about
Coordinated scaling of cortical and cerebellar numbers of neuronsThe human brain in numbers: a linearly scaled-up primate brainQuantitative relationships in delphinid neocortexBrain evolution by brain pathway duplication.The remarkable, yet not extraordinary, human brain as a scaled-up primate brain and its associated costFrom the primordial soup to self-driving cars: standards and their role in natural and technological innovationThe role of inflammasome in Alzheimer's diseaseIntegration of multiscale dendritic spine structure and function data into systems biology modelsCell based therapies for ischemic stroke: from basic science to bedsideBrain evolution and development: adaptation, allometry and constraintCellular scaling rules for primate brainsDecreasing sleep requirement with increasing numbers of neurons as a driver for bigger brains and bodies in mammalian evolutionCellular scaling rules for the brain of Artiodactyla include a highly folded cortex with few neuronsCellular scaling rules for the brain of afrotheriansValidation of the isotropic fractionator: comparison with unbiased stereology and DNA extraction for quantification of glial cellsThyroid hormone is required for the pruning of afferent type II spiral ganglion neurons in the mouse cochlea.Early exposure to bisphenol A alters neuron and glia number in the rat prefrontal cortex of adult males, but not females.Finding a roadmap to achieve large neuromorphic hardware systemsNeural progenitors organize in small-world networks to promote cell proliferationHabenula and the asymmetric development of the vertebrate brain.Modeled changes of cerebellar activity in mutant mice are predictive of their learning impairments.A proteomic survey of rat cerebral cortical synaptosomes.Aneuploidy and confined chromosomal mosaicism in the developing human brain.A unifying model for timing of walking onset in humans and other mammalsThe evolution of lossy compression.Teaching as Brain Changing: Exploring Connections between Neuroscience and Innovative TeachingUnderstanding neuronal connectivity through the post-transcriptional toolkit.Synaptosome proteomics.An estimation of the number of cells in the human body.Normal variation in fronto-occipital circuitry and cerebellar structure with an autism-associated polymorphism of CNTNAP2Network structure within the cerebellar input layer enables lossless sparse encoding.Neural development and the ontogeny of central nervous system tumors.A theory of sulcal-gap signalization.Neuroanatomical and neuropsychological correlates of the cerebellum in children with attention-deficit/hyperactivity disorder--combined typeCellular scaling rules for rodent brains.Genetic modulation of horizontal cell number in the mouse retina.Transgenic mice neuronally expressing baculoviral p35 are resistant to diverse types of induced apoptosis, including seizure-associated neurodegenerationStereological analysis of the rat and monkey amygdala.Functional role of RNA polymerase II and P70 S6 kinase in KCl withdrawal-induced cerebellar granule neuron apoptosis.Vision from next generation sequencing: multi-dimensional genome-wide analysis for producing gene regulatory networks underlying retinal development, aging and disease
P2860
Q21090475-6C5137B9-9DAB-47DC-87AE-D38FB21D5728Q21129074-1A20B855-8096-48B5-AB90-EC4648BD8359Q21131058-448861C2-3D93-48F7-8EF9-43289E876EECQ21710761-F5D33895-A868-4C6A-B868-B87ECC0C17B5Q24595440-0843D552-9A64-41D1-9E54-1A6F42004304Q26766703-8AA5C46A-9EDC-4DAE-AE5B-78B06FE40130Q26996822-97AB4782-8924-4A92-AFA5-B9F73580FD05Q27003132-F071A1D9-8F8C-4002-9143-B6E0FEC9F803Q27025754-7360A964-0BB2-4205-A4D8-8FCD9C383F83Q28078603-03CD9231-D8C4-4C08-9814-B3A82EE8E7E5Q28292947-F2099B5B-EB23-4C99-A96B-D30C4B2D02A3Q28608618-4A3E7EE2-4E23-4E08-9006-DC3720477FF6Q28652338-8FA74156-4F5F-4264-A4F1-0A31F7B0512AQ28659028-6BBB07A1-C34B-4391-96DB-B320FA05E662Q28659912-4B385CA8-8D14-46AA-AFB8-8AC2741B0507Q30365722-46267482-CF24-4F5D-BDC0-BF817449ED36Q30400639-BEDE2668-4EAD-4C17-96F6-FF9957A83116Q30449098-E0CB40EA-A181-4BD1-8FC6-1018904566A4Q30539060-795C7CC3-2B82-4B8A-A004-0DFFA3D0A7A2Q30574257-CE98BB5F-441E-4955-B8E6-2F0DA977DFACQ30827480-CDFB4504-BF0B-43DC-A43F-F9B41EE80E6AQ31163203-452573A5-721D-4A2A-A33B-3CF84EE671B5Q33288955-3352E684-787D-4A4C-8167-5C625B3D5F9FQ33519453-9840E4BE-666B-4BDF-9B9E-C1B727D288C0Q33753697-2489BA44-A05E-4848-B025-7EC66404CF55Q33764026-86212525-55B0-433A-88B2-2EDD63FA2412Q33767850-CE0CFE63-A546-4BD2-BFCD-8E76E346A9C9Q33786664-AC6C26C8-1352-4369-ADE1-D0E91C457308Q34037445-09F5935B-8FF0-4263-AE64-A2D24BA1F767Q34100081-3825E1AA-EE0C-4117-8E3B-9A0EC4A12F4AQ34104462-B53CCB5D-76BB-42CD-8404-E383D66C6EC9Q34422232-DEFF90BB-2F76-473F-82A8-4E89F13DFDAEQ34999036-03904123-8E65-47C2-8134-4C60C1717D9CQ35014083-85376ECB-BF6D-4FC5-929F-F41E9B609CCCQ35033213-904EDDF4-A44A-49F8-B90F-D329827220D5Q35034951-094646F1-8FFD-414A-AF90-CA75734788B4Q35053087-30BECAFC-FC3A-4E3F-8FAA-CB73E482CDB7Q35126233-A5431E2D-2653-4AAD-9628-AFBC9F6AAE4CQ35126559-65D511DD-3FB8-40C0-887E-5A2924584BA5Q35470460-F08D170D-DA0A-4610-9F4B-F71DA6196C5E
P2860
description
1988 nî lūn-bûn
@nan
1988 թուականի Մարտին հրատարակուած գիտական յօդուած
@hyw
1988 թվականի մարտին հրատարակված գիտական հոդված
@hy
1988年の論文
@ja
1988年論文
@yue
1988年論文
@zh-hant
1988年論文
@zh-hk
1988年論文
@zh-mo
1988年論文
@zh-tw
1988年论文
@wuu
name
The Control of Neuron Number
@ast
The Control of Neuron Number
@en
The Control of Neuron Number
@en-gb
The Control of Neuron Number
@nl
type
label
The Control of Neuron Number
@ast
The Control of Neuron Number
@en
The Control of Neuron Number
@en-gb
The Control of Neuron Number
@nl
altLabel
The control of neuron number
@en
prefLabel
The Control of Neuron Number
@ast
The Control of Neuron Number
@en
The Control of Neuron Number
@en-gb
The Control of Neuron Number
@nl
P3181
P1476
The Control of Neuron Number
@en
P2093
R W Williams
P304
P3181
P356
10.1146/ANNUREV.NE.11.030188.002231
P407
P577
1988-03-01T00:00:00Z