Cerebellum granule cell |
|
spike max decay slope |
Ionic mechanism of electroresponsiveness in cerebellar granule cells implicates the action of a persistent sodium current.
(NeuroElectro data)
(PubMed)
|
-88.8
± 29.9
(8)
|
88.8 (mV/ms)
|
Data Table |
Cerebellum granule cell |
|
spike max decay slope |
Ionic mechanism of electroresponsiveness in cerebellar granule cells implicates the action of a persistent sodium current.
(NeuroElectro data)
(PubMed)
|
-94.5
± 33.9
(10)
|
94.5 (mV/ms)
|
Data Table |
Cerebellum Purkinje cell |
|
spike max decay slope |
Aminopyridines correct early dysfunction and delay neurodegeneration in a mouse model of spinocerebellar ataxia type 1.
(NeuroElectro data)
(PubMed)
|
-277.09
(18)
|
277.09 (mV/ms)
|
Data Table |
Cerebellum Purkinje cell |
|
spike max decay slope |
Calcium dynamics and electrophysiological properties of cerebellar Purkinje cells in SCA1 transgenic mice.
(NeuroElectro data)
(PubMed)
|
-318.0
± 78.0
(28)
|
318.0 (mV/ms)
|
Data Table |
Cerebellum Purkinje cell |
|
spike max decay slope |
The leaner P/Q-type calcium channel mutation renders cerebellar Purkinje neurons hyper-excitable and eliminates Ca2+-Na+ spike bursts.
(NeuroElectro data)
(PubMed)
|
331.0
± 9.0
(17)
|
331.0 (mV/ms)
|
Data Table |
Cochlear nucleus (ventral) bushy cell |
anterior ventral cochlear nucleus dorsal third high frequency region neuron
|
spike max decay slope |
Synaptic transmission at the cochlear nucleus endbulb synapse during age-related hearing loss in mice.
(NeuroElectro data)
(PubMed)
|
75.7
(8)
|
75.7 (mV/ms)
|
Data Table |
Cochlear nucleus (ventral) bushy cell |
anterior ventral cochlear nucleus dorsal third high frequency region neuron
|
spike max decay slope |
Synaptic transmission at the cochlear nucleus endbulb synapse during age-related hearing loss in mice.
(NeuroElectro data)
(PubMed)
|
70.6
(10)
|
70.6 (mV/ms)
|
Data Table |
Cochlear nucleus (ventral) bushy cell |
anterior ventral cochlear nucleus dorsal third high frequency region neuron
|
spike max decay slope |
Synaptic transmission at the cochlear nucleus endbulb synapse during age-related hearing loss in mice.
(NeuroElectro data)
(PubMed)
|
60.7
(14)
|
60.7 (mV/ms)
|
Data Table |
Cochlear nucleus (ventral) bushy cell |
anterior ventral cochlear nucleus rostroventral third low frequency region neuron
|
spike max decay slope |
Synaptic transmission at the cochlear nucleus endbulb synapse during age-related hearing loss in mice.
(NeuroElectro data)
(PubMed)
|
59.7
(7)
|
59.7 (mV/ms)
|
Data Table |
Cochlear nucleus (ventral) bushy cell |
anterior ventral cochlear nucleus dorsal third high frequency region neuron
|
spike max decay slope |
Synaptic transmission at the cochlear nucleus endbulb synapse during age-related hearing loss in mice.
(NeuroElectro data)
(PubMed)
|
73.9
(21)
|
73.9 (mV/ms)
|
Data Table |
Dentate gyrus granule cell |
|
spike max decay slope |
Interneurons of the dentate-hilus border of the rat dentate gyrus: morphological and electrophysiological heterogeneity.
(NeuroElectro data)
(PubMed)
|
784.0
± 59.84
(16)
|
--
|
Data Table |
Dentate gyrus granule cell |
|
spike max decay slope |
Competition from newborn granule cells does not drive axonal retraction of silenced old granule cells in the adult hippocampus.
(NeuroElectro data)
(PubMed)
|
-93.0
± 5.0
(14)
|
93.0 (mV/ms)
|
Data Table |
Dentate gyrus granule cell |
|
spike max decay slope |
Granule-like neurons at the hilar/CA3 border after status epilepticus and their synchrony with area CA3 pyramidal cells: functional implications of seizure-induced neurogenesis.
(NeuroElectro data)
(PubMed)
|
92.0
(5)
|
--
|
Data Table |
Dentate gyrus granule cell |
|
spike max decay slope |
Preventing effect of L-type calcium channel blockade on electrophysiological alterations in dentate gyrus granule cells induced by entorhinal amyloid pathology.
(NeuroElectro data)
(PubMed)
|
-26.0
± 2.828
(16)
|
26.0 (mV/ms)
|
Data Table |
Dentate gyrus granule cell |
Granule cells located 50 - 100 um from granule cell layer/hilar border
|
spike max decay slope |
Granule-like neurons at the hilar/CA3 border after status epilepticus and their synchrony with area CA3 pyramidal cells: functional implications of seizure-induced neurogenesis.
(NeuroElectro data)
(PubMed)
|
92.0
|
--
|
Data Table |
Dentate gyrus hilar cell |
Dentate Gyrus nonadapting hilar interneuron
|
spike max decay slope |
Interneurons of the dentate-hilus border of the rat dentate gyrus: morphological and electrophysiological heterogeneity.
(NeuroElectro data)
(PubMed)
|
510.7
± 133.2
(6)
|
--
|
Data Table |
Dentate gyrus hilar cell |
Dentate Gyrus normally adapting hilar interneuron
|
spike max decay slope |
Interneurons of the dentate-hilus border of the rat dentate gyrus: morphological and electrophysiological heterogeneity.
(NeuroElectro data)
(PubMed)
|
397.2
± 42.8
(16)
|
--
|
Data Table |
Dentate gyrus hilar cell |
Dentate Gyrus strongly adapting hilar interneuron
|
spike max decay slope |
Interneurons of the dentate-hilus border of the rat dentate gyrus: morphological and electrophysiological heterogeneity.
(NeuroElectro data)
(PubMed)
|
452.0
± 103.8
(4)
|
--
|
Data Table |
Dentate gyrus mossy cell |
|
spike max decay slope |
Proper layering is important for precisely timed activation of hippocampal mossy cells.
(NeuroElectro data)
(PubMed)
|
118.0
± 4.0
(18)
|
118.0 (mV/ms)
|
Data Table |
Dentate gyrus mossy cell |
|
spike max decay slope |
Survival of dentate hilar mossy cells after pilocarpine-induced seizures and their synchronized burst discharges with area CA3 pyramidal cells.
(NeuroElectro data)
(PubMed)
|
63.4
|
--
|
Data Table |
Dentate gyrus mossy cell |
|
spike max decay slope |
Survival of dentate hilar mossy cells after pilocarpine-induced seizures and their synchronized burst discharges with area CA3 pyramidal cells.
(NeuroElectro data)
(PubMed)
|
74.1
|
--
|
Data Table |
Dorsal root ganglion cell |
|
spike max decay slope |
Similar electrophysiological changes in axotomized and neighboring intact dorsal root ganglion neurons.
(NeuroElectro data)
(PubMed)
|
-69.8
± 7.8
(13)
|
69.8 (mV/ms)
|
Data Table |
Dorsal root ganglion cell |
|
spike max decay slope |
Similar electrophysiological changes in axotomized and neighboring intact dorsal root ganglion neurons.
(NeuroElectro data)
(PubMed)
|
-100.0
± 11.0
(24)
|
100.0 (mV/ms)
|
Data Table |
Dorsal root ganglion cell |
|
spike max decay slope |
Distinctive neurophysiological properties of embryonic trigeminal and geniculate neurons in culture.
(NeuroElectro data)
(PubMed)
|
-40.0
± 8.0
(173)
|
40.0 (mV/ms)
|
Data Table |
Dorsal root ganglion cell |
lumbar 4 and lumbar 5 dorsal root ganglion large cell
|
spike max decay slope |
Hyperexcitability of axotomized and neighboring unaxotomized sensory neurons is reduced days after perineural clonidine at the site of injury.
(NeuroElectro data)
(PubMed)
|
154.2
± 14.06
(36)
|
154.2 (mV/ms)
|
Data Table |
Dorsal root ganglion cell |
|
spike max decay slope |
Similar electrophysiological changes in axotomized and neighboring intact dorsal root ganglion neurons.
(NeuroElectro data)
(PubMed)
|
-133.0
± 11.9
(18)
|
133.0 (mV/ms)
|
Data Table |
Dorsal root ganglion cell |
Large dorsal root ganglion cell
|
spike max decay slope |
Long-term IL-1β exposure causes subpopulation-dependent alterations in rat dorsal root ganglion neuron excitability.
(NeuroElectro data)
(PubMed)
|
-68.2
± 8.8
(12)
|
68.2 (mV/ms)
|
Data Table |
Dorsal root ganglion cell |
Medium dorsal root ganglion cell
|
spike max decay slope |
Long-term IL-1β exposure causes subpopulation-dependent alterations in rat dorsal root ganglion neuron excitability.
(NeuroElectro data)
(PubMed)
|
-52.1
± 2.5
(36)
|
52.1 (mV/ms)
|
Data Table |
Dorsal root ganglion cell |
Small isolectin B4 negative dorsal root ganglion cell
|
spike max decay slope |
Long-term IL-1β exposure causes subpopulation-dependent alterations in rat dorsal root ganglion neuron excitability.
(NeuroElectro data)
(PubMed)
|
-49.0
± 4.5
(23)
|
49.0 (mV/ms)
|
Data Table |
Dorsal root ganglion cell |
Small isolectin B4 positive dorsal root ganglion cell
|
spike max decay slope |
Long-term IL-1β exposure causes subpopulation-dependent alterations in rat dorsal root ganglion neuron excitability.
(NeuroElectro data)
(PubMed)
|
-57.9
± 3.3
(20)
|
57.9 (mV/ms)
|
Data Table |
Hippocampus CA1 basket cell |
Hippocampal MGE-derived, paravalbumin-expressing, fast-spiking, basket, bistratified, and axo-axonic cells
|
spike max decay slope |
A blueprint for the spatiotemporal origins of mouse hippocampal interneuron diversity.
(NeuroElectro data)
(PubMed)
|
-112.0
± 24.0
(15)
|
112.0 (mV/ms)
|
Data Table |
Hippocampus CA1 basket cell |
Hippocampal MGE and CGE derived, late-spiking, NPY expressing cells
|
spike max decay slope |
A blueprint for the spatiotemporal origins of mouse hippocampal interneuron diversity.
(NeuroElectro data)
(PubMed)
|
-55.0
± 13.0
(34)
|
55.0 (mV/ms)
|
Data Table |
Hippocampus CA1 basket cell |
Hippocampal MGE-derived, somatostatin expressing cells
|
spike max decay slope |
A blueprint for the spatiotemporal origins of mouse hippocampal interneuron diversity.
(NeuroElectro data)
(PubMed)
|
-96.0
± 17.0
(23)
|
96.0 (mV/ms)
|
Data Table |
Hippocampus CA1 basket cell |
hippocampal CCK, VGluT3 and VIP expressing basket cells
|
spike max decay slope |
A blueprint for the spatiotemporal origins of mouse hippocampal interneuron diversity.
(NeuroElectro data)
(PubMed)
|
-83.0
± 14.0
(18)
|
83.0 (mV/ms)
|
Data Table |
Hippocampus CA1 ivy neuron |
|
spike max decay slope |
Common origins of hippocampal Ivy and nitric oxide synthase expressing neurogliaform cells.
(NeuroElectro data)
(PubMed)
|
-71.0
± 4.0
(13)
|
71.0 (mV/ms)
|
Data Table |
Hippocampus CA1 neurogliaform cell |
Hippocampus CA1 non-nitric oxide synthase expressing neurogliaform cell
|
spike max decay slope |
Common origins of hippocampal Ivy and nitric oxide synthase expressing neurogliaform cells.
(NeuroElectro data)
(PubMed)
|
-80.0
± 7.0
(10)
|
80.0 (mV/ms)
|
Data Table |
Hippocampus CA1 neurogliaform cell |
Hippocampus CA1 nitric oxide synthase expressing neurogliaform cell
|
spike max decay slope |
Common origins of hippocampal Ivy and nitric oxide synthase expressing neurogliaform cells.
(NeuroElectro data)
(PubMed)
|
-72.0
± 4.0
(25)
|
72.0 (mV/ms)
|
Data Table |
Hippocampus CA1 oriens lacunosum moleculare neuron |
Hippocampus CA1 and CA2 non-fast spiking stramum oriens neuron
|
spike max decay slope |
Morphological and electrophysiological properties of pyramidal-like neurons in the stratum oriens of Cornu ammonis 1 and Cornu ammonis 2 area of Proechimys.
(NeuroElectro data)
(PubMed)
|
-47.7
± 8.1
(15)
|
47.7 (mV/ms)
|
Data Table |
Hippocampus CA1 pyramidal cell |
Hippocampus CA1 and subiculum bursting pyramidal neurons
|
spike max decay slope |
Hippocampal pyramidal neurons comprise two distinct cell types that are countermodulated by metabotropic receptors.
(NeuroElectro data)
(PubMed)
|
-113.0
± 5.0
(268)
|
--
|
Data Table |
Hippocampus CA1 pyramidal cell |
Ventral Hippocampus CA1 pyramidal cell
|
spike max decay slope |
Spatial Gene-Expression Gradients Underlie Prominent Heterogeneity of CA1 Pyramidal Neurons.
(NeuroElectro data)
(PubMed)
|
-116.0
± 1.0
(31)
|
116.0 (mV/ms)
|
Data Table |
Hippocampus CA1 pyramidal cell |
Hippocampus CA1 and subiculum regular spiking pyramidal neurons
|
spike max decay slope |
Hippocampal pyramidal neurons comprise two distinct cell types that are countermodulated by metabotropic receptors.
(NeuroElectro data)
(PubMed)
|
-106.0
± 4.0
(268)
|
--
|
Data Table |
Hippocampus CA1 pyramidal cell |
|
spike max decay slope |
Depression of synaptic transmission by vascular endothelial growth factor in adult rat hippocampus and evidence for increased efficacy after chronic seizures.
(NeuroElectro data)
(PubMed)
|
80.7
± 14.6
(8)
|
80.7 (mV/ms)
|
Data Table |
Hippocampus CA1 pyramidal cell |
|
spike max decay slope |
Normal electrical properties of hippocampal neurons modelling early Huntington disease pathogenesis.
(NeuroElectro data)
(PubMed)
|
-45.6
(15)
|
45.6 (mV/ms)
|
Data Table |
Hippocampus CA1 pyramidal cell |
|
spike max decay slope |
Resting and active properties of pyramidal neurons in subiculum and CA1 of rat hippocampus.
(NeuroElectro data)
(PubMed)
|
-94.8
± 4.7
|
--
|
Data Table |
Hippocampus CA1 pyramidal cell |
|
spike max decay slope |
Tetanus toxin induces long-term changes in excitation and inhibition in the rat hippocampal CA1 area.
(NeuroElectro data)
(PubMed)
|
108.0
± 4.0
(25)
|
108.0 (mV/ms)
|
Data Table |
Hippocampus CA1 pyramidal cell |
|
spike max decay slope |
Normal electrical properties of hippocampal neurons modelling early Huntington disease pathogenesis.
(NeuroElectro data)
(PubMed)
|
-43.6
(7)
|
43.6 (mV/ms)
|
Data Table |
Hippocampus CA1 pyramidal cell |
|
spike max decay slope |
Alpha5GABAA receptors regulate the intrinsic excitability of mouse hippocampal pyramidal neurons.
(NeuroElectro data)
(PubMed)
|
-69.3
± 6.7
(10)
|
69.3 (mV/ms)
|
Data Table |
Hippocampus CA1 pyramidal cell |
|
spike max decay slope |
Reduced Hyperpolarization-Activated Current Contributes to Enhanced Intrinsic Excitability in Cultured Hippocampal Neurons from PrP(-/-) Mice.
(NeuroElectro data)
(PubMed)
|
-67.0
± 6.2
(5)
|
--
|
Data Table |
Hippocampus CA1 pyramidal cell |
|
spike max decay slope |
Reduced seizure threshold and altered network oscillatory properties in a mouse model of Rett syndrome.
(NeuroElectro data)
(PubMed)
|
106.0
± 7.0
(14)
|
106.0 (mV/ms)
|
Data Table |
Hippocampus CA1 pyramidal cell |
Hippocampus CA1 non-fast spiking stratum oriens pyramidal-like cell
|
spike max decay slope |
Morphological and electrophysiological properties of pyramidal-like neurons in the stratum oriens of Cornu ammonis 1 and Cornu ammonis 2 area of Proechimys.
(NeuroElectro data)
(PubMed)
|
-47.1
± 6.9
(8)
|
47.1 (mV/ms)
|
Data Table |
Hippocampus CA1 pyramidal cell |
|
spike max decay slope |
Downregulation of Spermine Augments Dendritic Persistent Sodium Currents and Synaptic Integration after Status Epilepticus.
(NeuroElectro data)
(PubMed)
|
77.0
± 3.0
(9)
|
77.0 (mV/ms)
|
Data Table |
Hippocampus CA1 pyramidal cell |
Dorsal Hippocampus CA1 pyramidal cell
|
spike max decay slope |
Spatial Gene-Expression Gradients Underlie Prominent Heterogeneity of CA1 Pyramidal Neurons.
(NeuroElectro data)
(PubMed)
|
-112.0
± 1.0
(46)
|
112.0 (mV/ms)
|
Data Table |
Hippocampus CA1 pyramidal cell |
Hippocampus CA1 non-fast spiking pyramidal neuron
|
spike max decay slope |
Morphological and electrophysiological properties of pyramidal-like neurons in the stratum oriens of Cornu ammonis 1 and Cornu ammonis 2 area of Proechimys.
(NeuroElectro data)
(PubMed)
|
-41.7
± 5.6
(7)
|
41.7 (mV/ms)
|
Data Table |
Hippocampus CA2 pyramidal neuron |
Hippocampus CA2 non-fasting spiking pyramidal neuron
|
spike max decay slope |
Morphological and electrophysiological properties of pyramidal-like neurons in the stratum oriens of Cornu ammonis 1 and Cornu ammonis 2 area of Proechimys.
(NeuroElectro data)
(PubMed)
|
-37.9
± 9.3
(11)
|
37.9 (mV/ms)
|
Data Table |
Hippocampus CA2 pyramidal neuron |
Hippocampus CA2 non-fast spiking pyramidal-like neuron
|
spike max decay slope |
Morphological and electrophysiological properties of pyramidal-like neurons in the stratum oriens of Cornu ammonis 1 and Cornu ammonis 2 area of Proechimys.
(NeuroElectro data)
(PubMed)
|
-44.2
± 4.4
(7)
|
44.2 (mV/ms)
|
Data Table |
Hippocampus CA3 pyramidal cell |
|
spike max decay slope |
Local circuit abnormalities in chronically epileptic rats after intrahippocampal tetanus toxin injection in infancy.
(NeuroElectro data)
(PubMed)
|
-147.6
± 28.4
(10)
|
147.6 (mV/ms)
|
Data Table |
Locus coeruleus noradrenergic neuron |
|
spike max decay slope |
Corticotropin-releasing hormone directly activates noradrenergic neurons of the locus ceruleus recorded in vitro.
(NeuroElectro data)
(PubMed)
|
55.0
± 7.0
(4)
|
55.0 (mV/ms)
|
Data Table |
Medial vestibular nucleus neuron |
medial vestibular nucleus non-glycinergic neuron
|
spike max decay slope |
Transgenic mouse lines subdivide medial vestibular nucleus neurons into discrete, neurochemically distinct populations.
(NeuroElectro data)
(PubMed)
|
255.0
± 70.0
(14)
|
255.0 (mV/ms)
|
Data Table |
Medial vestibular nucleus neuron |
medial vestibular nucleus glycinergic neuron
|
spike max decay slope |
Transgenic mouse lines subdivide medial vestibular nucleus neurons into discrete, neurochemically distinct populations.
(NeuroElectro data)
(PubMed)
|
445.0
± 136.0
(9)
|
445.0 (mV/ms)
|
Data Table |
Medial vestibular nucleus neuron |
medial vestibular nucleus gabaergic neuron
|
spike max decay slope |
Transgenic mouse lines subdivide medial vestibular nucleus neurons into discrete, neurochemically distinct populations.
(NeuroElectro data)
(PubMed)
|
202.0
± 47.0
(37)
|
202.0 (mV/ms)
|
Data Table |
Medial vestibular nucleus neuron |
medial vestibular nucleus glutamatergic or glycinergic neuron
|
spike max decay slope |
Transgenic mouse lines subdivide medial vestibular nucleus neurons into discrete, neurochemically distinct populations.
(NeuroElectro data)
(PubMed)
|
444.0
± 117.0
(49)
|
444.0 (mV/ms)
|
Data Table |
Medial vestibular nucleus neuron |
medial vestibular nucleus glutamatergic or glycinergic neuron
|
spike max decay slope |
Transgenic mouse lines subdivide medial vestibular nucleus neurons into discrete, neurochemically distinct populations.
(NeuroElectro data)
(PubMed)
|
340.0
± 92.0
(26)
|
340.0 (mV/ms)
|
Data Table |
Medial vestibular nucleus neuron |
medial vestibular nucleus gabaergic neuron
|
spike max decay slope |
Transgenic mouse lines subdivide medial vestibular nucleus neurons into discrete, neurochemically distinct populations.
(NeuroElectro data)
(PubMed)
|
224.0
± 69.0
(59)
|
224.0 (mV/ms)
|
Data Table |
Medial vestibular nucleus neuron |
Medial vestibular nucleus non-GABAergic neurons expressing Thy1
|
spike max decay slope |
Firing properties of GABAergic versus non-GABAergic vestibular nucleus neurons conferred by a differential balance of potassium currents.
(NeuroElectro data)
(PubMed)
|
142.0
± 39.0
(39)
|
142.0 (mV/ms)
|
Data Table |
Medial vestibular nucleus neuron |
medial vestibular nucleus glycinergic neuron
|
spike max decay slope |
Transgenic mouse lines subdivide medial vestibular nucleus neurons into discrete, neurochemically distinct populations.
(NeuroElectro data)
(PubMed)
|
259.0
± 94.0
(14)
|
259.0 (mV/ms)
|
Data Table |
Medial vestibular nucleus neuron |
Medial vestibular nucleus GABAergic neurons
|
spike max decay slope |
Firing properties of GABAergic versus non-GABAergic vestibular nucleus neurons conferred by a differential balance of potassium currents.
(NeuroElectro data)
(PubMed)
|
107.0
± 33.0
(35)
|
107.0 (mV/ms)
|
Data Table |
Medial vestibular nucleus neuron |
medial vestibular nucleus glutamatergic neuron
|
spike max decay slope |
Transgenic mouse lines subdivide medial vestibular nucleus neurons into discrete, neurochemically distinct populations.
(NeuroElectro data)
(PubMed)
|
472.0
± 104.0
(9)
|
472.0 (mV/ms)
|
Data Table |
Neocortex basket cell |
Somatosensory cortex layer 5 multipolar fast-spiking parvalbumin positive interneuron
|
spike max decay slope |
Altered intrinsic properties of neuronal subtypes in malformed epileptogenic cortex.
(NeuroElectro data)
(PubMed)
|
117.0
± 7.0
(34)
|
117.0 (mV/ms)
|
Data Table |
Neocortex basket cell |
Neocortex layer 5-6 fast-spiking GABAergic interneuron
|
spike max decay slope |
Impaired fast-spiking, suppressed cortical inhibition, and increased susceptibility to seizures in mice lacking Kv3.2 K+ channel proteins.
(NeuroElectro data)
(PubMed)
|
-84.07
± 1.84
(20)
|
84.07 (mV/ms)
|
Data Table |
Neocortex basket cell |
Neocortex layer 1-4 fast-spiking GABAergic interneuron
|
spike max decay slope |
Impaired fast-spiking, suppressed cortical inhibition, and increased susceptibility to seizures in mice lacking Kv3.2 K+ channel proteins.
(NeuroElectro data)
(PubMed)
|
-79.37
± 5.75
(10)
|
79.37 (mV/ms)
|
Data Table |
Neocortex basket cell |
Somatosensory cortex layer 2-3 nonpyramidal multipolar fast-spiking inhibitory interneuron
|
spike max decay slope |
Integration of broadband conductance input in rat somatosensory cortical inhibitory interneurons: an inhibition-controlled switch between intrinsic and input-driven spiking in fast-spiking cells.
(NeuroElectro data)
(PubMed)
|
-136.0
± 35.0
(10)
|
0.136 (mV/ms)
|
Data Table |
Neocortex interneuron deep |
Presubiculum somatostatin-expressing interneuron
|
spike max decay slope |
Diversity and overlap of parvalbumin and somatostatin expressing interneurons in mouse presubiculum.
(NeuroElectro data)
(PubMed)
|
-353.0
(61)
|
353.0 (mV/ms)
|
Data Table |
Neocortex interneuron deep |
posterior piriform cortex GABAergic regular-spiking non-pyramidal inhibitory interneuron
|
spike max decay slope |
GABAergic inhibitory interneurons in the posterior piriform cortex of the GAD67-GFP mouse.
(NeuroElectro data)
(PubMed)
|
-22.7
± 1.21
(51)
|
22.7 (mV/ms)
|
Data Table |
Neocortex interneuron deep |
posterior piriform cortex GABAergic late-spiking inhibitory interneuron
|
spike max decay slope |
GABAergic inhibitory interneurons in the posterior piriform cortex of the GAD67-GFP mouse.
(NeuroElectro data)
(PubMed)
|
-22.5
± 1.6
(24)
|
22.5 (mV/ms)
|
Data Table |
Neocortex interneuron deep |
barrel cortex layer 6a GABAergic inhibitory interneuron
|
spike max decay slope |
Inter- and intralaminar subcircuits of excitatory and inhibitory neurons in layer 6a of the rat barrel cortex.
(NeuroElectro data)
(PubMed)
|
-94.5
± 27.2
(32)
|
94.5 (mV/ms)
|
Data Table |
Neocortex interneuron deep |
Presubiculum parvalbumin interneuron
|
spike max decay slope |
Diversity and overlap of parvalbumin and somatostatin expressing interneurons in mouse presubiculum.
(NeuroElectro data)
(PubMed)
|
-498.0
(46)
|
498.0 (mV/ms)
|
Data Table |
Neocortex interneuron deep |
posterior piriform cortex GABAergic irregular-spiking inhibitory interneuron
|
spike max decay slope |
GABAergic inhibitory interneurons in the posterior piriform cortex of the GAD67-GFP mouse.
(NeuroElectro data)
(PubMed)
|
-22.8
± 1.4
(19)
|
22.8 (mV/ms)
|
Data Table |
Neocortex interneuron deep |
Presubiculum somatostatin-expressing interneuron
|
spike max decay slope |
Diversity and overlap of parvalbumin and somatostatin expressing interneurons in mouse presubiculum.
(NeuroElectro data)
(PubMed)
|
-355.0
(35)
|
355.0 (mV/ms)
|
Data Table |
Neocortex Martinotti cell |
Barrel Cortex GAD67 expressing, somatostatin-containing Gabaergic interneurons
|
spike max decay slope |
Distinct subtypes of somatostatin-containing neocortical interneurons revealed in transgenic mice.
(NeuroElectro data)
(PubMed)
|
-132.0
(33)
|
132.0 (mV/ms)
|
Data Table |
Neocortex Martinotti cell |
somatosensory cortex layer 6 martinotti cell
|
spike max decay slope |
Anatomical, physiological and molecular properties of Martinotti cells in the somatosensory cortex of the juvenile rat.
(NeuroElectro data)
(PubMed)
|
-33.19
± 10.31
(7)
|
33.19 (mV/ms)
|
Data Table |
Neocortex Martinotti cell |
Barrel Cortex GAD67 expressing, somatostatin-containing Gabaergic interneurons
|
spike max decay slope |
Distinct subtypes of somatostatin-containing neocortical interneurons revealed in transgenic mice.
(NeuroElectro data)
(PubMed)
|
-166.0
(58)
|
166.0 (mV/ms)
|
Data Table |
Neocortex Martinotti cell |
somatosensory cortex layer 5 martinotti cell
|
spike max decay slope |
Anatomical, physiological and molecular properties of Martinotti cells in the somatosensory cortex of the juvenile rat.
(NeuroElectro data)
(PubMed)
|
-27.74
± 7.13
(25)
|
27.74 (mV/ms)
|
Data Table |
Neocortex Martinotti cell |
Barrel Cortex GAD67 expressing, somatostatin-containing Gabaergic interneurons
|
spike max decay slope |
Distinct subtypes of somatostatin-containing neocortical interneurons revealed in transgenic mice.
(NeuroElectro data)
(PubMed)
|
-101.0
(59)
|
101.0 (mV/ms)
|
Data Table |
Neocortex Martinotti cell |
Somatosensory cortex layer 5 low threshold-spiking interneuron
|
spike max decay slope |
Altered intrinsic properties of neuronal subtypes in malformed epileptogenic cortex.
(NeuroElectro data)
(PubMed)
|
85.0
± 4.0
(33)
|
85.0 (mV/ms)
|
Data Table |
Neocortex pyramidal cell layer 2-3 |
|
spike max decay slope |
Functional roles of Kv1 channels in neocortical pyramidal neurons.
(NeuroElectro data)
(PubMed)
|
34.0
± 14.0
|
34.0 (mV/ms)
|
Data Table |
Neocortex pyramidal cell layer 2-3 |
Dysplastic Cortex Regular Spiking Neuron
|
spike max decay slope |
Characterization of neuronal migration disorders in neocortical structures. II. Intracellular in vitro recordings.
(NeuroElectro data)
(PubMed)
|
79.8
± 2.5
(51)
|
79.8 (mV/ms)
|
Data Table |
Neocortex pyramidal cell layer 2-3 |
Somatosensory and motor cortex layer 2-3 regular spiking pyramidal neurons
|
spike max decay slope |
Effects of temperature on calcium transients and Ca2+-dependent afterhyperpolarizations in neocortical pyramidal neurons.
(NeuroElectro data)
(PubMed)
|
32.5
± 12.5
(20)
|
32.5 (mV/ms)
|
Data Table |
Neocortex pyramidal cell layer 2-3 |
Somatosensory and motor cortex layer 2-3 regular spiking pyramidal neurons
|
spike max decay slope |
Effects of temperature on calcium transients and Ca2+-dependent afterhyperpolarizations in neocortical pyramidal neurons.
(NeuroElectro data)
(PubMed)
|
44.0
± 11.0
(20)
|
44.0 (mV/ms)
|
Data Table |
Neocortex pyramidal cell layer 2-3 |
somatosensory cortex layer 2/3 pyramidal neurons
|
spike max decay slope |
Electrophysiological properties of genetically identified subtypes of layer 5 neocortical pyramidal neurons: Ca²⁺ dependence and differential modulation by norepinephrine.
(NeuroElectro data)
(PubMed)
|
89.0
± 4.0
(23)
|
89.0 (mV/ms)
|
Data Table |
Neocortex pyramidal cell layer 5-6 |
Neocortex layer 5 Kv3.1 non-expressing pyramidal cell
|
spike max decay slope |
Transgenic mice expressing a fluorescent in vivo label in a distinct subpopulation of neocortical layer 5 pyramidal cells.
(NeuroElectro data)
(PubMed)
|
-99.0
± 6.0
|
99.0 (mV/ms)
|
Data Table |
Neocortex pyramidal cell layer 5-6 |
Primary motor cortex layer 5b corticospinal thick-tufted large pyramidal neuron
|
spike max decay slope |
Intrinsic electrophysiology of mouse corticospinal neurons: a class-specific triad of spike-related properties.
(NeuroElectro data)
(PubMed)
|
-134.0
± 33.0
(23)
|
134.0 (mV/ms)
|
Data Table |
Neocortex pyramidal cell layer 5-6 |
Primary motor cortex layer 5b corticospinal thick-tufted large pyramidal neuron
|
spike max decay slope |
Intrinsic electrophysiology of mouse corticospinal neurons: a class-specific triad of spike-related properties.
(NeuroElectro data)
(PubMed)
|
-153.0
± 23.0
(9)
|
153.0 (mV/ms)
|
Data Table |
Neocortex pyramidal cell layer 5-6 |
|
spike max decay slope |
Protein-kinase C-dependent phosphorylation inhibits the effect of the antiepileptic drug topiramate on the persistent fraction of sodium currents.
(NeuroElectro data)
(PubMed)
|
115.8
± 12.0
(5)
|
115.8 (mV/ms)
|
Data Table |
Neocortex pyramidal cell layer 5-6 |
Somatosensory cortex layer 5 apical pyramidal cell
|
spike max decay slope |
Altered intrinsic properties of neuronal subtypes in malformed epileptogenic cortex.
(NeuroElectro data)
(PubMed)
|
42.0
± 2.0
(28)
|
42.0 (mV/ms)
|
Data Table |
Neocortex pyramidal cell layer 5-6 |
Somatosensory Cortex Layer V Barrel Mixed Burst/Spike Cortical Neuron
|
spike max decay slope |
Differential modulatory effects of norepinephrine on synaptically driven responses of layer V barrel field cortical neurons.
(NeuroElectro data)
(PubMed)
|
90.0
± 17.0
(62)
|
90.0 (mV/ms)
|
Data Table |
Neocortex pyramidal cell layer 5-6 |
neocortex layer 5 large pyramidal cell
|
spike max decay slope |
Maturation of "neocortex isole" in vivo in mice.
(NeuroElectro data)
(PubMed)
|
-39.6
± 3.7
(20)
|
39.6 (mV/ms)
|
Data Table |
Neocortex pyramidal cell layer 5-6 |
Somatosensory Cortex Layer V Barrel Intrinsic Burst Cortical Neuron
|
spike max decay slope |
Differential modulatory effects of norepinephrine on synaptically driven responses of layer V barrel field cortical neurons.
(NeuroElectro data)
(PubMed)
|
81.0
± 17.0
(9)
|
81.0 (mV/ms)
|
Data Table |
Neocortex pyramidal cell layer 5-6 |
Somatosensory cortex layer 5b Glt25d2-expressing thick-tufted pyramidal neurons
|
spike max decay slope |
Electrophysiological properties of genetically identified subtypes of layer 5 neocortical pyramidal neurons: Ca²⁺ dependence and differential modulation by norepinephrine.
(NeuroElectro data)
(PubMed)
|
125.0
± 7.0
(35)
|
125.0 (mV/ms)
|
Data Table |
Neocortex pyramidal cell layer 5-6 |
Primary motor cortex layer 5b corticospinal thick-tufted large pyramidal neuron
|
spike max decay slope |
Intrinsic electrophysiology of mouse corticospinal neurons: a class-specific triad of spike-related properties.
(NeuroElectro data)
(PubMed)
|
-175.0
± 10.0
(10)
|
175.0 (mV/ms)
|
Data Table |
Neocortex pyramidal cell layer 5-6 |
somatosensory cortex layer 5a corticostriatal Etv1-expressing slender-tufted pyramidal neurons
|
spike max decay slope |
Electrophysiological properties of genetically identified subtypes of layer 5 neocortical pyramidal neurons: Ca²⁺ dependence and differential modulation by norepinephrine.
(NeuroElectro data)
(PubMed)
|
105.0
± 3.0
(71)
|
105.0 (mV/ms)
|
Data Table |
Neocortex pyramidal cell layer 5-6 |
Secondary somatosensory cortex layer 5b corticospinal thick-tufted large pyramidal neuron
|
spike max decay slope |
Intrinsic electrophysiology of mouse corticospinal neurons: a class-specific triad of spike-related properties.
(NeuroElectro data)
(PubMed)
|
-147.0
± 15.0
(7)
|
147.0 (mV/ms)
|
Data Table |
Neocortex pyramidal cell layer 5-6 |
Layer 6a barrel cortex pyramidal corticothalamic neuron with large terminal arbors
|
spike max decay slope |
Inter- and intralaminar subcircuits of excitatory and inhibitory neurons in layer 6a of the rat barrel cortex.
(NeuroElectro data)
(PubMed)
|
-79.1
± 13.8
(34)
|
79.1 (mV/ms)
|
Data Table |
Neocortex pyramidal cell layer 5-6 |
Primary motor cortex layer 5b corticostriatal pyramidal neuron
|
spike max decay slope |
Intrinsic electrophysiology of mouse corticospinal neurons: a class-specific triad of spike-related properties.
(NeuroElectro data)
(PubMed)
|
-66.0
± 19.0
(10)
|
66.0 (mV/ms)
|
Data Table |
Neocortex pyramidal cell layer 5-6 |
Neocortex layer 5 Kv3.1 expressing pyramidal cell
|
spike max decay slope |
Transgenic mice expressing a fluorescent in vivo label in a distinct subpopulation of neocortical layer 5 pyramidal cells.
(NeuroElectro data)
(PubMed)
|
-95.0
± 7.0
|
95.0 (mV/ms)
|
Data Table |
Neocortex pyramidal cell layer 5-6 |
barrel cortex layer 6a corticocortical pyramidal neuron with infragranular arborization axons
|
spike max decay slope |
Inter- and intralaminar subcircuits of excitatory and inhibitory neurons in layer 6a of the rat barrel cortex.
(NeuroElectro data)
(PubMed)
|
-50.7
± 13.2
(38)
|
50.7 (mV/ms)
|
Data Table |
Neocortex uncharacterized cell |
prefrontal cortex neurogliaform Inhibitory Neuron
|
spike max decay slope |
Electrophysiological differences between neurogliaform cells from monkey and rat prefrontal cortex.
(NeuroElectro data)
(PubMed)
|
93.0
± 13.0
(19)
|
93.0 (mV/ms)
|
Data Table |
Neocortex uncharacterized cell |
prefrontal cortex neurogliaform Inhibitory Neuron
|
spike max decay slope |
Electrophysiological differences between neurogliaform cells from monkey and rat prefrontal cortex.
(NeuroElectro data)
(PubMed)
|
95.0
± 25.0
(30)
|
95.0 (mV/ms)
|
Data Table |
Neocortex uncharacterized cell |
Parietal cortex pyramidal cells
|
spike max decay slope |
Maturation of "neocortex isole" in vivo in mice.
(NeuroElectro data)
(PubMed)
|
0.55
± 0.33
(45)
|
0.55 (mV/ms)
|
Data Table |
Neocortex uncharacterized cell |
somatosensory cortex Layers II/III/V ADP-negative Pyramidal Cell
|
spike max decay slope |
Spike sequences and mean firing rate in rat neocortical neurons in vitro.
(NeuroElectro data)
(PubMed)
|
56.3
(47)
|
56.3 (mV/ms)
|
Data Table |
Neocortex uncharacterized cell |
somatosensory cortex Layers II/III/V ADP-positive Pyramidal Cell
|
spike max decay slope |
Spike sequences and mean firing rate in rat neocortical neurons in vitro.
(NeuroElectro data)
(PubMed)
|
87.5
(42)
|
87.5 (mV/ms)
|
Data Table |
Neostriatum gabaergic interneuron |
Neostriatum fast spiking gabaergic interneuron
|
spike max decay slope |
Up and down states in striatal medium spiny neurons simultaneously recorded with spontaneous activity in fast-spiking interneurons studied in cortex-striatum-substantia nigra organotypic cultures.
(NeuroElectro data)
(PubMed)
|
-55.0
± 7.0
(12)
|
55.0 (mV/ms)
|
Data Table |
Neostriatum gabaergic interneuron |
Neostriatum fast-spiking interneuron
|
spike max decay slope |
Heterogeneity of spike frequency adaptation among medium spiny neurones from the rat striatum.
(NeuroElectro data)
(PubMed)
|
48.7
± 2.3
(7)
|
48.7 (mV/ms)
|
Data Table |
Neostriatum medium spiny neuron |
|
spike max decay slope |
P2Y1 receptor modulation of Ca2+-activated K+ currents in medium-sized neurons from neonatal rat striatal slices.
(NeuroElectro data)
(PubMed)
|
-92.1
± 3.69
(7)
|
92.1 (mV/ms)
|
Data Table |
Neostriatum medium spiny neuron |
|
spike max decay slope |
Heterogeneity of spike frequency adaptation among medium spiny neurones from the rat striatum.
(NeuroElectro data)
(PubMed)
|
8.8
± 0.4
(139)
|
8.8 (mV/ms)
|
Data Table |
Neostriatum medium spiny neuron |
|
spike max decay slope |
Electrophysiological and morphological changes in striatal spiny neurons in R6/2 Huntington's disease transgenic mice.
(NeuroElectro data)
(PubMed)
|
-85.5
± 5.6
(8)
|
85.5 (mV/ms)
|
Data Table |
Neostriatum medium spiny neuron |
|
spike max decay slope |
Up and down states in striatal medium spiny neurons simultaneously recorded with spontaneous activity in fast-spiking interneurons studied in cortex-striatum-substantia nigra organotypic cultures.
(NeuroElectro data)
(PubMed)
|
-40.0
± 4.0
(14)
|
40.0 (mV/ms)
|
Data Table |
Neostriatum medium spiny neuron |
|
spike max decay slope |
Electrophysiological and morphological changes in striatal spiny neurons in R6/2 Huntington's disease transgenic mice.
(NeuroElectro data)
(PubMed)
|
-98.1
± 3.4
(13)
|
98.1 (mV/ms)
|
Data Table |
Nucleus of the solitary tract intrinsic cell |
|
spike max decay slope |
H₂O₂ induces delayed hyperexcitability in nucleus tractus solitarii neurons.
(NeuroElectro data)
(PubMed)
|
-93.16
± 6.05
(23)
|
93.16 (mV/ms)
|
Data Table |
Nucleus of the solitary tract principal cell |
rostral nucleus of the solitary tract neuron
|
spike max decay slope |
Pre- and postnatal differences in membrane, action potential, and ion channel properties of rostral nucleus of the solitary tract neurons.
(NeuroElectro data)
(PubMed)
|
45.0
± 2.0
(39)
|
45.0 (mV/ms)
|
Data Table |
Nucleus of the solitary tract principal cell |
rostral nucleus of the solitary tract neuron
|
spike max decay slope |
Pre- and postnatal differences in membrane, action potential, and ion channel properties of rostral nucleus of the solitary tract neurons.
(NeuroElectro data)
(PubMed)
|
22.0
± 2.0
(18)
|
22.0 (mV/ms)
|
Data Table |
Nucleus of the solitary tract principal cell |
rostral nucleus of the solitary tract neuron
|
spike max decay slope |
Pre- and postnatal differences in membrane, action potential, and ion channel properties of rostral nucleus of the solitary tract neurons.
(NeuroElectro data)
(PubMed)
|
16.0
± 4.0
(25)
|
16.0 (mV/ms)
|
Data Table |
Nucleus of the solitary tract principal cell |
|
spike max decay slope |
Exogenous brain-derived neurotrophic factor rescues synaptic dysfunction in Mecp2-null mice.
(NeuroElectro data)
(PubMed)
|
-61.96
± 5.98
(13)
|
61.96 (mV/ms)
|
Data Table |
Olfactory bulb (main) Blanes cell |
Olfactory bulb deep short-axon cells
|
spike max decay slope |
Rapid Feedforward Inhibition and Asynchronous Excitation Regulate Granule Cell Activity in the Mammalian Main Olfactory Bulb.
(NeuroElectro data)
(PubMed)
|
-102.5
± 29.5
(9)
|
102.5 (mV/ms)
|
Data Table |
Olfactory bulb (main) granule cell |
|
spike max decay slope |
Rapid Feedforward Inhibition and Asynchronous Excitation Regulate Granule Cell Activity in the Mammalian Main Olfactory Bulb.
(NeuroElectro data)
(PubMed)
|
-60.3
± 13.9
(31)
|
60.3 (mV/ms)
|
Data Table |
Olfactory bulb (main) mitral cell |
|
spike max decay slope |
Postnatal development attunes olfactory bulb mitral cells to high-frequency signaling.
(NeuroElectro data)
(PubMed)
|
-77.9
± 22.6
(48)
|
77.9 (mV/ms)
|
Data Table |
Olfactory cortex large multipolar cell |
posterior piriform cortex round smooth GABAergic fast-spiking inhibitory interneuron
|
spike max decay slope |
GABAergic inhibitory interneurons in the posterior piriform cortex of the GAD67-GFP mouse.
(NeuroElectro data)
(PubMed)
|
-40.8
± 5.67
(12)
|
40.8 (mV/ms)
|
Data Table |
Other |
Basolateral amygdala cholecystokinin induced fast spiking type 2 interneurons
|
spike max decay slope |
Cholecystokinin excites interneurons in rat basolateral amygdala.
(NeuroElectro data)
(PubMed)
|
-85.0
± 4.0
|
85.0 (mV/ms)
|
Data Table |
Other |
somatosensory cortex layer 1 bursting non-accommodating GABAergic cells
|
spike max decay slope |
Synaptic and cellular organization of layer 1 of the developing rat somatosensory cortex.
(NeuroElectro data)
(PubMed)
|
40.02
|
40.02 (mV/ms)
|
Data Table |
Other |
Lateral central amygdala late-spiking GABAergic neuron
|
spike max decay slope |
Wiring Specificity and Synaptic Diversity in the Mouse Lateral Central Amygdala.
(NeuroElectro data)
(PubMed)
|
43.6
± 1.4
(50)
|
43.6 (mV/ms)
|
Data Table |
Other |
Basolateral amygdala cholecystokinin induced projection neurons
|
spike max decay slope |
Cholecystokinin excites interneurons in rat basolateral amygdala.
(NeuroElectro data)
(PubMed)
|
-79.0
± 5.0
|
79.0 (mV/ms)
|
Data Table |
Other |
neocortex layer 1 classical irregular spiking GABAergic cells
|
spike max decay slope |
Synaptic and cellular organization of layer 1 of the developing rat somatosensory cortex.
(NeuroElectro data)
(PubMed)
|
50.64
(8)
|
50.64 (mV/ms)
|
Data Table |
Other |
Lateral central amygdala early-spiking GABAergic neuron
|
spike max decay slope |
Wiring Specificity and Synaptic Diversity in the Mouse Lateral Central Amygdala.
(NeuroElectro data)
(PubMed)
|
45.6
± 1.6
(40)
|
45.6 (mV/ms)
|
Data Table |
Other |
CA3 projecting hippocampus Granule Cell
|
spike max decay slope |
Two electrophysiologically distinct types of granule cells in epileptic human hippocampus.
(NeuroElectro data)
(PubMed)
|
-124.0
± 21.0
|
124.0 (mV/ms)
|
Data Table |
Other |
Basolateral amygdala cholecystokinin induced burst-spiking interneurons
|
spike max decay slope |
Cholecystokinin excites interneurons in rat basolateral amygdala.
(NeuroElectro data)
(PubMed)
|
-97.0
± 6.0
|
97.0 (mV/ms)
|
Data Table |
Other |
Basolateral amygdala cholecystokinin induced regular-firing interneurons
|
spike max decay slope |
Cholecystokinin excites interneurons in rat basolateral amygdala.
(NeuroElectro data)
(PubMed)
|
-86.0
± 3.0
|
86.0 (mV/ms)
|
Data Table |
Other |
Rostral ventromedial medulla fast-spiking on-response neurons
|
spike max decay slope |
Intrinsic membrane characteristics distinguish two subsets of nociceptive modulatory neurons in rat RVM.
(NeuroElectro data)
(PubMed)
|
270.0
± 13.0
(5)
|
270.0 (mV/ms)
|
Data Table |
Other |
Dentate gyrus GABAergic neurons
|
spike max decay slope |
Multiple roles for mammalian target of rapamycin signaling in both glutamatergic and GABAergic synaptic transmission.
(NeuroElectro data)
(PubMed)
|
-60.0
± 5.0
(23)
|
60.0 (mV/ms)
|
Data Table |
Other |
Rostral ventromedial medulla fast-spiking off-response neurons
|
spike max decay slope |
Intrinsic membrane characteristics distinguish two subsets of nociceptive modulatory neurons in rat RVM.
(NeuroElectro data)
(PubMed)
|
287.0
± 29.0
(5)
|
287.0 (mV/ms)
|
Data Table |
Other |
presubiculum regular spiking pyramidal cells in layers II/III
|
spike max decay slope |
Cellular neuroanatomy of rat presubiculum.
(NeuroElectro data)
(PubMed)
|
-122.0
(24)
|
122.0 (mV/ms)
|
Data Table |
Other |
Dentate gyrus glutamergic neurons
|
spike max decay slope |
Multiple roles for mammalian target of rapamycin signaling in both glutamatergic and GABAergic synaptic transmission.
(NeuroElectro data)
(PubMed)
|
-89.0
± 6.0
(21)
|
89.0 (mV/ms)
|
Data Table |
Other |
Layer IV Excitatory Barrel Neurons
|
spike max decay slope |
Increased excitability of cortical neurons induced by associative learning: an ex vivo study.
(NeuroElectro data)
(PubMed)
|
-94.8
± 3.4
(33)
|
94.8 (mV/ms)
|
Data Table |
Other |
rostral ventromedial medulla slow-spiking off -response neurons
|
spike max decay slope |
Intrinsic membrane characteristics distinguish two subsets of nociceptive modulatory neurons in rat RVM.
(NeuroElectro data)
(PubMed)
|
191.0
± 78.0
(1)
|
191.0 (mV/ms)
|
Data Table |
Other |
presubiculum intrinsically bursting cells in layers IV
|
spike max decay slope |
Cellular neuroanatomy of rat presubiculum.
(NeuroElectro data)
(PubMed)
|
-91.0
(6)
|
91.0 (mV/ms)
|
Data Table |
Other |
lamina terminalis- preoptic area-diagonal band of Broca GnRH expressing neurons
|
spike max decay slope |
GABA- and glutamate-activated channels in green fluorescent protein-tagged gonadotropin-releasing hormone neurons in transgenic mice.
(NeuroElectro data)
(PubMed)
|
53.1
± 13.9
(26)
|
53.1 (mV/ms)
|
Data Table |
Other |
Rostral ventromedial medulla slow-spiking on-response neurons
|
spike max decay slope |
Intrinsic membrane characteristics distinguish two subsets of nociceptive modulatory neurons in rat RVM.
(NeuroElectro data)
(PubMed)
|
206.0
± 12.0
(3)
|
206.0 (mV/ms)
|
Data Table |
Other |
presubiculum regular spiking pyramidal cells in layer V/VI
|
spike max decay slope |
Cellular neuroanatomy of rat presubiculum.
(NeuroElectro data)
(PubMed)
|
-97.0
(17)
|
97.0 (mV/ms)
|
Data Table |
Other |
Neostriatum long-lasting afterhyperpolarization interneuron
|
spike max decay slope |
Heterogeneity of spike frequency adaptation among medium spiny neurones from the rat striatum.
(NeuroElectro data)
(PubMed)
|
6.6
± 1.6
(11)
|
6.6 (mV/ms)
|
Data Table |
Other |
hypothalamic non-GnRH expressing neuron
|
spike max decay slope |
GABA- and glutamate-activated channels in green fluorescent protein-tagged gonadotropin-releasing hormone neurons in transgenic mice.
(NeuroElectro data)
(PubMed)
|
63.1
± 23.6
(26)
|
63.1 (mV/ms)
|
Data Table |
Other |
Rostral ventromedial medulla neutral slow-spiking inhibitory neurons
|
spike max decay slope |
Intrinsic membrane characteristics distinguish two subsets of nociceptive modulatory neurons in rat RVM.
(NeuroElectro data)
(PubMed)
|
180.0
± 18.0
(5)
|
180.0 (mV/ms)
|
Data Table |
Other |
resembled hippocampal Schaffer collateral associated cells and hippocampal associational commissural-associated cells
|
spike max decay slope |
A blueprint for the spatiotemporal origins of mouse hippocampal interneuron diversity.
(NeuroElectro data)
(PubMed)
|
-79.0
± 16.0
(33)
|
79.0 (mV/ms)
|
Data Table |
Other |
neocortex layer 1 classical stuttering GABAergic cells
|
spike max decay slope |
Synaptic and cellular organization of layer 1 of the developing rat somatosensory cortex.
(NeuroElectro data)
(PubMed)
|
42.75
(14)
|
42.75 (mV/ms)
|
Data Table |
Other |
presubiculum regular spiking pyramidal cells in layer V/VI
|
spike max decay slope |
Cellular neuroanatomy of rat presubiculum.
(NeuroElectro data)
(PubMed)
|
-80.0
(11)
|
80.0 (mV/ms)
|
Data Table |
Other |
hippocampal GABAergic projection cells or interneuron-targeting interneurons
|
spike max decay slope |
A blueprint for the spatiotemporal origins of mouse hippocampal interneuron diversity.
(NeuroElectro data)
(PubMed)
|
-50.0
± 12.0
(19)
|
--
|
Data Table |
Other |
somatosensory cortex layer 1 classical non-accomodating GABAergic cells
|
spike max decay slope |
Synaptic and cellular organization of layer 1 of the developing rat somatosensory cortex.
(NeuroElectro data)
(PubMed)
|
43.78
(40)
|
43.78 (mV/ms)
|
Data Table |
Other |
Basolateral amygdala cholecystokinin induced fast spiking type 1 interneurons
|
spike max decay slope |
Cholecystokinin excites interneurons in rat basolateral amygdala.
(NeuroElectro data)
(PubMed)
|
-103.0
± 2.0
|
103.0 (mV/ms)
|
Data Table |
Other |
somatosensory cortex layer 1 classical adapting GABAergic cells
|
spike max decay slope |
Synaptic and cellular organization of layer 1 of the developing rat somatosensory cortex.
(NeuroElectro data)
(PubMed)
|
45.45
(11)
|
45.45 (mV/ms)
|
Data Table |
Spinal cord ventral horn motor neuron alpha |
spinal cord lumbar motor neuron
|
spike max decay slope |
Early excitability changes in lumbar motoneurons of transgenic SOD1G85R and SOD1G(93A-Low) mice.
(NeuroElectro data)
(PubMed)
|
-82.1
± 4.6
(33)
|
82.1 (mV/ms)
|
Data Table |
Subiculum pyramidal cell |
subiculum bursting pyramidal neuron
|
spike max decay slope |
Target-specific output patterns are predicted by the distribution of regular-spiking and bursting pyramidal neurons in the subiculum.
(NeuroElectro data)
(PubMed)
|
-133.0
± 2.0
(188)
|
133.0 (mV/ms)
|
Data Table |
Subiculum pyramidal cell |
Subiculum weak bursting pyramidal cell
|
spike max decay slope |
Resting and active properties of pyramidal neurons in subiculum and CA1 of rat hippocampus.
(NeuroElectro data)
(PubMed)
|
-88.8
± 5.1
|
--
|
Data Table |
Subiculum pyramidal cell |
Presubicular pyramidal cells
|
spike max decay slope |
Diversity and overlap of parvalbumin and somatostatin expressing interneurons in mouse presubiculum.
(NeuroElectro data)
(PubMed)
|
-134.0
(17)
|
134.0 (mV/ms)
|
Data Table |
Subiculum pyramidal cell |
subiculum pyramidal neuron projecting to thalamic nucleus
|
spike max decay slope |
Target-specific output patterns are predicted by the distribution of regular-spiking and bursting pyramidal neurons in the subiculum.
(NeuroElectro data)
(PubMed)
|
-129.0
± 2.0
(68)
|
129.0 (mV/ms)
|
Data Table |
Subiculum pyramidal cell |
Subiculum strong bursting pyramidal cell
|
spike max decay slope |
Resting and active properties of pyramidal neurons in subiculum and CA1 of rat hippocampus.
(NeuroElectro data)
(PubMed)
|
-103.0
± 5.0
|
--
|
Data Table |
Subiculum pyramidal cell |
subiculum pyramidal neuron projecting to nucleus accumbens
|
spike max decay slope |
Target-specific output patterns are predicted by the distribution of regular-spiking and bursting pyramidal neurons in the subiculum.
(NeuroElectro data)
(PubMed)
|
-118.0
± 3.0
(64)
|
118.0 (mV/ms)
|
Data Table |
Subiculum pyramidal cell |
subiculum pyramidal neuron projecting to ventromedial hypothalamus
|
spike max decay slope |
Target-specific output patterns are predicted by the distribution of regular-spiking and bursting pyramidal neurons in the subiculum.
(NeuroElectro data)
(PubMed)
|
-141.0
± 3.0
(46)
|
141.0 (mV/ms)
|
Data Table |
Subiculum pyramidal cell |
subiculum pyramidal neuron projecting to presubiculum
|
spike max decay slope |
Target-specific output patterns are predicted by the distribution of regular-spiking and bursting pyramidal neurons in the subiculum.
(NeuroElectro data)
(PubMed)
|
-138.0
± 5.0
(23)
|
138.0 (mV/ms)
|
Data Table |
Subiculum pyramidal cell |
subiculum pyramidal neuron projecting to medial entorhinal cortex
|
spike max decay slope |
Target-specific output patterns are predicted by the distribution of regular-spiking and bursting pyramidal neurons in the subiculum.
(NeuroElectro data)
(PubMed)
|
-121.0
± 3.0
(28)
|
121.0 (mV/ms)
|
Data Table |
Subiculum pyramidal cell |
subiculum pyramidal neuron projecting to retrosplenial cortex
|
spike max decay slope |
Target-specific output patterns are predicted by the distribution of regular-spiking and bursting pyramidal neurons in the subiculum.
(NeuroElectro data)
(PubMed)
|
-169.0
± 4.0
(43)
|
169.0 (mV/ms)
|
Data Table |
Subiculum pyramidal cell |
subiculum pyramidal neuron projecting to orbitofrontal cortex
|
spike max decay slope |
Target-specific output patterns are predicted by the distribution of regular-spiking and bursting pyramidal neurons in the subiculum.
(NeuroElectro data)
(PubMed)
|
-109.0
± 4.0
(50)
|
109.0 (mV/ms)
|
Data Table |
Subiculum pyramidal cell |
subiculum pyramidal neuron projecting to lateral entorhinal cortex
|
spike max decay slope |
Target-specific output patterns are predicted by the distribution of regular-spiking and bursting pyramidal neurons in the subiculum.
(NeuroElectro data)
(PubMed)
|
-109.0
± 4.0
(51)
|
109.0 (mV/ms)
|
Data Table |
Subiculum pyramidal cell |
subiculum pyramidal neuron projecting to amygdala
|
spike max decay slope |
Target-specific output patterns are predicted by the distribution of regular-spiking and bursting pyramidal neurons in the subiculum.
(NeuroElectro data)
(PubMed)
|
-97.0
± 3.0
(33)
|
97.0 (mV/ms)
|
Data Table |
Subiculum pyramidal cell |
subiculum regular spiking pyramidal neuron
|
spike max decay slope |
Target-specific output patterns are predicted by the distribution of regular-spiking and bursting pyramidal neurons in the subiculum.
(NeuroElectro data)
(PubMed)
|
-118.0
± 2.0
(218)
|
118.0 (mV/ms)
|
Data Table |
Subiculum pyramidal cell |
Subiculum regular spiking pyramidal cell
|
spike max decay slope |
Resting and active properties of pyramidal neurons in subiculum and CA1 of rat hippocampus.
(NeuroElectro data)
(PubMed)
|
-110.0
± 5.0
|
--
|
Data Table |
Substantia nigra pars compacta dopaminergic cell |
|
spike max decay slope |
Non-linear developmental trajectory of electrical phenotype in rat substantia nigra pars compacta dopaminergic neurons.
(NeuroElectro data)
(PubMed)
|
-42.6
± 8.8
|
42.6 (mV/ms)
|
Data Table |
Substantia nigra pars compacta dopaminergic cell |
|
spike max decay slope |
Non-linear developmental trajectory of electrical phenotype in rat substantia nigra pars compacta dopaminergic neurons.
(NeuroElectro data)
(PubMed)
|
-19.6
± 5.2
|
19.6 (mV/ms)
|
Data Table |
Substantia nigra pars compacta dopaminergic cell |
|
spike max decay slope |
Non-linear developmental trajectory of electrical phenotype in rat substantia nigra pars compacta dopaminergic neurons.
(NeuroElectro data)
(PubMed)
|
-16.9
± 4.6
|
16.9 (mV/ms)
|
Data Table |
Substantia nigra pars compacta dopaminergic cell |
|
spike max decay slope |
Non-linear developmental trajectory of electrical phenotype in rat substantia nigra pars compacta dopaminergic neurons.
(NeuroElectro data)
(PubMed)
|
-39.7
± 11.5
|
39.7 (mV/ms)
|
Data Table |
Substantia nigra pars compacta dopaminergic cell |
|
spike max decay slope |
Non-linear developmental trajectory of electrical phenotype in rat substantia nigra pars compacta dopaminergic neurons.
(NeuroElectro data)
(PubMed)
|
-38.8
± 8.8
|
38.8 (mV/ms)
|
Data Table |
Substantia nigra pars compacta dopaminergic cell |
|
spike max decay slope |
Non-linear developmental trajectory of electrical phenotype in rat substantia nigra pars compacta dopaminergic neurons.
(NeuroElectro data)
(PubMed)
|
-20.2
± 5.9
|
20.2 (mV/ms)
|
Data Table |
Substantia nigra pars compacta dopaminergic cell |
|
spike max decay slope |
Non-linear developmental trajectory of electrical phenotype in rat substantia nigra pars compacta dopaminergic neurons.
(NeuroElectro data)
(PubMed)
|
-41.4
± 11.4
|
41.4 (mV/ms)
|
Data Table |
Substantia nigra pars compacta dopaminergic cell |
|
spike max decay slope |
Non-linear developmental trajectory of electrical phenotype in rat substantia nigra pars compacta dopaminergic neurons.
(NeuroElectro data)
(PubMed)
|
-43.2
± 8.7
|
43.2 (mV/ms)
|
Data Table |
Substantia nigra pars compacta dopaminergic cell |
|
spike max decay slope |
Non-linear developmental trajectory of electrical phenotype in rat substantia nigra pars compacta dopaminergic neurons.
(NeuroElectro data)
(PubMed)
|
-17.6
± 4.1
|
17.6 (mV/ms)
|
Data Table |
Substantia nigra pars compacta dopaminergic cell |
|
spike max decay slope |
Regulation of action potential size and excitability in substantia nigra compacta neurons: sensitivity to 4-aminopyridine.
(NeuroElectro data)
(PubMed)
|
44.0
± 2.0
(35)
|
44.0 (mV/ms)
|
Data Table |
Substantia nigra pars compacta dopaminergic cell |
|
spike max decay slope |
Non-linear developmental trajectory of electrical phenotype in rat substantia nigra pars compacta dopaminergic neurons.
(NeuroElectro data)
(PubMed)
|
-30.9
± 8.5
|
30.9 (mV/ms)
|
Data Table |
Substantia nigra pars compacta dopaminergic cell |
|
spike max decay slope |
Non-linear developmental trajectory of electrical phenotype in rat substantia nigra pars compacta dopaminergic neurons.
(NeuroElectro data)
(PubMed)
|
-44.1
± 11.4
|
44.1 (mV/ms)
|
Data Table |
Substantia nigra pars compacta dopaminergic cell |
|
spike max decay slope |
Non-linear developmental trajectory of electrical phenotype in rat substantia nigra pars compacta dopaminergic neurons.
(NeuroElectro data)
(PubMed)
|
-41.1
± 7.3
|
41.1 (mV/ms)
|
Data Table |
Substantia nigra pars compacta dopaminergic cell |
|
spike max decay slope |
Non-linear developmental trajectory of electrical phenotype in rat substantia nigra pars compacta dopaminergic neurons.
(NeuroElectro data)
(PubMed)
|
-18.0
± 6.6
|
18.0 (mV/ms)
|
Data Table |
Substantia nigra pars compacta dopaminergic cell |
|
spike max decay slope |
Non-linear developmental trajectory of electrical phenotype in rat substantia nigra pars compacta dopaminergic neurons.
(NeuroElectro data)
(PubMed)
|
-29.7
± 4.2
|
29.7 (mV/ms)
|
Data Table |
Substantia nigra pars compacta dopaminergic cell |
|
spike max decay slope |
Non-linear developmental trajectory of electrical phenotype in rat substantia nigra pars compacta dopaminergic neurons.
(NeuroElectro data)
(PubMed)
|
-21.4
± 7.5
|
21.4 (mV/ms)
|
Data Table |
Thalamic reticular nucleus cell |
Thalamic reticular nucleus fast-spiking GABAergic cell
|
spike max decay slope |
Resilient RTN fast spiking in Kv3.1 null mice suggests redundancy in the action potential repolarization mechanism.
(NeuroElectro data)
(PubMed)
|
-241.4
± 13.3
(16)
|
241.4 (mV/ms)
|
Data Table |
Thalamic reticular nucleus cell |
Thalamic reticular nucleus fast-spiking GABAergic cell
|
spike max decay slope |
Resilient RTN fast spiking in Kv3.1 null mice suggests redundancy in the action potential repolarization mechanism.
(NeuroElectro data)
(PubMed)
|
-543.5
± 49.6
(16)
|
543.5 (mV/ms)
|
Data Table |
Thalamus relay cell |
Lateral dorsal thalamic relay nucleus
|
spike max decay slope |
Differential regulation of action potential firing in adult murine thalamocortical neurons by Kv3.2, Kv1, and SK potassium and N-type calcium channels.
(NeuroElectro data)
(PubMed)
|
168.9
(82)
|
168.9 (mV/ms)
|
Data Table |