about
Temporal control of immediate early gene induction by lightHigh-efficiency channelrhodopsins for fast neuronal stimulation at low light levelsMultiple dynamic representations in the motor cortex during sensorimotor learning.Optimizing the spatial resolution of Channelrhodopsin-2 activation.NMDA receptor-dependent GABAB receptor internalization via CaMKII phosphorylation of serine 867 in GABAB1.Conversion of channelrhodopsin into a light-gated chloride channel.The rhodopsin-guanylyl cyclase of the aquatic fungus Blastocladiella emersonii enables fast optical control of cGMP signaling.An improved chloride-conducting channelrhodopsin for light-induced inhibition of neuronal activity in vivo.Active cortical dendrites modulate perception.Optical induction of synaptic plasticity using a light-sensitive channel.Spine neck plasticity controls postsynaptic calcium signals through electrical compartmentalization.Functional imaging of single synapses in brain slices.Calcium regulation of actin dynamics in dendritic spines.Single-Cell Electroporation of Neurons.Differential compartmentalization and distinct functions of GABAB receptor variants.Long-term depression triggers the selective elimination of weakly integrated synapses.Layer-specific optogenetic activation of pyramidal neurons causes beta-gamma entrainment of neonatal networks.Viral Vector-Based Transduction of Slice Cultures.Automated analysis of spine dynamics on live CA1 pyramidal cells.The life cycle of Ca(2+) ions in dendritic spines.The number of glutamate receptors opened by synaptic stimulation in single hippocampal spines.Influx of extracellular calcium regulates actin-dependent morphological plasticity in dendritic spines.Anion-conducting channelrhodopsins with tuned spectra and modified kinetics engineered for optogenetic manipulation of behavior.Neighborly synapses help each other out.Stimulating Neurons with Heterologously Expressed Light-Gated Ion Channels.Preparation of Slice Cultures from Rodent Hippocampus.Neurobiology: Pull out the stops for plasticity.Author Correction: Anion-conducting channelrhodopsins with tuned spectra and modified kinetics engineered for optogenetic manipulation of behavior.Ultrafast glutamate sensors resolve high-frequency release at Schaffer collateral synapses.The fate of hippocampal synapses depends on the sequence of plasticity-inducing eventsImproved methods for marking active neuron populationsThe kinetic mechanisms of fast-decay red-fluorescent genetically encoded calcium indicatorsThe Lego-logic of optogeneticsActive dendrites under parental supervisionNeurobeachin and the Kinesin KIF21B Are Critical for Endocytic Recycling of NMDA Receptors and Regulate Social BehaviorHow (not) to silence long-range projections with lightMyosin V regulates synaptopodin clustering and localization in the dendrites of hippocampal neuronsHigh-speed imaging of glutamate release with genetically encoded sensorsFreeze-frame imaging of synaptic activity using SynTagMA
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Q21562339-94105ADA-7D59-49B8-83D5-73E68783C0D9Q24598917-40387A1B-6D1C-4BF9-89F6-584147FDEDA7Q30667690-5B30F4FD-2A44-43AB-A6C3-AF662A637353Q33355036-2F6EAEC0-F3DA-4F3A-BD64-89F03BBC6265Q34068578-1AB04644-F6EB-4368-8E75-F6BB2C73A5B7Q34412448-C3DC532B-BD5C-4B44-A856-81C5EC64CEABQ34489293-E0CCC074-61C9-4F64-9A27-C496B92BE3A5Q34497141-2092C7C6-024C-4BF0-B0BB-9E20AD76B9A6Q34547863-90A004E2-A7C9-475E-A480-5DCDBBE61F3AQ34596094-7594C020-AD92-4213-90E4-84AE3EE10FFCQ34901087-605A0BA6-6CDD-4756-A477-973F3CD47DB5Q35007101-1B412618-06B3-480E-9A5C-6C8C155F0E99Q36093658-138B12C8-3CBC-46C4-AE3C-53895F1EC710Q36266864-341C82E8-7994-45BD-818C-3BB1AA0BC2AEQ36492579-9438B278-EAE0-499F-B427-7023E90C82B9Q37340829-31F93EE5-8655-47A5-A5F5-DDBDBAE1E586Q37660582-6AEAB14A-D68D-4305-A5FF-A5723A7BD6C3Q40355225-F6F3B467-AE57-451D-93AD-1C299CC567EEQ43579260-09D39527-F52C-4658-BC55-C042F7CE5B75Q43879113-44374805-FCB5-4EA5-89AA-F4C5172543DFQ44777547-5E422516-3611-482E-9C45-8C5DC68CD7CBQ45086238-59D1D489-B637-4D16-9988-48E3690D1492Q46613474-427ED4BF-BEC0-4180-93ED-EB4245F8426DQ48222135-54E0963E-8CD5-4F06-A91C-F1E4CFF2C913Q48286699-D3D2968A-FEE6-4548-B407-51353F8FB795Q48286727-9D6605C1-5F5C-492B-9277-D6C3CC549761Q52144835-70D56E25-20C3-4BFA-B04C-6CB626057A8CQ52807555-5253FE93-5DF5-4065-93F4-613344E97D61Q55396849-FB9A9DC3-B682-438F-AF38-17E73D34E5CCQ57470848-845652CD-D912-4AA8-8347-261DB32BAA8FQ58561087-DE61B03B-1FB7-4BD4-B8C6-7F519D5AFF32Q64268639-48F7BBB7-11D6-4447-9B9C-00AAE87973A1Q82731463-ABCA5D4A-154E-45C3-93B0-E7DFE5CA230CQ87492160-FAC28B5B-5503-40EA-8B13-31A8DE1A6E78Q88920925-568E24C0-AE6F-447A-AC70-9EB830F37B02Q89076551-F9046014-8D54-4631-A220-23B7FDB4B672Q92351638-B0FEE30F-F8C1-4D6A-9DD4-BFF0C2EB814FQ93112689-92A74366-D2C2-42E0-818E-3711C9CE5A65Q95326249-38A31C6B-01F8-4F02-A87F-240BD7AF7F7C
P50
description
hulumtues
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researcher
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wetenschapper
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հետազոտող
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name
Thomas G. Oertner
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Thomas G. Oertner
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Thomas G. Oertner
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Thomas G. Oertner
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Thomas G. Oertner
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type
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Thomas G. Oertner
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Thomas G. Oertner
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Thomas G. Oertner
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Thomas G. Oertner
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Thomas G. Oertner
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Oertner TG
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Thomas G. Oertner
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Thomas Oertner
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Thomas G. Oertner
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Thomas G. Oertner
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Thomas G. Oertner
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Thomas G. Oertner
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Thomas G. Oertner
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P214
P1053
F-2214-2010
P106
P1153
6602417431
P21
P214
P31
P3829
P496
0000-0002-2312-7528
P735
P7859
viaf-10712876