The processing of color, motion, and stimulus timing are anatomically segregated in the bumblebee brain. - Wikidata - wikimedia - TriplyDB

The processing of color, motion, and stimulus timing are anatomically segregated in the bumblebee brain.

The processing of color, motion, and stimulus timing are anatomically segregated in the bumblebee brain.

http://www.wikidata.org/entity/Q37352334

about

More than colour attraction: behavioural functions of flower patterns Bumblebee Homing: The Fine Structure of Head Turning Movements A Model for an Angular Velocity-Tuned Motion Detector Accounting for Deviations in the Corridor-Centering Response of the Bee It takes two-coincidence coding within the dual olfactory pathway of the honeybee The central complex of the flesh fly, Neobellieria bullata: recordings and morphologies of protocerebral inputs and small-field neurons Parallel processing in the honeybee olfactory pathway: structure, function, and evolution.Photoreceptor spectral sensitivity in the bumblebee, Bombus impatiens (Hymenoptera: Apidae).Histamine-immunoreactive local neurons in the antennal lobes of the hymenoptera.Brain allometry and neural plasticity in the bumblebee Bombus occidentalis.Photoreceptor processing speed and input resistance changes during light adaptation correlate with spectral class in the bumblebee, Bombus impatiens Honeybees (Apis mellifera) learn color discriminations via differential conditioning independent of long wavelength (green) photoreceptor modulation.Does Fine Color Discrimination Learning in Free-Flying Honeybees Change Mushroom-Body Calyx Neuroarchitecture?Mapping chromatic pathways in the Drosophila visual system Representation of the brain's superior protocerebrum of the flesh fly, Neobellieria bullata, in the central body Visual processing in the central bee brain.Synaptic Organization of Microglomerular Clusters in the Lateral and Medial Bulbs of the Honeybee Brain.Color and polarization vision in foraging Papilio.Mechanisms, functions and ecology of colour vision in the honeybee.Color polymorphic lures target different visual channels in prey.Age-related and light-induced plasticity in opsin gene expression and in primary and secondary visual centers of the nectar-feeding ant Camponotus rufipes.The spatial frequency tuning of optic-flow-dependent behaviors in the bumblebee Bombus impatiens.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.Learning from learning and memory in bumblebees.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.Characterization of the first-order visual interneurons in the visual system of the bumblebee (Bombus terrestris).Spectral inputs and ocellar contributions to a pitch-sensitive descending neuron in the honeybee.Neural basis of forward flight control and landing in honeybees.An insect-inspired model for visual binding II: functional analysis and visual attention.Afferent neural pathways from the photoperiodic receptor in the bean bug, Riptortus pedestris.Age-related plasticity in the synaptic ultrastructure of neurons in the mushroom body calyx of the adult honeybee Apis mellifera.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).Decision-making and associative color learning in harnessed bumblebees (Bombus impatiens).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.Multiple spectral channels in branchiopods. II. Role in light-dependent behavior and natural light environments.Multimodal integration and stimulus categorization in putative mushroom body output neurons of the honeybee.

P2860

Q26750416-6C52AF26-1191-4728-8ED8-AC628C71D1CF Q27300881-DC893645-CCF7-4E72-9F01-145C3F858EFD Q28551837-976AF5FB-C224-4B71-B741-3309FC442184 Q30404815-0B81D8C6-502A-4EA9-9C73-65C069C8F502 Q30435934-111CB8B8-0255-41C4-BA0B-415511750060 Q30446944-F6A0E2D7-7861-4B9C-B29C-D2318D921D63 Q33659043-12DA6E53-FF7B-4190-B247-AB7E68DADE38 Q33917267-3B639869-09C4-4146-AF9B-DEFE5ABAA15C Q34038179-4328F1D0-5963-4BCD-B2EF-F98BC9302666 Q34064339-A84C8FED-DD01-4F29-A2F3-21ED027AD64A Q34479036-44A2CB29-02AA-43F2-AF6B-A43339E999AA Q36174939-8D4AC0F2-6A79-4D3E-BF65-BF58D194CC31 Q36371271-F85E0C82-09FE-43EB-A106-B0A29B1928E3 Q36926627-D317549D-8E74-4D20-AD84-1F13E8E85D8C Q37353710-5B73EA01-B833-4641-BD3F-F0A0270FFD9F Q37382319-A9C4C589-2BD3-4454-9AEE-C26E3567AEBF Q38203793-3C89338D-5629-4EFC-AC3C-B14F27880826 Q38211797-192C6D38-8ABD-4A74-B0F1-F4D9019FA764 Q39776186-06BA260F-DFEA-4D9F-9EAE-1DFF964144CE Q40151429-A08E56E1-FF5D-40CD-AB7C-E98502C51DF6 Q40274972-48A82D1D-BC11-4182-81C2-755FEF0D2F1E Q41420697-0572F094-6AEC-4E16-B942-ECEFA816EC02 Q42001680-3275E1DA-71EA-4110-BC59-95AF664AA977 Q42627329-588E0576-9FB1-4E3E-A9B5-3366EAABA93C Q42779136-FAC0EACA-5CA2-4A4E-854E-662A69EA8A35 Q42913483-3B9A3D63-B23A-4ECD-8011-356F4BEA5D05 Q44341359-CBB8E097-6E79-42D7-B47F-17F088E8B6D1 Q46331331-734FC38B-EC1A-4EF3-95A7-B8DE7658779C Q46893173-B15EDAAA-EAD3-4909-8017-1CF8AB602636 Q47157990-7D566BEB-C47E-4CD7-BE3B-2DE863840C55 Q47926323-AF65D8D3-F142-4F4F-833C-13AFC1A58F60 Q48330385-BD273AE8-189F-4C36-B4A2-2A83FBC68925 Q48607350-C0FCF88B-A30F-4760-A503-1B970C762076 Q48875322-215857A7-6951-4223-A06C-CCFD9B5FA7BD Q50243521-AACA0AD2-3A30-4D83-8872-85876FD6D8A7 Q51027624-DABF9933-8E89-4271-A3E6-F141192FC87D Q51148241-595AF5A0-0461-429D-BDD7-55029E63D4D1 Q51843216-B78742A0-5E4B-49AB-BA5B-EFBD7DC026A6 Q53070198-259936B4-B6DF-49A9-B628-5A65707CACB3 Q53439245-F5BDA4D3-390D-4890-9455-49C028E28EC4

P2860

The processing of color, motion, and stimulus timing are anatomically segregated in the bumblebee brain.

http://www.wikidata.org/entity/Q37352334

description

article científic

@ca

article scientifique

@fr

articolo scientifico

@it

artigo científico

@pt

bilimsel makale

@tr

scientific article published on June 2008

@en

vedecký článok

@sk

vetenskaplig artikel

@sv

videnskabelig artikel

@da

vědecký článek

@cs

name

The processing of color, motio ...... egated in the bumblebee brain.

@en

The processing of color, motio ...... egated in the bumblebee brain.

@nl

type

label

The processing of color, motio ...... egated in the bumblebee brain.

@en

The processing of color, motio ...... egated in the bumblebee brain.

@nl

prefLabel

The processing of color, motio ...... egated in the bumblebee brain.

@en

The processing of color, motio ...... egated in the bumblebee brain.

@nl

P1433

Q37352334-CCC3C7FB-6D53-4526-B01E-78A366C19E2A

P1476

Q37352334-2C74ABAA-C8C3-4D10-AC25-938281C12D4D

P2093

Q37352334-559DCEDE-9864-47EE-9764-BADE2DE26863

Q37352334-6CB09220-CFB0-4520-AB29-8B3437351BE9

Q37352334-708B0553-8AB5-4602-B626-AB71CE9B51F7

Q37352334-7C85EB6B-8FB0-4F02-B3EB-1A1458CC07B3

Q37352334-D73B44CD-27EB-4716-8629-3AD231FE3D4E

P2860

Q37352334-0231CA48-44C5-4702-8136-B8C9FEB3DCFC

Q37352334-09236C88-8A25-4E83-8034-400F512056D9

Q37352334-0E9A85CE-7EEC-40A5-A30E-507279618413

Q37352334-1268E49F-72A0-4178-A935-E9B8901AE4AE

Q37352334-127A11D5-ECF5-4B57-AC32-D91472060D3C

Q37352334-1A89DA8C-0B86-460B-902D-030317FBC51B

Q37352334-21A5A6CE-EBCB-4D56-952E-2E9F8859D9A8

Q37352334-24FF315C-B50E-4D41-8591-64CD28C477A6

Q37352334-3672C22F-C462-40B8-884C-08AE0B97E5FA

Q37352334-3AC4E0ED-817D-4A43-BB89-D0DFE5A74586

P304

Q37352334-530329F2-0DC1-4178-A340-6E5E0F2900FF

P31

Q37352334-F2A592A4-FE04-41DA-B0FB-74B997F0A6A6

P356

Q37352334-7ECBEF1A-EE56-4FB9-9FD2-C9DAD62D958F

P407

Q37352334-11234CA5-2872-451D-A503-337BEF63A572

P433

Q37352334-23648DAB-833B-443D-AE81-D09C43731DD4

P478

Q37352334-70E336B3-C7BF-423D-A8FE-35406BDABE2A

P577

Q37352334-0E8B11CD-B60F-47DB-AFCA-B5AB404BCA7B

P698

Q37352334-308B120A-5DA2-45E5-BFF3-F28A31A4E724

P932

Q37352334-CF9FA818-1251-464F-94BF-94767EC1B36B

P356

JNEUROSCI.1196-08.2008

P1433

Journal of Neuroscience

P1476

The processing of color, motio ...... egated in the bumblebee brain.

@en

P2093

Andrew M Dacks

http://www.w3.org/2001/XMLSchema#string

Angelique C Paulk

http://www.w3.org/2001/XMLSchema#string

James Phillips-Portillo

http://www.w3.org/2001/XMLSchema#string

Jean-Marc Fellous

http://www.w3.org/2001/XMLSchema#string

Wulfila Gronenberg

http://www.w3.org/2001/XMLSchema#string

P2860

Mushroom body memoir: from maps to models

Biogenic amines in the brain of the honeybee: cellular distribution, development, and behavioral functions.

Single units and visual cortical organization.

What do the mushroom bodies do for the insect brain? an introduction

Regulation of spike timing in visual cortical circuits.

Neural networks in the cockpit of the fly.

Organization of the honey bee mushroom body: representation of the calyx within the vertical and gamma lobes.

Structure and function of parallel pathways in the primate early visual system.

The circuitry of V1 and V2: integration of color, form, and motion.

Convergent processing in honeybee vision: multiple channels for the recognition of shape

P304

6319-6332

http://www.w3.org/2001/XMLSchema#string

P31

scholarly article

P356

10.1523/JNEUROSCI.1196-08.2008

http://www.w3.org/2001/XMLSchema#string

P407

P433

25

http://www.w3.org/2001/XMLSchema#string

P478

28

http://www.w3.org/2001/XMLSchema#string

P577

2008-06-01T00:00:00Z

http://www.w3.org/2001/XMLSchema#dateTime

P698

18562602

http://www.w3.org/2001/XMLSchema#string

P932

3844780

http://www.w3.org/2001/XMLSchema#string