about
Assembly and operation of the autopatcher for automated intracellular neural recording in vivo.Neural circuits. Inhibition protects acquired song segments during vocal learning in zebra finchesAn optogenetics- and imaging-assisted simultaneous multiple patch-clamp recording system for decoding complex neural circuitsFluorescent Arc/Arg3.1 indicator mice: a versatile tool to study brain activity changes in vitro and in vivo.Three-dimensional mapping of microcircuit correlation structureLabel-free live brain imaging and targeted patching with third-harmonic generation microscopy.A disinhibitory circuit mediates motor integration in the somatosensory cortex.Population code in mouse V1 facilitates readout of natural scenes through increased sparseness.Quantum dot-based multiphoton fluorescent pipettes for targeted neuronal electrophysiology.EM connectomics reveals axonal target variation in a sequence-generating network.The Touch and Zap method for in vivo whole-cell patch recording of intrinsic and visual responses of cortical neurons and glial cellsHigh-resolution optical control of spatiotemporal neuronal activity patterns in zebrafish using a digital micromirror device.Target-specific effects of somatostatin-expressing interneurons on neocortical visual processingChronic cranial window with access port for repeated cellular manipulations, drug application, and electrophysiology.Phase-gradient contrast in thick tissue with a scanning microscopeFunctional dissection of synaptic circuits: in vivo patch-clamp recording in neuroscience.Post hoc immunostaining of GABAergic neuronal subtypes following in vivo two-photon calcium imaging in mouse neocortex.Integration of autopatching with automated pipette and cell detection in vitroSimultaneous all-optical manipulation and recording of neural circuit activity with cellular resolution in vivoParvalbumin-expressing interneurons linearly transform cortical responses to visual stimuli.Structural neurobiology: missing link to a mechanistic understanding of neural computation.Robotic Automation of In Vivo Two-Photon Targeted Whole-Cell Patch-Clamp Electrophysiology.Near-Infrared Fluorescent Proteins Engineered from Bacterial Phytochromes in Neuroimaging.Closed-Loop Real-Time Imaging Enables Fully Automated Cell-Targeted Patch-Clamp Neural Recording In Vivo.Stereotaxic gene delivery in the rodent brain.Postsynaptic excitability is necessary for strengthening of cortical sensory responses during experience-dependent development.Imaging population dynamics of surround suppression in the superior colliculus.Targeted single-cell electroporation of mammalian neurons in vivo.Mouse Ability to Perceive Subjective Contours.Two-photon targeted patching and electroporation in vivo.Neuronal activity is not required for the initial formation and maturation of visual selectivity.Food and water restriction lead to differential learning behaviors in a head-fixed two-choice visual discrimination task for mice
P2860
Q27310304-00528044-7484-4952-87E6-58384E76DD2CQ28603112-48786CB0-E070-4A1B-8603-1B9ED1DD8EE9Q30300853-2BC82BBB-DD1D-44DE-B4C5-C06CC6839600Q30438489-3748E46E-2A06-4096-B17B-36051083F4ACQ30448305-91343E03-50BF-48C2-9FA7-4E6B92DB9652Q30499588-9E45EBFA-D0B5-49F4-9B67-0A0AB7CEA055Q30583772-5B256980-B603-497E-8EA7-81DEACEE8614Q30584517-11E95126-283A-4068-8D03-4F40A7232203Q30602210-BC1A78B5-7E0C-4EDD-B4E3-E68C18F3A394Q33591173-90C2E5AC-8788-4233-8CB9-F83F78887086Q33685535-D2434ED4-04BB-491A-A676-8F0E0884F60FQ34320668-64EC18BD-205E-40EA-A595-901346397DD5Q34391868-B2BD815F-6EDC-405C-84FC-7676A59C243AQ34488172-8FEC29E0-56F9-4EDC-8D08-F2C49FF8121AQ35103770-5188740E-E57A-4426-AAA5-3227254B3CC5Q35634989-C9431D71-EEAC-4AB2-8DF6-B0DDA9642552Q35681124-07C62EE9-8B8D-4CF6-9199-7D8F7739AA95Q36069393-88CA6AC5-722A-4344-B73F-6B67A6BB9D9DQ37065814-87FC02DC-9A28-4F07-AE8F-269BE68F6D18Q37094389-9BBDF502-1444-4A3A-9F31-69C8297CDF02Q37986998-9A2AC4B0-7DB4-42BC-A2A6-E19B26C18116Q41615605-398F4E2C-A091-4B29-B0CC-6F83B57539F3Q47582818-4BB60647-B9C2-4306-BBAF-11E9D5C555EFQ47707227-1236EF65-7973-4A18-B9FF-2621EC96DC5AQ48218703-DCD57875-C885-409E-8B43-27D9AEA531B8Q48442040-6D9EC93E-A1FD-4609-BD7C-5E96772DC3AFQ48568310-5B6F0CA8-3853-4F84-8098-18139E96FC53Q48614885-FDFE8F7D-E805-43B2-A946-E34E958DF206Q50280409-49AC9C4C-116F-423A-AB41-F57285A03123Q50465552-6A20ED20-B168-49CF-85E5-186471C55E2FQ52147287-D0372C3F-30CE-44AA-A0A1-933D53A79E21Q58744049-E803D703-B2D4-4667-BAEE-BCD57EEB0869
P2860
description
2006 nî lūn-bûn
@nan
2006 թուականի Յունուարին հրատարակուած գիտական յօդուած
@hyw
2006 թվականի հունվարին հրատարակված գիտական հոդված
@hy
2006年の論文
@ja
2006年学术文章
@wuu
2006年学术文章
@zh-cn
2006年学术文章
@zh-hans
2006年学术文章
@zh-my
2006年学术文章
@zh-sg
2006年學術文章
@yue
name
Two-photon targeted patching (TPTP) in vivo.
@ast
Two-photon targeted patching (TPTP) in vivo.
@en
type
label
Two-photon targeted patching (TPTP) in vivo.
@ast
Two-photon targeted patching (TPTP) in vivo.
@en
prefLabel
Two-photon targeted patching (TPTP) in vivo.
@ast
Two-photon targeted patching (TPTP) in vivo.
@en
P2093
P2860
P356
P1433
P1476
Two-photon targeted patching (TPTP) in vivo.
@en
P2093
Michael Brecht
Pavel Osten
Troy W Margrie
Winfried Denk
P2860
P2888
P304
P356
10.1038/NPROT.2006.100
P50
P577
2006-01-01T00:00:00Z
P5875
P6179
1007358549