| 1 |
A 1000 cell network model for Lateral Amygdala (Kim et al. 2013) |
| 2 |
A focal seizure model with ion concentration changes (Gentiletti et al., 2022) |
| 3 |
A Model Circuit of Thalamocortical Convergence (Behuret et al. 2013) |
| 4 |
A model of the T-junction of a C-fiber sensory neuron (Sundt et al. 2015) |
| 5 |
A model of ventral Hippocampal CA1 pyramidal neurons of Tg2576 AD mice (Spoleti et al. 2021) |
| 6 |
A modified Morris-Lecar model with gM and gAHP (Yang et al., 2022) |
| 7 |
A Moth MGC Model-A HH network with quantitative rate reduction (Buckley & Nowotny 2011) |
| 8 |
A multilayer cortical model to study seizure propagation across microdomains (Basu et al. 2015) |
| 9 |
A set of reduced models of layer 5 pyramidal neurons (Bahl et al. 2012) |
| 10 |
A simplified cerebellar Purkinje neuron (the PPR model) (Brown et al. 2011) |
| 11 |
A single column thalamocortical network model (Traub et al 2005) |
| 12 |
A two-layer biophysical olfactory bulb model of cholinergic neuromodulation (Li and Cleland 2013) |
| 13 |
Action Potential initiation and backpropagation in Neocortical L5 Pyramidal Neuron (Hu et al. 2009) |
| 14 |
Alcohol action in a detailed Purkinje neuron model and an efficient simplified model (Forrest 2015) |
| 15 |
Allen Institute: Gad2-IRES-Cre VISp layer 5 472447460 |
| 16 |
Allen Institute: Gad2-IRES-Cre VISp layer 5 473561729 |
| 17 |
Allen Institute: Htr3a-Cre VISp layer 2/3 472352327 |
| 18 |
Allen Institute: Htr3a-Cre VISp layer 2/3 472421285 |
| 19 |
Allen Institute: Nr5a1-Cre VISp layer 2/3 473862496 |
| 20 |
Allen Institute: Nr5a1-Cre VISp layer 4 329322394 |
| 21 |
Allen Institute: Nr5a1-Cre VISp layer 4 472306544 |
| 22 |
Allen Institute: Nr5a1-Cre VISp layer 4 472442377 |
| 23 |
Allen Institute: Nr5a1-Cre VISp layer 4 472451419 |
| 24 |
Allen Institute: Nr5a1-Cre VISp layer 4 472915634 |
| 25 |
Allen Institute: Nr5a1-Cre VISp layer 4 473834758 |
| 26 |
Allen Institute: Nr5a1-Cre VISp layer 4 473863035 |
| 27 |
Allen Institute: Nr5a1-Cre VISp layer 4 473871429 |
| 28 |
Allen Institute: Ntsr1-Cre VISp layer 4 472430904 |
| 29 |
Allen Institute: Pvalb-IRES-Cre VISp layer 2/3 472306616 |
| 30 |
Allen Institute: Pvalb-IRES-Cre VISp layer 5 471085845 |
| 31 |
Allen Institute: Pvalb-IRES-Cre VISp layer 5 472349114 |
| 32 |
Allen Institute: Pvalb-IRES-Cre VISp layer 5 472912177 |
| 33 |
Allen Institute: Pvalb-IRES-Cre VISp layer 5 473465774 |
| 34 |
Allen Institute: Pvalb-IRES-Cre VISp layer 5 473862421 |
| 35 |
Allen Institute: Pvalb-IRES-Cre VISp layer 6a 471081668 |
| 36 |
Allen Institute: Pvalb-IRES-Cre VISp layer 6a 472301074 |
| 37 |
Allen Institute: Pvalb-IRES-Cre VISp layer 6a 473860269 |
| 38 |
Allen Institute: Rbp4-Cre VISp layer 5 472424854 |
| 39 |
Allen Institute: Rbp4-Cre VISp layer 6a 473871592 |
| 40 |
Allen Institute: Rorb-IRES2-Cre-D VISp layer 2/3 472299294 |
| 41 |
Allen Institute: Rorb-IRES2-Cre-D VISp layer 2/3 472434498 |
| 42 |
Allen Institute: Rorb-IRES2-Cre-D VISp layer 4 473863510 |
| 43 |
Allen Institute: Rorb-IRES2-Cre-D VISp layer 5 471087975 |
| 44 |
Allen Institute: Rorb-IRES2-Cre-D VISp layer 5 473561660 |
| 45 |
Allen Institute: Scnn1a-Tg2-Cre VISp layer 4 472300877 |
| 46 |
Allen Institute: Scnn1a-Tg2-Cre VISp layer 4 472427533 |
| 47 |
Allen Institute: Scnn1a-Tg2-Cre VISp layer 4 472912107 |
| 48 |
Allen Institute: Scnn1a-Tg2-Cre VISp layer 4 473465456 |
| 49 |
Allen Institute: Scnn1a-Tg2-Cre VISp layer 5 472306460 |
| 50 |
Allen Institute: Scnn1a-Tg3-Cre VISp layer 4 329321704 |
| 51 |
Allen Institute: Scnn1a-Tg3-Cre VISp layer 4 472363762 |
| 52 |
Allen Institute: Scnn1a-Tg3-Cre VISp layer 4 473862845 |
| 53 |
Allen Institute: Scnn1a-Tg3-Cre VISp layer 4 473872986 |
| 54 |
Allen Institute: Scnn1a-Tg3-Cre VISp layer 5 472455509 |
| 55 |
Allen Institute: Scnn1a-Tg3-Cre VISp layer 5 473863578 |
| 56 |
Allen Institute: Scnn1a-Tg3-Cre VISp layer 5 473871773 |
| 57 |
Allen Institute: Sst-IRES-Cre VISp layer 2/3 471086533 |
| 58 |
Allen Institute: Sst-IRES-Cre VISp layer 2/3 472304676 |
| 59 |
Allen Institute: Sst-IRES-Cre VISp layer 4 472304539 |
| 60 |
Allen Institute: Sst-IRES-Cre VISp layer 5 472299363 |
| 61 |
Allen Institute: Sst-IRES-Cre VISp layer 5 472450023 |
| 62 |
Allen Institute: Sst-IRES-Cre VISp layer 5 473835796 |
| 63 |
Allen Institute: Sst-IRES-Cre VISp layer 6a 472440759 |
| 64 |
Alpha rhythm in vitro visual cortex (Traub et al 2020) |
| 65 |
Amyloid-beta effects on release probability and integration at CA3-CA1 synapses (Romani et al. 2013) |
| 66 |
AP back-prop. explains threshold variability and rapid rise (McCormick et al. 2007, Yu et al. 2008) |
| 67 |
AP initiation and propagation in type II cochlear ganglion cell (Hossain et al 2005) |
| 68 |
Apical Length Governs Computational Diversity of Layer 5 Pyramidal Neurons (Galloni et al 2020) |
| 69 |
Axonal gap junctions produce fast oscillations in cerebellar Purkinje cells (Traub et al. 2008) |
| 70 |
Axonal NaV1.6 Sodium Channels in AP Initiation of CA1 Pyramidal Neurons (Royeck et al. 2008) |
| 71 |
Axonal Projection and Interneuron Types (Helmstaedter et al. 2008) |
| 72 |
Biophysical and phenomenological models of spike-timing dependent plasticity (Badoual et al. 2006) |
| 73 |
Bursting and oscillations in RD1 Retina driven by AII Amacrine Neuron (Choi et al. 2014) |
| 74 |
Ca+/HCN channel-dependent persistent activity in multiscale model of neocortex (Neymotin et al 2016) |
| 75 |
CA1 network model for place cell dynamics (Turi et al 2019) |
| 76 |
CA1 network model: interneuron contributions to epileptic deficits (Shuman et al 2020) |
| 77 |
CA1 pyramidal cell: I_NaP and I_M contributions to somatic bursting (Golomb et al 2006) |
| 78 |
CA1 pyramidal cell: reconstructed axonal arbor and failures at weak gap junctions (Vladimirov 2011) |
| 79 |
CA1 pyramidal neuron (Combe et al 2018) |
| 80 |
CA1 pyramidal neuron to study INaP properties and repetitive firing (Uebachs et al. 2010) |
| 81 |
CA1 pyramidal neuron: as a 2-layer NN and subthreshold synaptic summation (Poirazi et al 2003) |
| 82 |
CA1 pyramidal neuron: depolarization block (Bianchi et al. 2012) |
| 83 |
CA1 pyramidal neuron: effects of R213Q and R312W Kv7.2 mutations (Miceli et al. 2013) |
| 84 |
CA1 pyramidal neuron: functional significance of axonal Kv7 channels (Shah et al. 2008) |
| 85 |
CA1 pyramidal neuron: Ih current (Migliore et al. 2012) |
| 86 |
CA1 pyramidal neuron: Persistent Na current mediates steep synaptic amplification (Hsu et al 2018) |
| 87 |
CA1 Pyramidal Neuron: slow Na+ inactivation (Migliore 1996) |
| 88 |
CA1 pyramidal neuron: synaptically-induced bAP predicts synapse location (Sterratt et al. 2012) |
| 89 |
CA1 pyramidal neurons: effects of a Kv7.2 mutation (Miceli et al. 2009) |
| 90 |
CA1 pyramidal neurons: effects of Kv7 (M-) channels on synaptic integration (Shah et al. 2011) |
| 91 |
CA1 pyramidal populations after high frequency head impacts (Chapman, et al., 2023) |
| 92 |
CA3 pyramidal neuron (Lazarewicz et al 2002) |
| 93 |
CA3 Pyramidal Neuron (Migliore et al 1995) |
| 94 |
CA3 pyramidal neuron (Safiulina et al. 2010) |
| 95 |
CA3 pyramidal neuron: firing properties (Hemond et al. 2008) |
| 96 |
Cerebellar Golgi cell (Solinas et al. 2007a, 2007b) |
| 97 |
Cerebellar purkinje cell (De Schutter and Bower 1994) |
| 98 |
Cerebellar purkinje cell: K and Ca channels regulate APs (Miyasho et al 2001) |
| 99 |
Cerebellum granule cell FHF (Dover et al. 2016) |
| 100 |
Changes of ionic concentrations during seizure transitions (Gentiletti et al. 2016) |
| 101 |
Channel density variability among CA1 neurons (Migliore et al. 2018) |
| 102 |
Circadian rhythmicity shapes astrocyte morphology and neuronal function in CA1 (McCauley et al 2020) |
| 103 |
Collection of simulated data from a thalamocortical network model (Glabska, Chintaluri, Wojcik 2017) |
| 104 |
Complex CA1-neuron to study AP initiation (Wimmer et al. 2010) |
| 105 |
Computational aspects of feedback in neural circuits (Maass et al 2006) |
| 106 |
Computational model of bladder small DRG neuron soma (Mandge & Manchanda 2018) |
| 107 |
Conductance-based model of rodent thoracic sympathetic postganglionic neuron (McKinnon et al 2019) |
| 108 |
Control of vibrissa motoneuron firing (Harish and Golomb 2010) |
| 109 |
Correcting space clamp in dendrites (Schaefer et al. 2003 and 2007) |
| 110 |
Cortical pyramidal neuron, phase response curve (Stiefel et al 2009) |
| 111 |
Current Dipole in Laminar Neocortex (Lee et al. 2013) |
| 112 |
Data-driven, HH-type model of the lateral pyloric (LP) cell in the STG (Nowotny et al. 2008) |
| 113 |
Dendritica (Vetter et al 2001) |
| 114 |
Dentate granule cell: mAHP & sAHP; SK & Kv7/M channels (Mateos-Aparicio et al., 2014) |
| 115 |
Discharge hysteresis in motoneurons (Powers & Heckman 2015) |
| 116 |
Dopamine neuron of the vent. periaqu. gray and dors. raphe nucleus (vlPAG/DRN) (Dougalis et al 2017) |
| 117 |
Double cable myelinated axon (Layer 5 pyramidal neuron; Cohen et al 2020) |
| 118 |
Dynamic cortical interlaminar interactions (Carracedo et al. 2013) |
| 119 |
Dynamical assessment of ion channels during in vivo-like states (Guet-McCreight & Skinner 2020) |
| 120 |
Early-onset epileptic encephalopathy (Miceli et al. 2015) |
| 121 |
Effects of increasing CREB on storage and recall processes in a CA1 network (Bianchi et al. 2014) |
| 122 |
Electrodecrements in in vitro model of infantile spasms (Traub et al 2020) |
| 123 |
Engaging distinct oscillatory neocortical circuits (Vierling-Claassen et al. 2010) |
| 124 |
Firing neocortical layer V pyramidal neuron (Reetz et al. 2014; Stadler et al. 2014) |
| 125 |
Fluctuating synaptic conductances recreate in-vivo-like activity (Destexhe et al 2001) |
| 126 |
Gamma genesis in the basolateral amygdala (Feng et al 2019) |
| 127 |
GC model (Beining et al 2017) |
| 128 |
Hippocampal CA1 microcircuit model including somatic and dendritic inhibition |
| 129 |
Hippocampal CA1 pyramidal cell demonstrating dynamic mode switching (Berteau & Bullock 2020) |
| 130 |
Hippocampal Mossy Fiber bouton: presynaptic KV7 channel function (Martinello et al 2019) |
| 131 |
Hippocampus CA1 OLM cell multicompartment conductance-based model (Sun et al. 2023) |
| 132 |
Hodgkin-Huxley model of persistent activity in PFC neurons (Winograd et al. 2008) (NEURON python) |
| 133 |
Hodgkin-Huxley model of persistent activity in prefrontal cortex neurons (Winograd et al. 2008) |
| 134 |
Hodgkin-Huxley models of different classes of cortical neurons (Pospischil et al. 2008) |
| 135 |
Human Cortical L5 Pyramidal Cell (Rich et al. 2021) |
| 136 |
Human L5 Cortical Circuit (Guet-McCreight) |
| 137 |
Human layer 2/3 cortical microcircuits in health and depression (Yao et al, 2022) |
| 138 |
Hyperexcitability from Nav1.2 channel loss in neocortical pyramidal cells (Spratt et al 2021) |
| 139 |
Hysteresis in voltage gating of HCN channels (Elinder et al 2006, Mannikko et al 2005) |
| 140 |
Impact of dendritic atrophy on intrinsic and synaptic excitability (Narayanan & Chattarji, 2010) |
| 141 |
Impact of dendritic size and topology on pyramidal cell burst firing (van Elburg and van Ooyen 2010) |
| 142 |
Influence of dendritic structure on neocortical neuron firing patterns (Mainen and Sejnowski 1996) |
| 143 |
Intracortical synaptic potential modulation by presynaptic somatic potential (Shu et al. 2006, 2007) |
| 144 |
Ionic mechanisms of bursting in CA3 pyramidal neurons (Xu and Clancy 2008) |
| 145 |
Knox implementation of Destexhe 1998 spike and wave oscillation model (Knox et al 2018) |
| 146 |
L5b PC model constrained for BAC firing and perisomatic current step firing (Hay et al., 2011) |
| 147 |
Layer V pyramidal cell functions and schizophrenia genetics (Mäki-Marttunen et al 2019) |
| 148 |
Layer V pyramidal cell model with reduced morphology (Mäki-Marttunen et al 2018) |
| 149 |
LCN-HippoModel: model of CA1 PCs deep-superficial theta firing dynamics (Navas-Olive et al 2020) |
| 150 |
LGMD - ON excitation to dendritic field C |
| 151 |
LGMD impedance (Dewell & Gabbiani 2019) |
| 152 |
LGMD with 3D morphology and active dendrites (Dewell & Gabbiani 2018) |
| 153 |
Library of biophysically detailed striatal projection neurons (Lindroos and Hellgren Kotaleski 2020) |
| 154 |
LIP and FEF rhythmic attention model (Aussel et al. 2023) |
| 155 |
Long time windows from theta modulated inhib. in entorhinal–hippo. loop (Cutsuridis & Poirazi 2015) |
| 156 |
Long-Term Inactivation of Na+ Channels as a Mech of Adaptation in CA1 Pyr Cells (Upchurch et al '22) |
| 157 |
M-current in a collision detection neuron (LGMD model) (Dewell & Gabbiani 2018) |
| 158 |
Mature and young adult-born dentate granule cell models (T2N interface) (Beining et al. 2017) |
| 159 |
MEG of Somatosensory Neocortex (Jones et al. 2007) |
| 160 |
Membrane electrical properties of mouse CA1 pyramidal cells during strong inputs (Bianchi et al 22) |
| 161 |
Microcircuits of L5 thick tufted pyramidal cells (Hay & Segev 2015) |
| 162 |
Mirror Neuron (Antunes et al 2017) |
| 163 |
Modelling reduced excitability in aged CA1 neurons as a Ca-dependent process (Markaki et al. 2005) |
| 164 |
Modulation of septo-hippocampal theta activity by GABAA receptors (Hajos et al. 2004) |
| 165 |
Multi-comp. CA1 O-LM interneuron model with varying dendritic Ih distributions (Sekulic et al 2015) |
| 166 |
Multicompartmental cerebellar granule cell model (Diwakar et al. 2009) |
| 167 |
Multitarget pharmacology for Dystonia in M1 (Neymotin et al 2016) |
| 168 |
MyFirstNEURON (Houweling, Sejnowski 1997) |
| 169 |
Na+ channel dependence of AP initiation in cortical pyramidal neuron (Kole et al. 2008) |
| 170 |
NN activity impact on neocortical pyr. neurons integrative properties in vivo (Destexhe & Pare 1999) |
| 171 |
O-LM interneuron model (Lawrence et al. 2006) |
| 172 |
Olfactory Bulb Network (Davison et al 2003) |
| 173 |
Optical stimulation of a channelrhodopsin-2 positive pyramidal neuron model (Foutz et al 2012) |
| 174 |
Orientation preference in L23 V1 pyramidal neurons (Park et al 2019) |
| 175 |
Paradoxical GABA-mediated excitation (Lewin et al. 2012) |
| 176 |
Parameter estimation for Hodgkin-Huxley based models of cortical neurons (Lepora et al. 2011) |
| 177 |
Persistent synchronized bursting activity in cortical tissues (Golomb et al 2005) |
| 178 |
Phase response curve of a globus pallidal neuron (Fujita et al. 2011) |
| 179 |
Phasic ACh promotes gamma oscillations in E-I networks (Lu et al, 2020) |
| 180 |
Phosphoinositide-Dependent Signaling in Sympathetic Neurons (SCG) (Kruse et al. 2016) |
| 181 |
Pleiotropic effects of SCZ-associated genes (Mäki-Marttunen et al. 2017) |
| 182 |
Pyramidal neuron coincidence detection tuned by dendritic branching pattern (Schaefer et al 2003) |
| 183 |
Pyramidal Neuron Deep: Constrained by experiment (Dyhrfjeld-Johnsen et al. 2005) |
| 184 |
Pyramidal Neuron: Deep, Thalamic Relay and Reticular, Interneuron (Destexhe et al 1998, 2001) |
| 185 |
Pyramidal neurons switch from integrators to resonators (Prescott et al. 2008) |
| 186 |
Rapid desynchronization of an electrically coupled Golgi cell network (Vervaeke et al. 2010) |
| 187 |
Reconstructing cerebellar granule layer evoked LFP using convolution (ReConv) (Diwakar et al. 2011) |
| 188 |
Reduced-morphology model of CA1 pyramidal cells optimized + validated w/ HippoUnit (Tomko et al '21) |
| 189 |
Regulation of KCNQ2/KCNQ3 current by G protein cycling (Suh et al 2004) |
| 190 |
Regulation of motoneuron excitability by KCNQ/Kv7 modulators (Lombardo & Harrington 2016) |
| 191 |
Rhesus Monkey Layer 3 Pyramidal Neurons: Young vs aged PFC (Coskren et al. 2015) |
| 192 |
Rhesus Monkey Young and Aged L3 PFC Pyramidal Neurons (Rumbell et al. 2016) |
| 193 |
Role of afferent-hair cell connectivity in determining spike train regularity (Holmes et al 2017) |
| 194 |
Schiz.-linked gene effects on intrinsic single-neuron excitability (Maki-Marttunen et al. 2016) |
| 195 |
SCZ-associated variant effects on L5 pyr cell NN activity and delta osc. (Maki-Marttunen et al 2018) |
| 196 |
Self-organized olfactory pattern recognition (Kaplan & Lansner 2014) |
| 197 |
Sensory-evoked responses of L5 pyramidal tract neurons (Egger et al 2020) |
| 198 |
Shaping NMDA spikes by timed synaptic inhibition on L5PC (Doron et al. 2017) |
| 199 |
Sleep-wake transitions in corticothalamic system (Bazhenov et al 2002) |
| 200 |
Spike burst-pause dynamics of Purkinje cells regulate sensorimotor adaptation (Luque et al 2019) |
| 201 |
STDP depends on dendritic synapse location (Letzkus et al. 2006) |
| 202 |
Striatal FSI and SPN oscillation model (Chartove et al. 2020) |
| 203 |
Structure-dynamics relationships in bursting neuronal networks revealed (Mäki-Marttunen et al. 2013) |
| 204 |
Subiculum network model with dynamic chloride/potassium homeostasis (Buchin et al 2016) |
| 205 |
Sympathetic neuron (Wheeler et al 2004) |
| 206 |
Systematic integration of data into multi-scale models of mouse primary V1 (Billeh et al 2020) |
| 207 |
Thalamocortical loop with delay for investigation of absence epilepsy (Liu et al 2019) |
| 208 |
The APP in C-terminal domain alters CA1 neuron firing (Pousinha et al 2019) |
| 209 |
The origin of different spike and wave-like events (Hall et al 2017) |
| 210 |
Theta phase precession in a model CA3 place cell (Baker and Olds 2007) |
| 211 |
Theta-gamma phase amplitude coupling in a hippocampal CA1 microcircuit (Ponzi et al. 2023) |
| 212 |
Tight junction model of CNS myelinated axons (Devaux and Gow 2008) |
| 213 |
Unbalanced peptidergic inhibition in superficial cortex underlies seizure activity (Hall et al 2015) |
| 214 |
Visual physiology of the layer 4 cortical circuit in silico (Arkhipov et al 2018) |
| 215 |
Zebrafish Mauthner-cell model (Watanabe et al 2017) |
