| 1 |
A biophysical model of vestibular ganglion neurons (Hight & Kalluri 2016, Ventura & Kalluri 2018) |
| 2 |
A model for a nociceptor terminal and terminal tree (Barkai et al., 2020) |
| 3 |
A model for interaural time difference sensitivity in the medial superior olive (Zhou et al 2005) |
| 4 |
A model of local field potentials generated by medial superior olive neurons (Goldwyn et al 2014) |
| 5 |
A model of ventral Hippocampal CA1 pyramidal neurons of Tg2576 AD mice (Spoleti et al. 2021) |
| 6 |
A multilayer cortical model to study seizure propagation across microdomains (Basu et al. 2015) |
| 7 |
A set of reduced models of layer 5 pyramidal neurons (Bahl et al. 2012) |
| 8 |
A single column thalamocortical network model (Traub et al 2005) |
| 9 |
A two-layer biophysical olfactory bulb model of cholinergic neuromodulation (Li and Cleland 2013) |
| 10 |
A unified thalamic model of multiple distinct oscillations (Li, Henriquez and Fröhlich 2017) |
| 11 |
Action potential of mouse urinary bladder smooth muscle (Mahapatra et al 2018) |
| 12 |
Active dendrites and spike propagation in a hippocampal interneuron (Saraga et al 2003) |
| 13 |
Active dendrites shape signaling microdomains in hippocampal neurons (Basak & Narayanan 2018) |
| 14 |
Active dendritic integration in robust and precise grid cell firing (Schmidt-Hieber et al 2017) |
| 15 |
Activity constraints on stable neuronal or network parameters (Olypher and Calabrese 2007) |
| 16 |
Activity dependent changes in motoneurones (Dai Y et al 2002, Gardiner et al 2002) |
| 17 |
Activity dependent regulation of pacemaker channels by cAMP (Wang et al 2002) |
| 18 |
Afferent Integration in the NAcb MSP Cell (Wolf et al. 2005) |
| 19 |
Age-dependent excitability of CA1 pyramidal neurons in APPPS1 Alzheimer's model (Vitale et al 2021) |
| 20 |
Alcohol action in a detailed Purkinje neuron model and an efficient simplified model (Forrest 2015) |
| 21 |
Allen Institute: Gad2-IRES-Cre VISp layer 5 472447460 |
| 22 |
Allen Institute: Gad2-IRES-Cre VISp layer 5 473561729 |
| 23 |
Allen Institute: Htr3a-Cre VISp layer 2/3 472352327 |
| 24 |
Allen Institute: Htr3a-Cre VISp layer 2/3 472421285 |
| 25 |
Allen Institute: Nr5a1-Cre VISp layer 2/3 473862496 |
| 26 |
Allen Institute: Nr5a1-Cre VISp layer 4 329322394 |
| 27 |
Allen Institute: Nr5a1-Cre VISp layer 4 472306544 |
| 28 |
Allen Institute: Nr5a1-Cre VISp layer 4 472442377 |
| 29 |
Allen Institute: Nr5a1-Cre VISp layer 4 472451419 |
| 30 |
Allen Institute: Nr5a1-Cre VISp layer 4 472915634 |
| 31 |
Allen Institute: Nr5a1-Cre VISp layer 4 473834758 |
| 32 |
Allen Institute: Nr5a1-Cre VISp layer 4 473863035 |
| 33 |
Allen Institute: Nr5a1-Cre VISp layer 4 473871429 |
| 34 |
Allen Institute: Ntsr1-Cre VISp layer 4 472430904 |
| 35 |
Allen Institute: Pvalb-IRES-Cre VISp layer 2/3 472306616 |
| 36 |
Allen Institute: Pvalb-IRES-Cre VISp layer 5 471085845 |
| 37 |
Allen Institute: Pvalb-IRES-Cre VISp layer 5 472349114 |
| 38 |
Allen Institute: Pvalb-IRES-Cre VISp layer 5 472912177 |
| 39 |
Allen Institute: Pvalb-IRES-Cre VISp layer 5 473465774 |
| 40 |
Allen Institute: Pvalb-IRES-Cre VISp layer 5 473862421 |
