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Pubmed for Handhelds

PUBMED FOR HANDHELDS

Journal Abstract Search

696 related items for PubMed ID: 15193581

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  • 3. The neural mechanisms of top-down attentional control.
    Hopfinger JB, Buonocore MH, Mangun GR.
    Nat Neurosci; 2000 Mar; 3(3):284-91. PubMed ID: 10700262
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  • 5. Cognitive control mechanisms revealed by ERP and fMRI: evidence from repeated task-switching.
    Swainson R, Cunnington R, Jackson GM, Rorden C, Peters AM, Morris PG, Jackson SR.
    J Cogn Neurosci; 2003 Aug 15; 15(6):785-99. PubMed ID: 14511532
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  • 6. Brain structures involved in visual search in the presence and absence of color singletons.
    Talsma D, Coe B, Munoz DP, Theeuwes J.
    J Cogn Neurosci; 2010 Apr 15; 22(4):761-74. PubMed ID: 19309291
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  • 8. 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 15; 27(5):945-58. PubMed ID: 20636208
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  • 9. Where and when the anterior cingulate cortex modulates attentional response: combined fMRI and ERP evidence.
    Crottaz-Herbette S, Menon V.
    J Cogn Neurosci; 2006 May 15; 18(5):766-80. PubMed ID: 16768376
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  • 10. Who comes first? The role of the prefrontal and parietal cortex in cognitive control.
    Brass M, Ullsperger M, Knoesche TR, von Cramon DY, Phillips NA.
    J Cogn Neurosci; 2005 Sep 15; 17(9):1367-75. PubMed ID: 16197690
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  • 11. Effective connectivity in target stimulus processing: a dynamic causal modeling study of visual oddball task.
    Brázdil M, Mikl M, Marecek R, Krupa P, Rektor I.
    Neuroimage; 2007 Apr 01; 35(2):827-35. PubMed ID: 17258910
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  • 12. [Brain electrical source analysis of the response to visual target and distractor stimuli].
    Li Y, Hu Y, Ren L, Sun Z.
    Sheng Wu Yi Xue Gong Cheng Xue Za Zhi; 2012 Oct 01; 29(5):933-40. PubMed ID: 23198438
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  • 13. Event-related potential study of novelty processing abnormalities in autism.
    Sokhadze E, Baruth J, Tasman A, Sears L, Mathai G, El-Baz A, Casanova MF.
    Appl Psychophysiol Biofeedback; 2009 Mar 01; 34(1):37-51. PubMed ID: 19199028
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  • 14. Electrophysiological indices of target and distractor processing in visual search.
    Hickey C, Di Lollo V, McDonald JJ.
    J Cogn Neurosci; 2009 Apr 01; 21(4):760-75. PubMed ID: 18564048
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  • 15. Difficulty of discrimination modulates attentional capture by regulating attentional focus.
    Sawaki R, Katayama J.
    J Cogn Neurosci; 2009 Feb 01; 21(2):359-71. PubMed ID: 18510441
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  • 16. Isolating event-related potential components associated with voluntary control of visuo-spatial attention.
    McDonald JJ, Green JJ.
    Brain Res; 2008 Aug 28; 1227():96-109. PubMed ID: 18621037
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  • 17. Stimulus context determines whether non-target stimuli are processed as task-relevant or distractor information.
    Sawaki R, Katayama J.
    Clin Neurophysiol; 2006 Nov 28; 117(11):2532-9. PubMed ID: 17005448
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  • 18. Sources of top-down control in visual search.
    Weidner R, Krummenacher J, Reimann B, Müller HJ, Fink GR.
    J Cogn Neurosci; 2009 Nov 28; 21(11):2100-13. PubMed ID: 19199412
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  • 19. The separation of processing stages in a lexical interference fMRI-paradigm.
    Abel S, Dressel K, Bitzer R, Kümmerer D, Mader I, Weiller C, Huber W.
    Neuroimage; 2009 Feb 01; 44(3):1113-24. PubMed ID: 19015036
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  • 20. fMRI in an oddball task: effects of target-to-target interval.
    Stevens MC, Calhoun VD, Kiehl KA.
    Psychophysiology; 2005 Nov 01; 42(6):636-42. PubMed ID: 16364059
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