http://www.bibsonomy.org/burst/concept/tag/saccadesBibSonomy BuRST Feed for /concept/tag/saccades2008-10-16T09:00:55+02:00CCNLab BibTeXhttp://www.bibsonomy.org/bibtex/27c03a8cd87708a78a984a18dfb7678bd/brian.mingusbrian.mingus2008-09-16T23:39:07+02:00mulatta; Mapping; Restraint, Eye Association Animals; Macaca Brain Prefrontal Reaction Functional Laterality; Saccades Physical; Learning; Neurons; Movements; Cortex; Time; <span style="color:#555555;">W. F. <a href="http://www.bibsonomy.org/author/Asaad">Asaad</a> und G. <a href="http://www.bibsonomy.org/author/Rainer">Rainer</a> und E. K. <a href="http://www.bibsonomy.org/author/Miller">Miller</a> </span><em>Neuron</em><em>21(6):1399--1407</em><em>Dec1998. </em>Tue Sep 16 23:39:07 CEST 2008NeuronDec61399--1407Neural activity in the primate prefrontal cortex during associative learning.211998mulatta; Mapping; Restraint, Eye Association Animals; Macaca Brain Prefrontal Reaction Functional Laterality; Saccades Physical; Learning; Neurons; Movements; Cortex; Time; CCNLab BibTeXhttp://www.bibsonomy.org/bibtex/23c40b6f15eb90ba660040b8707a2c523/brian.mingusbrian.mingus2008-09-16T23:39:07+02:00Nonlinear Animals; Cerebral Behavior, Laterality; Functional Animal; Dynamics; Neural Potentials; Action Decision (Computer); Neurons; Networks Cortex; Basal Primates; Psychological; Reaction Ganglia; Saccades Pathways; Making; Models, Time; <span style="color:#555555;">Chung-Chuan <a href="http://www.bibsonomy.org/author/Lo">Lo</a> und Xiao-Jing <a href="http://www.bibsonomy.org/author/Wang">Wang</a> </span><em>Nat Neurosci</em><em>9(7):956--963</em><em>Jul2006. </em>Tue Sep 16 23:39:07 CEST 2008Nat NeurosciJul7956--963Cortico-basal ganglia circuit mechanism for a decision threshold in reaction time tasks.92006Nonlinear Animals; Cerebral Behavior, Laterality; Functional Animal; Dynamics; Neural Potentials; Action Decision (Computer); Neurons; Networks Cortex; Basal Primates; Psychological; Reaction Ganglia; Saccades Pathways; Making; Models, Time; CCNLab BibTeXhttp://www.bibsonomy.org/bibtex/2eb2314ac1efabb9d73bda2247a41578a/brian.mingusbrian.mingus2008-09-16T23:39:07+02:00Allocation; Animals; Behavior, Male; Electrophysiology; Saccades Animal; Dopamine; Probability; Making; Decision Macaca; Neurons; Reward; Mesencephalon; Random Female; <span style="color:#555555;">Genela <a href="http://www.bibsonomy.org/author/Morris">Morris</a> und Alon <a href="http://www.bibsonomy.org/author/Nevet">Nevet</a> und David <a href="http://www.bibsonomy.org/author/Arkadir">Arkadir</a> und Eilon <a href="http://www.bibsonomy.org/author/Vaadia">Vaadia</a> und Hagai <a href="http://www.bibsonomy.org/author/Bergman">Bergman</a> </span><em>Nat Neurosci</em><em>9(8):1057--1063</em><em>Aug2006. </em>Tue Sep 16 23:39:07 CEST 2008Nat NeurosciAug81057--1063Midbrain dopamine neurons encode decisions for future action.92006Allocation; Animals; Behavior, Male; Electrophysiology; Saccades Animal; Dopamine; Probability; Making; Decision Macaca; Neurons; Reward; Mesencephalon; Random Female; Microsaccades uncover the orientation of covert at...[Vision Res. 2003] - PubMed Resulthttp://www.bibsonomy.org/bibtex/2a6ac7fcc4994e695e649edf9b2ba4505/tmalsburgtmalsburg2007-10-30T17:38:06+01:00vision B_scanpathsimilarity eyemovements saccades algorithm <span style="color:#555555;">Ralf <a href="http://www.bibsonomy.org/author/Engbert">Engbert</a> und Reinhold <a href="http://www.bibsonomy.org/author/Kliegl">Kliegl</a> </span><em>Vision Res</em><em>43(9):1035-1045</em><em>Apr2003. </em>Tue Oct 30 17:38:06 CET 2007Vision ResApr91035-1045Microsaccades uncover the orientation of covert attention432003vision B_scanpathsimilarity eyemovements saccades algorithm Fixational eye movements are subdivided into tremor, drift, and microsaccades. All three types of miniature eye movements generate small random displacements of the retinal image when viewing a stationary scene. Here we investigate the modulation of microsaccades by shifts of covert attention in a classical spatial cueing paradigm. First, we replicate the suppression of microsaccades with a minimum rate about 150 ms after cue onset. Second, as a new finding we observe microsaccadic enhancement with a maximum rate about 350 ms after presentation of the cue. Third, we find a modulation of the orientation towards the cue direction. These multiple influences of visual attention on microsaccades accentuate their role for visual information processing. Furthermore, our results suggest that microsaccades can be used to map the orientation of visual attention in psychophysical experiments.