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Comparative Neuroanatomy of the Lateral Accessory Lobe in the Insect BrainBumblebee Homing: The Fine Structure of Head Turning MovementsA Model for an Angular Velocity-Tuned Motion Detector Accounting for Deviations in the Corridor-Centering Response of the BeeSelective attention in the honeybee optic lobes precedes behavioral choices.Photoreceptor processing speed and input resistance changes during light adaptation correlate with spectral class in the bumblebee, Bombus impatiensAnatomical basis of sun compass navigation II: the neuronal composition of the central complex of the monarch butterfly.Honeybees (Apis mellifera) learn color discriminations via differential conditioning independent of long wavelength (green) photoreceptor modulation.The diversification of Heliconius butterflies: what have we learned in 150 years?Does Fine Color Discrimination Learning in Free-Flying Honeybees Change Mushroom-Body Calyx Neuroarchitecture?Synaptic Organization of Microglomerular Clusters in the Lateral and Medial Bulbs of the Honeybee Brain.Honeybees as a model for the study of visually guided flight, navigation, and biologically inspired robotics.Going with the flow: a brief history of the study of the honeybee's navigational 'odometer'.Where paths meet and cross: navigation by path integration in the desert ant and the honeybee.An insect-inspired model for visual binding I: learning objects and their characteristics.Age-related and light-induced plasticity in opsin gene expression and in primary and secondary visual centers of the nectar-feeding ant Camponotus rufipes.Improved color constancy in honey bees enabled by parallel visual projections from dorsal ocelli.Color Difference and Memory Recall in Free-Flying Honeybees: Forget the Hard Problem.Topographically distinct visual and olfactory inputs to the mushroom body in the Swallowtail butterfly, Papilio xuthus.Sound-sensitive neurons innervate the ventro-lateral protocerebrum of the heliothine moth brain.Identifying functional connections of the inner photoreceptors in Drosophila using Tango-Trace.Visual motion-sensitive neurons in the bumblebee brain convey information about landmarks during a navigational task.Membrane filtering properties of the bumblebee (Bombus terrestris) photoreceptors across three spectral classes.Retinal perception and ecological significance of color vision in insects.Colour constancy in insects.An insect-inspired model for visual binding II: functional analysis and visual attention.Segregation of visual inputs from different regions of the compound eye in two parallel pathways through the anterior optic tubercle of the bumblebee (Bombus ignitus).Counting insects.Colour processing in complex environments: insights from the visual system of bees.Toward a Mechanistic Understanding of Color Vision in Insects.Investment in higher order central processing regions is not constrained by brain size in social insects.Multimodal integration and stimulus categorization in putative mushroom body output neurons of the honeybee.Assessing the ecological significance of bee visual detection and colour discrimination on the evolution of flower colours
P2860
Q26738312-7D9CCAB5-C2E6-4093-9F8D-7892CC886F4EQ27300881-94A723DD-5029-4620-9900-8A3D4F4F78B7Q28551837-9C690FD2-2BFA-448E-BEFF-BA694F87EB8BQ30575522-014DFFC2-14CD-426A-8916-FA318D1C20FFQ34064339-DC7863E0-6104-4364-8A05-A843D7E23799Q34293597-BACEE3BC-FC09-440E-B79C-5B886A7D449BQ34479036-241C20A6-3389-415F-98DE-937D51F8CF2DQ35664966-516388B6-9B2E-4DB4-9341-11799539B589Q36174939-69F23184-49E6-462A-89C8-634197284554Q37382319-58202D96-31C2-4066-B09B-F98AFCE5D7BCQ37870033-707467BF-A34C-4B15-A54D-C5CFE3F453F9Q38205149-AF88A146-FFF2-4A1E-8699-D47D8C49E97FQ38562042-3E24D4F0-DE15-4A17-A13F-3A44DAD73F8FQ38902238-A261D8D7-AF4C-4188-82D1-810122CB3943Q40151429-61BE62E8-BE9B-457D-829C-9939DBF59037Q40483448-8374F490-B709-4D23-9F12-CAC11C7E535BQ41420697-C001E063-393D-4B99-A50D-A55B58E161A6Q42001680-916E0312-8F84-4A5D-B608-663F62260846Q42005588-F6D58D62-353E-4953-8DE4-909AE261A7ADQ42779136-71BEE585-B2DF-4DAD-84CA-E8B3ADBABAB4Q42913483-2B322D12-3E37-4C4F-A943-26ACEF72A30DQ44341359-AE1157A6-B662-4167-82E4-85FB37D10283Q46247459-66DC738B-AB61-461B-9DF2-8EC24C6134D9Q46916726-AE17D5A1-2B34-48AD-BA6C-0FB1C560B506Q47926323-A2C9304C-96D6-4B92-BEA8-9607A1962DE8Q48875322-9752FD7B-73B5-43C4-8920-AC976628FC3DQ50543096-BFEBD963-3717-4E44-B4D9-65F0218C9BDBQ51027624-529AC0C0-909A-481D-AAD6-776AE3080B85Q51148241-33A7A1D2-715B-4185-8D0D-F2BEE491D5D9Q51843216-30B72906-42F8-422B-A3E1-DA8754B613FEQ53439245-05FE9D45-E6E5-423C-9943-9B0E94C92012Q57638542-B2499610-E27D-474C-8EC3-0FE8B391F3DD
P2860
description
article científic
@ca
article scientifique
@fr
articolo scientifico
@it
artigo científico
@pt
bilimsel makale
@tr
scientific article published on August 2009
@en
vedecký článok
@sk
vetenskaplig artikel
@sv
videnskabelig artikel
@da
vědecký článek
@cs
name
Visual processing in the central bee brain.
@en
Visual processing in the central bee brain.
@nl
type
label
Visual processing in the central bee brain.
@en
Visual processing in the central bee brain.
@nl
prefLabel
Visual processing in the central bee brain.
@en
Visual processing in the central bee brain.
@nl
P2093
P2860
P1476
Visual processing in the central bee brain.
@en
P2093
Andrew M Dacks
Angelique C Paulk
James Phillips-Portillo
Jean-Marc Fellous
Wulfila Gronenberg
P2860
P304
P356
10.1523/JNEUROSCI.1325-09.2009
P407
P577
2009-08-01T00:00:00Z