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Items: 1 to 20 of 407

1.

The activation of attentional networks.

Fan J, McCandliss BD, Fossella J, Flombaum JI, Posner MI.

Neuroimage. 2005 Jun;26(2):471-9.

PMID:
15907304
2.
3.
4.

Associations between regional cortical thickness and attentional networks as measured by the attention network test.

Westlye LT, Grydeland H, Walhovd KB, Fjell AM.

Cereb Cortex. 2011 Feb;21(2):345-56. doi: 10.1093/cercor/bhq101.

PMID:
20525771
5.

Diurnal patterns of activity of the orienting and executive attention neuronal networks in subjects performing a Stroop-like task: a functional magnetic resonance imaging study.

Marek T, Fafrowicz M, Golonka K, Mojsa-Kaja J, Oginska H, Tucholska K, Urbanik A, Beldzik E, Domagalik A.

Chronobiol Int. 2010 Jul;27(5):945-58. doi: 10.3109/07420528.2010.489400.

PMID:
20636208
6.

Cognitive and brain consequences of conflict.

Fan J, Flombaum JI, McCandliss BD, Thomas KM, Posner MI.

Neuroimage. 2003 Jan;18(1):42-57.

PMID:
12507442
7.

Right temporal-parietal junction engagement during spatial reorienting does not depend on strategic attention control.

Natale E, Marzi CA, Macaluso E.

Neuropsychologia. 2010 Mar;48(4):1160-4. doi: 10.1016/j.neuropsychologia.2009.11.012.

PMID:
19932706
8.

Development of attentional networks: an fMRI study with children and adults.

Konrad K, Neufang S, Thiel CM, Specht K, Hanisch C, Fan J, Herpertz-Dahlmann B, Fink GR.

Neuroimage. 2005 Nov 1;28(2):429-39.

PMID:
16122945
9.

A neural network elicited by parametric manipulation of the attention load.

Mazoyer P, Wicker B, Fonlupt P.

Neuroreport. 2002 Dec 3;13(17):2331-4.

PMID:
12488821
11.

An event-related fMRI Study of exogenous facilitation and inhibition of return in the auditory modality.

Mayer AR, Harrington DL, Stephen J, Adair JC, Lee RR.

J Cogn Neurosci. 2007 Mar;19(3):455-67.

PMID:
17335394
12.

Neural mechanisms of visual attention: object-based selection of a region in space.

Arrington CM, Carr TH, Mayer AR, Rao SM.

J Cogn Neurosci. 2000;12 Suppl 2:106-17.

PMID:
11506651
13.

Parallel networks operating across attentional deployment and motion processing: a multi-seed partial least squares fMRI study.

Caplan JB, Luks TL, Simpson GV, Glaholt M, McIntosh AR.

Neuroimage. 2006 Feb 15;29(4):1192-202.

PMID:
16236528
14.

Development of attentional networks in childhood.

Rueda MR, Fan J, McCandliss BD, Halparin JD, Gruber DB, Lercari LP, Posner MI.

Neuropsychologia. 2004;42(8):1029-40.

PMID:
15093142
15.

Neural networks of response shifting: influence of task speed and stimulus material.

Loose R, Kaufmann C, Tucha O, Auer DP, Lange KW.

Brain Res. 2006 May 23;1090(1):146-55.

PMID:
16643867
16.

On the neural basis of focused and divided attention.

Nebel K, Wiese H, Stude P, de Greiff A, Diener HC, Keidel M.

Brain Res Cogn Brain Res. 2005 Dec;25(3):760-76.

PMID:
16337110
17.

Automatic attention orienting by social and symbolic cues activates different neural networks: an fMRI study.

Hietanen JK, Nummenmaa L, Nyman MJ, Parkkola R, Hämäläinen H.

Neuroimage. 2006 Oct 15;33(1):406-13.

PMID:
16949306
18.

Orienting attention in time: behavioural and neuroanatomical distinction between exogenous and endogenous shifts.

Coull JT, Frith CD, Büchel C, Nobre AC.

Neuropsychologia. 2000;38(6):808-19.

PMID:
10689056
19.

A large-scale distributed network for covert spatial attention: further anatomical delineation based on stringent behavioural and cognitive controls.

Gitelman DR, Nobre AC, Parrish TB, LaBar KS, Kim YH, Meyer JR, Mesulam M.

Brain. 1999 Jun;122 ( Pt 6):1093-106.

PMID:
10356062
20.

Testing the efficiency and independence of attentional networks.

Fan J, McCandliss BD, Sommer T, Raz A, Posner MI.

J Cogn Neurosci. 2002 Apr 1;14(3):340-7.

PMID:
11970796

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