 2018)
|
641. |
Single E-I oscillating network with amplitude modulation (Avella Gonzalez et al. 2012)
|
642. |
Single excitatory axons form clustered synapses onto CA1 pyramidal cell dendrites (Bloss et al 2018)
|
643. |
Site of impulse initiation in a neuron (Moore et al 1983)
|
644. |
Small world networks of Type I and Type II Excitable Neurons (Bogaard et al. 2009)
|
645. |
Sodium channel mutations causing generalized epilepsy with febrile seizures + (Barela et al. 2006)
|
646. |
Sodium currents activate without a delay (Baranauskas and Martina 2006)
|
647. |
Sodium potassium ATPase pump (Chapman et al. 1983)
|
648. |
Sound-evoked activity in peripheral axons of type I spiral ganglion neurons (Budak et al. 2021)
|
649. |
Space clamp problems in neurons with voltage-gated conductances (Bar-Yehuda and Korngreen 2008)
|
650. |
Spatial constrains of GABAergic rheobase shift (Lombardi et al., accepted)
|
651. |
Spatial gridding and temporal accuracy in NEURON (Hines and Carnevale 2001)
|
652. |
Spike burst-pause dynamics of Purkinje cells regulate sensorimotor adaptation (Luque et al 2019)
|
653. |
Spike exchange methods for a Blue Gene/P supercomputer (Hines et al., 2011)
|
654. |
Spike frequency adaptation in spinal sensory neurones (Melnick et al 2004)
|
655. |
Spike Initiation in Neocortical Pyramidal Neurons (Mainen et al 1995)
|
656. |
Spike propagation in dendrites with stochastic ion channels (Diba et al. 2006)
|
657. |
Spike repolarization in axon collaterals (Foust et al. 2011)
|
658. |
Spike-timing dependent inhibitory plasticity for gating bAPs (Wilmes et al 2017)
|
659. |
Spikelet generation and AP initiation in a L5 neocortical pyr neuron (Michalikova et al. 2017) Fig 1
|
660. |
Spikelet generation and AP initiation in a simplified pyr neuron (Michalikova et al. 2017) Fig 3
|
661. |
Spinal Dorsal Horn Network Model (Medlock et al 2022)
|
662. |
Spinal motoneuron recruitment regulated by ionic channels during fictive locomotion (Zhang & Dai 20)
|
663. |
Spinal Motor Neuron (Dodge, Cooley 1973)
|
664. |
Spinal Motor Neuron (McIntyre et al 2002)
|
665. |
Spinal Motor Neuron: Na, K_A, and K_DR currents (Safronov, Vogel 1995)
|
666. |
Spine fusion and branching affects synaptic response (Rusakov et al 1996, 1997)
|
667. |
Spine head calcium in a CA1 pyramidal cell model (Graham et al. 2014)
|
668. |
Spine neck plasticity controls postsynaptic calcium signals (Grunditz et al. 2008)
|
669. |
Spiny neuron model with dopamine-induced bistability (Gruber et al 2003)
|
670. |
Spontaneous firing caused by stochastic channel gating (Chow, White 1996)
|
671. |
Spreading Depolarization in Brain Slices (Kelley et al. 2022)
|
672. |
Squid axon (Hodgkin, Huxley 1952) (NEURON)
|
673. |
State and location dependence of action potential metabolic cost (Hallermann et al., 2012)
|
674. |
State dependent drug binding to sodium channels in the dentate gyrus (Thomas & Petrou 2013)
|
675. |
Status epilepticus alters dentate basket cell tonic inhibition (Yu J et al 2013)
|
676. |
STD-dependent and independent encoding of Input irregularity as spike rate (Luthman et al. 2011)
|
677. |
STDP and BDNF in CA1 spines (Solinas et al. 2019)
|
678. |
STDP depends on dendritic synapse location (Letzkus et al. 2006)
|
679. |
Steady-state Vm distribution of neurons subject to synaptic noise (Rudolph, Destexhe 2005)
|
680. |
Stochastic 3D model of neonatal rat spinal motoneuron (Ostroumov 2007)
|
681. |
Stochastic Ih and Na-channels in pyramidal neuron dendrites (Kole et al 2006)
|
682. |
Stochastic layer V pyramidal neuron: interpulse interval coding and noise (Singh & Levy 2017)
|
683. |
Storing serial order in intrinsic excitability: a working memory model (Conde-Sousa & Aguiar 2013)
|
684. |
Striatal D1R medium spiny neuron, including a subcellular DA cascade (Lindroos et al 2018)
|
685. |
Striatal Output Neuron (Mahon, Deniau, Charpier, Delord 2000)
|
686. |
Submyelin Potassium accumulation in Subthalamic neuron (STN) axons (Bellinger et al. 2008)
|
687. |
Subthreshold inact. of K channels modulates APs in bitufted interneurons (Korngreen et al 2005)
|
688. |
Superior paraolivary nucleus neuron (Kopp-Scheinpflug et al. 2011)
|
689. |
Survey of electrically evoked responses in the retina (Tsai et al 2017)
|
690. |
Sympathetic Preganglionic Neurone (Briant et al. 2014)
|
691. |
Synaptic gating at axonal branches, and sharp-wave ripples with replay (Vladimirov et al. 2013)
|
692. |
Synaptic information transfer in computer models of neocortical columns (Neymotin et al. 2010)
|
693. |
Synaptic integration by MEC neurons (Justus et al. 2017)
|
694. |
Synaptic integration in a model of granule cells (Gabbiani et al 1994)
|
695. |
Synaptic integration in tuft dendrites of layer 5 pyramidal neurons (Larkum et al. 2009)
|
696. |
Synaptic plasticity: pyramid->pyr and pyr->interneuron (Tsodyks et al 1998)
|
697. |
Synaptic scaling balances learning in a spiking model of neocortex (Rowan & Neymotin 2013)
|
698. |
Synaptic transmission at the calyx of Held (Graham et al 2001)
|
699. |
Synchrony by synapse location (McTavish et al. 2012)
|
700. |
Synthesis of spatial tuning functions from theta cell spike trains (Welday et al., 2011)
|
701. |
T channel currents (Vitko et al 2005)
|
702. |
T-type Ca current in thalamic neurons (Wang et al 1991)
|
703. |
T-type Calcium currents (McRory et al 2001)
|
704. |
Temperature sensitive axon models (DeMaegd & Stein 2020)
|
705. |
Temperature-Sensitive conduction at axon branch points (Westerfield et al 1978)
|
706. |
Thalamic interneuron multicompartment model (Zhu et al. 1999)
|
707. |
Thalamic network model of deep brain stimulation in essential tremor (Birdno et al. 2012)
|
708. |
Thalamic neuron: Modeling rhythmic neuronal activity (Meuth et al. 2005)
|
709. |
Thalamic quiescence of spike and wave seizures (Lytton et al 1997)
|
710. |
Thalamic Relay Neuron: I-h (McCormick, Pape 1990)
|
711. |
Thalamic Relay Neuron: I-T current (Williams, Stuart 2000)
|
712. |
Thalamic Reticular Network (Destexhe et al 1994)
|
713. |
Thalamic reticular neurons: the role of Ca currents (Destexhe et al 1996)
|
714. |
Thalamocortical and Thalamic Reticular Network (Destexhe et al 1996)
|
715. |
Thalamocortical augmenting response (Bazhenov et al 1998)
|
716. |
Thalamocortical Relay cell under current clamp in high-conductance state (Zeldenrust et al 2018)
|
717. |
Thalamocortical relay neuron models constrained by experiment and optimization (Iavarone et al 2019)
|
718. |
The APP in C-terminal domain alters CA1 neuron firing (Pousinha et al 2019)
|
719. |
The cannula artifact (Chandler & Hodgkin 1965)
|
720. |
The subcellular distribution of T-type Ca2+ channels in LGN interneurons (Allken et al. 2014)
|
721. |
The virtual slice setup (Lytton et al. 2008)
|
722. |
Tight junction model of CNS myelinated axons (Devaux and Gow 2008)
|
723. |
Tonic firing in substantia gelatinosa neurons (Melnick et al 2004)
|
724. |
Tonic neuron in spinal lamina I: prolongation of subthreshold depol. (Prescott and De Koninck 2005)
|
725. |
Tonic-clonic transitions in a seizure simulation (Lytton and Omurtag 2007)
|
726. |
Transfer properties of Neuronal Dendrites (Korogod et al 1998)
|
727. |
Translating network models to parallel hardware in NEURON (Hines and Carnevale 2008)
|
728. |
TRPM8-dependent dynamic response in cold thermoreceptors (Olivares et al. 2015)
|
729. |
TTX-R Na+ current effect on cell response (Herzog et al 2001)
|
730. |
Two populations of excitatory neurons in the superficial retrosplenial cortex (Brennan et al 2020)
|
731. |
Updated Tritonia Swim CPG (Calin-Jagemann et al. 2007)
|
732. |
Using NEURON for reaction-diffusion modeling of extracellular dynamics (Newton et al 2018)
|
733. |
Using Strahler's analysis to reduce realistic models (Marasco et al, 2013)
|
734. |
Ventromedial Thalamocortical Neuron (Bichler et al 2021)
|
735. |
Vertical system (VS) fly cells with biophysics (Dan et al 2018)
|
736. |
Visual Cortex Neurons: Dendritic computations (Archie, Mel 2000)
|
737. |
Visual Cortex Neurons: Dendritic study (Anderson et al 1999)
|
738. |
Voltage and light-sensitive Channelrhodopsin-2 model (ChR2-H134R) (Williams et al. 2013) (NEURON)
|
739. |
Voltage- and Branch-specific Climbing Fiber Responses in Purkinje Cells (Zang et al 2018)
|
740. |
Voltage-based STDP synapse (Clopath et al. 2010)
|
741. |
Vomeronasal sensory neuron (Shimazaki et al 2006)
|
742. |
VTA neurons: Morphofunctional alterations in acute opiates withdrawal (Enrico et al. 2016)
|
743. |
Xenopus Myelinated Neuron (Frankenhaeuser, Huxley 1964)
|
744. |
Zebrafish Mauthner-cell model (Watanabe et al 2017)
|