| | Models |
| 1. |
A 1000 cell network model for Lateral Amygdala (Kim et al. 2013)
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| 2. |
A focal seizure model with ion concentration changes (Gentiletti et al., accepted)
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| 3. |
A model for focal seizure onset, propagation, evolution, and progression (Liou et al 2020)
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| 4. |
A model of closed-loop motor unit including muscle spindle feedback (Kim, 2020)
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| 5. |
A model of slow motor unit (Kim, 2017)
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| 6. |
A modified Morris-Lecar model with gM and gAHP (Yang et al., accepted)
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| 7. |
A modified Morris-Lecar with TRPC4 & GIRK (Tian et al. 2022)
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| 8. |
A multi-compartment model for interneurons in the dLGN (Halnes et al. 2011)
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| 9. |
A unified thalamic model of multiple distinct oscillations (Li, Henriquez and Fröhlich 2017)
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| 10. |
Active dendritic integration in robust and precise grid cell firing (Schmidt-Hieber et al 2017)
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| 11. |
Activity patterns in a subthalamopallidal network of the basal ganglia model (Terman et al 2002)
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| 12. |
Alcohol action in a detailed Purkinje neuron model and an efficient simplified model (Forrest 2015)
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| 13. |
Amyloid-beta effects on release probability and integration at CA3-CA1 synapses (Romani et al. 2013)
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| 14. |
AP back-prop. explains threshold variability and rapid rise (McCormick et al. 2007, Yu et al. 2008)
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| 15. |
Ca+/HCN channel-dependent persistent activity in multiscale model of neocortex (Neymotin et al 2016)
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| 16. |
CA1 network model: interneuron contributions to epileptic deficits (Shuman et al 2020)
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| 17. |
CA1 pyramidal neuron: depolarization block (Bianchi et al. 2012)
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| 18. |
CA1 pyramidal neuron: synaptically-induced bAP predicts synapse location (Sterratt et al. 2012)
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| 19. |
CA1 pyramidal neurons: effects of Kv7 (M-) channels on synaptic integration (Shah et al. 2011)
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| 20. |
CA1 pyramidal: Stochastic amplification of KCa in Ca2+ microdomains (Stanley et al. 2011)
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| 21. |
Changes of ionic concentrations during seizure transitions (Gentiletti et al. 2016)
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| 22. |
Control of vibrissa motoneuron firing (Harish and Golomb 2010)
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| 23. |
Cortex-Basal Ganglia-Thalamus network model (Kumaravelu et al. 2016)
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| 24. |
Cortical Basal Ganglia Network Model during Closed-loop DBS (Fleming et al 2020)
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| 25. |
Deconstruction of cortical evoked potentials generated by subthalamic DBS (Kumaravelu et al 2018)
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| 26. |
Discharge hysteresis in motoneurons (Powers & Heckman 2015)
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| 27. |
Effects of increasing CREB on storage and recall processes in a CA1 network (Bianchi et al. 2014)
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| 28. |
Effects of the membrane AHP on the Lateral Superior Olive (LSO) (Zhou & Colburn 2010)
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| 29. |
Failure of Deep Brain Stimulation in a basal ganglia neuronal network model (Dovzhenok et al. 2013)
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| 30. |
Gamma genesis in the basolateral amygdala (Feng et al 2019)
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| 31. |
Impact of dendritic atrophy on intrinsic and synaptic excitability (Narayanan & Chattarji, 2010)
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| 32. |
Inhibition and glial-K+ interaction leads to diverse seizure transition modes (Ho & Truccolo 2016)
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| 33. |
Initiation of spreading depolarization by GABAergic neuron hyperactivity & NaV 1.1 (Chever et al 21)
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| 34. |
Intracortical synaptic potential modulation by presynaptic somatic potential (Shu et al. 2006, 2007)
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| 35. |
L5 PFC microcircuit used to study persistent activity (Papoutsi et al. 2014, 2013)
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| 36. |
L5 PFC pyramidal neurons (Papoutsi et al. 2017)
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| 37. |
Large-scale model of neocortical slice in vitro exhibiting persistent gamma (Tomsett et al. 2014)
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| 38. |
LCN-HippoModel: model of CA1 PCs deep-superficial theta firing dynamics (Navas-Olive et al 2020)
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| 39. |
Linear vs non-linear integration in CA1 oblique dendrites (Gómez González et al. 2011)
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| 40. |
Locational influence of dendritic PIC on input-output properties of spinal motoneurons (Kim 2017)
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| 41. |
Long time windows from theta modulated inhib. in entorhinal–hippo. loop (Cutsuridis & Poirazi 2015)
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| 42. |
Multi-comp. CA1 O-LM interneuron model with varying dendritic Ih distributions (Sekulic et al 2015)
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| 43. |
Multiscale interactions between chemical and electric signaling in LTP (Bhalla 2011)
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| 44. |
Network bursts in cultured NN result from different adaptive mechanisms (Masquelier & Deco 2013)
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| 45. |
Persistent Spiking in ACC Neurons (Ratte et al 2018)
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| 46. |
PyMUS: A Python based Motor Unit Simulator (Kim & Kim 2018)
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| 47. |
Pyramidal neuron conductances state and STDP (Delgado et al. 2010)
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| 48. |
Rapid desynchronization of an electrically coupled Golgi cell network (Vervaeke et al. 2010)
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| 49. |
Reliability of Morris-Lecar neurons with added T, h, and AHP currents (Zeldenrust et al. 2013)
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| 50. |
Rhesus Monkey Layer 3 Pyramidal Neurons: Young vs aged PFC (Coskren et al. 2015)
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| 51. |
Rhesus Monkey Young and Aged L3 PFC Pyramidal Neurons (Rumbell et al. 2016)
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| 52. |
Spinal motoneuron recruitment regulated by ionic channels during fictive locomotion (Zhang & Dai 20)
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| 53. |
State dependent drug binding to sodium channels in the dentate gyrus (Thomas & Petrou 2013)
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| 54. |
Sympathetic Preganglionic Neurone (Briant et al. 2014)
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| 55. |
Synaptic gating at axonal branches, and sharp-wave ripples with replay (Vladimirov et al. 2013)
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| 56. |
The APP in C-terminal domain alters CA1 neuron firing (Pousinha et al 2019)
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| 57. |
The electrodiffusive neuron-extracellular-glia (edNEG) model (Sætra et al. 2021)
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| 58. |
The electrodiffusive Pinsky-Rinzel (edPR) model (Sætra et al., 2020)
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| 59. |
The subcellular distribution of T-type Ca2+ channels in LGN interneurons (Allken et al. 2014)
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| 60. |
Two-neuron conductance-based model with dynamic ion concentrations to study NaV1.1 channel mutations
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