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Article: Ca2+-dependent and Na+-dependent K+ conductances contribute to a slow AHP in thalamic paraventricular nucleus neurons: a novel target for orexin receptors.

Full Text (publisher's website) ; Article Metadata ; Article Data (extracted)
Zhang L; Kolaj M; Renaud LP
J. Neurophysiol., 2010

Inferred neuron-electrophysiology data values

Neuron Type Neuron Description Ephys Prop Extracted Value Standardized Value Content Source
Other Intralaminar thalamic centrolateral nucleus neuron input resistance (MΩ) 386.0 ± 124.0 (29) 386.0 (MΩ) Data Table
Other Thalamus Higher-Order Lateral Posterior Nucleus neuron input resistance (MΩ) 242.0 ± 65.0 (8) 242.0 (MΩ) Data Table
Other Thalamus first-Order dorsal lateral geniculate nucleus neuron input resistance (MΩ) 262.0 ± 70.0 (4) 262.0 (MΩ) Data Table
Other Thalamus Higher-Order posterior thalamic nucleus neuron input resistance (MΩ) 212.0 ± 55.0 (11) 212.0 (MΩ) Data Table
Other Thalamus Higher-Order lateral posterior nucleus neuron input resistance (MΩ) 345.0 ± 112.0 (9) 345.0 (MΩ) Data Table
Other Thalamus first-Order dorsal lateral geniculate nucleus neuron input resistance (MΩ) 342.0 ± 96.0 (12) 342.0 (MΩ) Data Table
Other Thalamus Midline mediodorsal nucleus neuron input resistance (MΩ) 277.0 ± 105.0 (19) 277.0 (MΩ) Data Table
Other Thalamus Midline mediodorsal nucleus neuron resting membrane potential (mV) -69.5 ± 3.3 (19) -69.5 (mV) Data Table
Other Intralaminar thalamic centrolateral nucleus neuron resting membrane potential (mV) -69.5 ± 4.0 (29) -69.5 (mV) Data Table
Other Thalamus Higher-Order Lateral Posterior Nucleus neuron resting membrane potential (mV) -73.0 ± 5.0 (8) -73.0 (mV) Data Table
Other Thalamus first-Order dorsal lateral geniculate nucleus neuron resting membrane potential (mV) -68.2 ± 2.7 (4) -68.2 (mV) Data Table
Other Thalamus Higher-Order posterior thalamic nucleus neuron resting membrane potential (mV) -72.0 ± 2.0 (13) -72.0 (mV) Data Table
Other Thalamus Higher-Order lateral posterior nucleus neuron resting membrane potential (mV) -71.0 ± 3.0 (9) -71.0 (mV) Data Table
Other Thalamus first-Order dorsal lateral geniculate nucleus neuron resting membrane potential (mV) -68.3 ± 4.1 (12) -68.3 (mV) Data Table
Thalamic reticular nucleus cell input resistance (MΩ) 341.0 ± 214.0 (21) 341.0 (MΩ) Data Table
Thalamic reticular nucleus cell resting membrane potential (mV) -65.8 ± 8.4 (26) -65.8 (mV) Data Table
Thalamus parafascicular nucleus neuron input resistance (MΩ) 589.0 ± 207.0 (22) 589.0 (MΩ) Data Table
Thalamus parafascicular nucleus neuron resting membrane potential (mV) -66.7 ± 5.2 (22) -66.7 (mV) Data Table
Thalamic reticular nucleus cell input resistance 341.0 ± 214.0 341.0 (MΩ) User Submission ()
Thalamic reticular nucleus cell resting membrane potential -65.8 ± 8.4 -65.8 (mV) User Submission ()
Thalamus parafascicular nucleus neuron input resistance 589.0 ± 207.0 589.0 (MΩ) User Submission ()
Thalamus parafascicular nucleus neuron resting membrane potential -66.7 ± 5.2 -66.7 (mV) User Submission ()
Thalamus relay cell input resistance 342.0 ± 96.0 342.0 (MΩ) User Submission ()
Thalamus relay cell resting membrane potential -68.3 ± 4.1 -68.3 (mV) User Submission ()

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Metadata values

Experimental condition Value
RecTemp 23.0 - 25.0
AnimalAge 21.0 - 35.0
Strain Wistar
PrepType in vitro
ElectrodeType Patch-clamp
Species Rats
InternalSolution 5.0
ExternalSolution 5.0
JxnPotential Corrected
JxnOffset -15.0
internal_0_pH 7.3
internal_0_Mg 4.0
internal_0_Na 8.4
internal_0_K 140.0
internal_0_GTP 0.4
internal_0_ATP 2.0
internal_0_HEPES 10.0
internal_0_Cl 12.0
external_0_pH 7.3
external_0_Mg 1.3
external_0_Na 153.0
external_0_K 3.1
external_0_Cl 137.5
external_0_Ca 2.4
external_0_glucose 10.0

Data table listing

Data Table Article Title Authors Journal Year Table needs expert? Ephys table mentions Curated by Times validated
22117 Ca2+-dependent and Na+-dependent K+ conductances contribute to a slow AHP in thalamic paraventricular nucleus neurons: a novel target for orexin receptors. Zhang L; Kolaj M; Renaud LP J. Neurophysiol. 2010 False 2 James liu, Athanasios Kritharis, 1
22118 Ca2+-dependent and Na+-dependent K+ conductances contribute to a slow AHP in thalamic paraventricular nucleus neurons: a novel target for orexin receptors. Zhang L; Kolaj M; Renaud LP J. Neurophysiol. 2010 False 0 None