| | Models |
| 1. |
A detailed Purkinje cell model (Masoli et al 2015)
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| 2. |
A model of the T-junction of a C-fiber sensory neuron (Sundt et al. 2015)
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| 3. |
Action Potential initiation and backpropagation in Neocortical L5 Pyramidal Neuron (Hu et al. 2009)
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| 4. |
Activity-dependent broadening of axonal spikes by inactivating K channels (Zheng & Kamiya 2023)
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| 5. |
AIS model of L5 cortical pyramidal neuron (Filipis et al., 2023)
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| 6. |
AP back-prop. explains threshold variability and rapid rise (McCormick et al. 2007, Yu et al. 2008)
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| 7. |
AP initiation, propagation, and cortical invasion in a Layer 5 pyramidal cell (Anderson et 2018)
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| 8. |
Axon growth model (Diehl et al. 2016)
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| 9. |
Axonal HH-model for temperature stimulation (Fribance et al 2016)
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| 10. |
Axonal spheroids and conduction defects in Alzheimer’s disease (Yuan, Zhang, Tong, et al 2022)
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| 11. |
Axonal subthreshold voltage signaling along hippocampal mossy fiber (Kamiya 2022)
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| 12. |
Biologically Constrained Basal Ganglia model (BCBG model) (Lienard, Girard 2014)
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| 13. |
Biophysically realistic neuron models for simulation of cortical stimulation (Aberra et al. 2018)
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| 14. |
CA1 pyramidal cell: reconstructed axonal arbor and failures at weak gap junctions (Vladimirov 2011)
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| 15. |
CA1 pyramidal neuron: functional significance of axonal Kv7 channels (Shah et al. 2008)
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| 16. |
CA1 pyramidal neuron: Persistent Na current mediates steep synaptic amplification (Hsu et al 2018)
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| 17. |
Cerebellum granule cell FHF (Dover et al. 2016)
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| 18. |
Compartmental models of growing neurites (Graham and van Ooyen 2004)
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| 19. |
Comprehensive models of human cortical pyramidal neurons (Eyal et al 2018)
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| 20. |
Conduction in uniform myelinated axons (Moore et al 1978)
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| 21. |
Continuous time stochastic model for neurite branching (van Elburg 2011)
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| 22. |
Continuum model of tubulin-driven neurite elongation (Graham et al 2006)
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| 23. |
Contribution of the axon initial segment to APs recorded extracellularly (Telenczuk et al 2018)
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| 24. |
Cooling reverses pathological spontaneous firing caused by mild traumatic injury (Barlow et al 2018)
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| 25. |
Cortical Basal Ganglia Network Model during Closed-loop DBS (Fleming et al 2020)
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| 26. |
Current flow during PAP in squid axon at diameter change (Joyner et al 1980)
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| 27. |
Demyelinated and remyelinating axon conductances (Hines, Shrager 1991)
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| 28. |
Dentate granule cell: mAHP & sAHP; SK & Kv7/M channels (Mateos-Aparicio et al., 2014)
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| 29. |
Diameter, Myelination and Na/K pump interactions affect axonal resilience to high frequency spiking
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| 30. |
Dipolar extracellular potentials generated by axonal projections (McColgan et al 2017)
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| 31. |
Direct recruitment of S1 pyramidal cells and interneurons via ICMS (Overstreet et al., 2013)
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| 32. |
Dorsal Column Fiber Stimulation model (Gilbert et al. 2022)
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| 33. |
Double cable myelinated axon (Layer 5 pyramidal neuron; Cohen et al 2020)
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| 34. |
Earthworm medial giant fiber conduction velocity across electrical synapses (Heller, Crisp 2016)
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| 35. |
Effect of trp-like current on APs during exposure to sinusoidal voltage (Chen et al. 2010)
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| 36. |
ELL Medium Ganglion cell (Muller et al 2019)
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| 37. |
Ephaptic interactions in olfactory nerve (Bokil et al 2001)
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| 38. |
Evaluation of passive component of propagating AP in mossy fiber axons (Ohura & Kamiya 2018)
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| 39. |
Explaining pathological changes in axonal excitability by dynamical analysis (Coggan et al. 2011)
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| 40. |
Extracellular stimulation of myelinated axon (Reilly 2016)
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| 41. |
Globus pallidus neuron models with differing dendritic Na channel expression (Edgerton et al., 2010)
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| 42. |
GPi/GPe neuron models (Johnson and McIntyre 2008)
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| 43. |
Heterogeneous axon model (Zang et al, accepted)
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| 44. |
High frequency oscillations induced in three gap-junction coupled neurons (Tseng et al. 2008)
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| 45. |
Human somatosensory and motor axon pair to compare thresholds (Gaines et al 2018)
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| 46. |
Human tactile FA1 neurons (Hay and Pruszynski 2020)
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| 47. |
Hypocretin and Locus Coeruleus model neurons (Carter et al 2012)
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| 48. |
Intracortical synaptic potential modulation by presynaptic somatic potential (Shu et al. 2006, 2007)
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| 49. |
L5 pyramidal neuron myelination increases analog-digital facilitation extent (Zbili & Debanne 2020)
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| 50. |
Leech S Cell: Modulation of Excitability by Serotonin (Burrell and Crisp 2008)
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| 51. |
Lillie Transition: onset of saltatory conduction in myelinating axons (Young et al. 2013)
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| 52. |
LP neuron model database (Zang and Marder 2023)
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| 53. |
Mechanisms of very fast oscillations in axon networks coupled by gap junctions (Munro, Borgers 2010)
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| 54. |
Model of peripheral nerve with ephaptic coupling (Capllonch-Juan & Sepulveda 2020)
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| 55. |
Model of the Xenopus tadpole swimming spinal network (Roberts et al. 2014)
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| 56. |
Morphological determinants of action potential dynamics in substantia nigra (Moubarak et al 2022)
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| 57. |
Multiscale model of olfactory receptor neuron in mouse (Dougherty 2009)
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| 58. |
Myelinated axon conduction velocity (Brill et al 1977)
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| 59. |
Neocort. pyramidal cells subthreshold somatic voltage controls spike propagation (Munro Kopell 2012)
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| 60. |
Neural recruitment during synchronous multichannel microstimulation (Hokanson et al 2018)
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| 61. |
Neurite: electrophysiological-mechanical coupling simulation framework (Garcia-Grajales et al 2015)
|
| 62. |
NeuroGPU example on L5_TTPC1_cADpyr232_1 (Ben-Shalom 2022)(Ramaswamy et al., 2015)
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| 63. |
Nodes of Ranvier with left-shifted Nav channels (Boucher et al. 2012)
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| 64. |
Optical stimulation of a channelrhodopsin-2 positive pyramidal neuron model (Foutz et al 2012)
|
| 65. |
Parametric computation and persistent gamma in a cortical model (Chambers et al. 2012)
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| 66. |
Peripheral nerve:Morris-Lecar implementation of (Schwarz et al 1995)
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| 67. |
Prediction for the presence of voltage-gated Ca2+ channels in myelinated central axons (Brown 2003)
|
| 68. |
Preserving axosomatic spiking features despite diverse dendritic morphology (Hay et al., 2013)
|
| 69. |
Principles of Computational Modelling in Neuroscience (Book) (Sterratt et al. 2011)
|
| 70. |
PyPNS: Multiscale Simulation of a Peripheral Nerve in Python (Lubba et al 2018)
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| 71. |
Realistic amplifier model (Oláh et al. 2021)
|
| 72. |
Response properties of neocort. neurons to temporally modulated noisy inputs (Koendgen et al. 2008)
|
| 73. |
Role of afferent-hair cell connectivity in determining spike train regularity (Holmes et al 2017)
|
| 74. |
ROOTS: An Algorithm to Generate Biologically Realistic Cortical Axons (Bingham et al 2020)
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| 75. |
Selective control of cortical axonal spikes by a slowly inactivating K+ current (Shu et al. 2007)
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| 76. |
Sharpness of spike initiation in neurons explained by compartmentalization (Brette 2013)
|
| 77. |
Sound-evoked activity in peripheral axons of type I spiral ganglion neurons (Budak et al. 2021)
|
| 78. |
Spike propagation and bouton activation in terminal arborizations (Luscher, Shiner 1990)
|
| 79. |
Spike trains in Hodgkin–Huxley model and ISIs of acupuncture manipulations (Wang et al. 2008)
|
| 80. |
Spikelet generation and AP initiation in a L5 neocortical pyr neuron (Michalikova et al. 2017) Fig 1
|
| 81. |
Spikelet generation and AP initiation in a simplified pyr neuron (Michalikova et al. 2017) Fig 3
|
| 82. |
Spinal Motor Neuron (McIntyre et al 2002)
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| 83. |
Squid axon (Hodgkin, Huxley 1952) (LabAXON)
|
| 84. |
Squid axon (Hodgkin, Huxley 1952) (NEURON)
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| 85. |
Squid axon (Hodgkin, Huxley 1952) (SBML, XPP, other)
|
| 86. |
Squid axon (Hodgkin, Huxley 1952) (SNNAP)
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| 87. |
Squid axon (Hodgkin, Huxley 1952) used in (Chen et al 2010) (R language)
|
| 88. |
Squid axon: Bifurcation analysis of mode-locking (Lee & Kim 2006) (Gangal & Dar 2014)
|
| 89. |
State dependent drug binding to sodium channels in the dentate gyrus (Thomas & Petrou 2013)
|
| 90. |
Stimulated and physiologically induced APs: frequency and fiber diameter (Sadashivaiah et al 2018)
|
| 91. |
Stoney vs Histed: Quantifying spatial effects of intracortical microstims (Kumaravelu et al 2022)
|
| 92. |
Strategy for kinase transport by microtubules to nerve terminals (Koon et al. 2014)
|
| 93. |
Striatal D1R medium spiny neuron, including a subcellular DA cascade (Lindroos et al 2018)
|
| 94. |
Striatal NN model of MSNs and FSIs investigated effects of dopamine depletion (Damodaran et al 2015)
|
| 95. |
Submyelin Potassium accumulation in Subthalamic neuron (STN) axons (Bellinger et al. 2008)
|
| 96. |
Synaptic gating at axonal branches, and sharp-wave ripples with replay (Vladimirov et al. 2013)
|
| 97. |
Temperature sensitive axon models (DeMaegd & Stein 2020)
|
| 98. |
Temperature-Sensitive conduction at axon branch points (Westerfield et al 1978)
|
| 99. |
Thalamic network model of deep brain stimulation in essential tremor (Birdno et al. 2012)
|
| 100. |
The basis of sharp spike onset in standard biophysical models (Telenczuk et al 2017)
|
| 101. |
Two Models for synaptic input statistics for the MSO neuron model (Jercog et al. 2010)
|
| 102. |
Vertical system (VS) fly cells with biophysics (Dan et al 2018)
|
| 103. |
Vertical System (VS) tangential cells network model (Trousdale et al. 2014)
|
| 104. |
Xenopus Myelinated Neuron (Frankenhaeuser, Huxley 1964)
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