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Some publications using EYE-EEG




  1. Dimigen, O., Kliegl, R., & Sommer, W. (2012). Trans-saccadic parafoveal preview benefits in fluent reading: a study with fixation-related brain potentials. Neuroimage, 62, 381-393 [link]
  2. Simola, J., Torniainen, J., Moisala, M., Kivikangas, M., Krause, C.M. (2013). Eye movement related brain responses to emotional scenes during free viewing. Front Syst Neurosci, 7, 41.
  3. Baekgaard, P., Petersen, M. K., & Larsen, J. E. (2014). In the twinkling of an eye: Synchronization of EEG and eye tracking based on blink signatures. 4th International Workshop on Cognitive Information Processing (CIP) (pp. 1-6). IEEE. [link]
  4. Meyberg, S., Werkle-Bergner, M., Sommer, W., & Dimigen, O. (2015). Microsaccade-related brain potentials signal the focus of visuospatial attention. Neuroimage, 104, 79-88 [link]
  5. Kornrumpf, B. & Sommer, W. (2015). Modulation of the attentional span by foveal and parafoveal task load: An ERP study using attentional probes. Psychophysiology,52, 1218-27 [link]
  6. Ehinger, B., König, P., & Ossandon, J.P. (2015). Predictions of visual content across eye movements and their modulation by inferred information. Journal of Neuroscience, 35, 7403-13 [link]
  7. Li, N., Niefind, F., Wang, S., Sommer, W. & Dimigen, O. (2015). Parafoveal processing in reading Chinese sentences: Evidence from event-related brain potentials. Psychophysiology. [author preprint]
  8. Scharinger, C., Kammerer, Y., & Gerjets, P. (2015). Pupil Dilation and EEG Alpha Frequency Band Power Reveal Load on Executive Functions for Link-Selection Processes during Text Reading. Plos One, doi:10.1371/journal.pone.013060
  9. Krebber, M., Harwood, J., Spitzer, B., Keil, J., & Senkowski, D. (2015) Visuotactile motion congruence enhances gamma-band activity in visual and somatosensory cortices Neuroimage, 117, 160-169
  10. Scharinger, C., Soutschek, A., Schubert, T., Gerjets, P. (2015). When flanker meets the n-back: What EEG and pupil dilation data reveal about the interplay between the two central-executive working memory functions inhibition and updating. Psychophysiology, 52, 1293-1304
  11. Krebber, M., Harwood, J., Spitzer, B., Keil, J., Senkowski, D. (2015). Visuotactile motion congruence enhances gamma-band activity in visual and somatosensory cortices. Neuroimage
  12. Emmerling, T.C., Zimmermann, J., Sorger, B., Frost, M.A., & Goebel R. (2016). Decoding the direction of imagined visual motion using 7T ultra-high field fMRI. Neuroimage [link]
  13. Huber-Huber, C., Dityea, T, Marchantea, M. & Ansorge, U. (2016). Using Temporally Aligned Event-Related Potentials for the Investigation of Attention Shifts Prior to and During Saccades. Neuropsychologia[link]
  14. Kovalenko, L., Busch, N. (2016). Probing the dynamics of perisaccadic vision with EEG. Neuropsychologia, 85, 337-348 [link]
  15. Chmielewski, W., Mückschel, M., Ziemssen, T. & Beste, C. (2016). The Norepinephrine System Affects Specific Neurophysiological Subprocesses in the Modulation of Inhibitory Control by Working Memory Demands. Human Brain Mapping
  16. Kornrumpf, B., Niefind, F., Sommer, W., & Dimigen, O. (2016). Neural correlates of word recognition: A systematic comparison of natural reading and RSVP. Journal of Cognitive Neuroscience. 28 (9) 28:9, 1374-1391. doi:10.1162/jocn_a_00977 [author pdf]
  17. Niefind, F., & Dimigen, O. (2016). Dissociating parafoveal preview benefit and parafovea-on-fovea effects during reading: A combined eye tracking and EEG study. Psychophysiology [abstract]
  18. McLelland, D., Lavergne, L. & VanRullen, R. (2016). The phase of ongoing EEG oscillations predicts the amplitude of peri-saccadic mislocalization. Scientific Reports 6:29335, doi: 10.1038/srep29335
  19. Mückschel, M., Gohil, K., Ziemssen, T., Beste, C. (in press). The norepinephrine system and its relevance for multi-component behavior. Neuroimage
  20. Weaver, M. D., Van Zoest, W. & Hickey, C. (2016). A temporal dependency account of attentional inhibition in oculomotor control. Neuroimagelink
  21. van den Brink, R. L., Pfeffer, T., Warren, C. M. et al. (2016). Catecholaminergic neuromodulation shapes intrinsic MRI functional connectivity in the human brain. Journal of Neuroscience, 36(30), 7865-7876.
  22. Ries, A., Touryan, J., Ahrens, B., & Connolly, P. (2016). The Impact on Task Demands on Fixation-Related Brain Potentials during Guided Search. Plos ONE link
  23. Weaver, M.D., Van Zoest, W., & Hickey, C. (2017). The impact of salience and visual working memory on the monitoring and control of saccadic behaviour: An eye-tracking and EEG study. Psychophysiology.
  24. Mückschel, M., Chmielewski, W., Ziemssen, & Beste, C. (2017). The norepinephrine system shows information-content specific properties during cognitive control - evidence from EEG and pupillary responses. Neuroimage.
  25. Kornrumpf, B., Dimigen, O. & Sommer, W. (2017). Lateralization of posterior Alpha-EEG reflects the distribution of spatial attention during saccadic reading. Psychphysiology, 54, 809-823 [link]
  26. Meyberg, S., Sommer, W., & Dimigen, O. (2017). How microsaccades relate to lateralized ERP components of spatial attention: A co-registration study.Neuropsychologia, 99, 64-80 [link]
  27. Meindertsma, N., Kloosterman, A., Nolte, G., Engel, A.K., & Donner, T.H. (2017). Multiple Transient Signals in Human Visual Cortex Associated with an Elementary Decision. Journal of Neuroscience, 37, 5744-5757 [link]
  28. Dippel, G., Mückschel, M., Ziemssen, T., Beste, C. (2017). Demands on response inhibition processes determine modulations of theta band activity in superior frontal areas and correlations with pupillometry. Implications for the norepinephrine system during inhibitory control.Neuroimage, 157, 575-585
  29. Xue, J., Quan, C., Li, C., Yue, J., & Zhang, C. (2017). A crucial temporal accuracy test of combining EEG and Tobii eye tracker. Medicine, 96(13).
  30. Cuesta-Frau, D. et al. (2017). Noisy EEG signals classification based on entropy metrics. Performance assessment using first and second generation statistics. Computers in Biology and Medicine, 87, 141-151
  31. Wolff, N., Mückschel, M. Ziemssen, T., & Beste, C. (2017). The role of phasic norepinephrine modulations during task switching: evidence for specific effects in parietal areas. Brain Structure and Function
  32. Magazzini, L., Singh, K.D. (in press). Spatial attention modulates visual gamma oscillations across the human ventral stream. NeuroImage [link]
  33. Lehr, E.J., Dresler, T.D., Hautzinger, M., & Zipfel, S. (2018). Food specific inhibitory control under negative mood in binge-eating disorder: Evidence from a multimethod approach. Eating disorders [link]
  34. Gao, Y., Huber, C., Sabel, B.A. (2018). Stable Microsaccades and Microsaccade-Induced Global Alpha Band Phase Reset Across the Life Span. Invest Ophthalmol Vis Sci, 59, 2032-2041
  35. Kostandyan, M., Bombeke, K. et al. (2018). Differential effects of sustained and transient effort triggered by reward – a combined EEG and pupillometry study. Neuropsychologia https://doi.org/10.1016/j.neuropsychologia.2018.04.032
  36. Hollenstein, N., Rotsztejn, J., Troendle, M., Pedroni, A., Zhang, C., & Langer, N. (2018). ZuCo, a simultaneous EEG and eye-tracking resource for natural sentence reading. Scientific data, 5, 180291. [cites random paper as reference, but uses EYE-EEG, so that might count :-)]
  37. Borowicz, A. (2018). Using a multichannel Wiener filter to remove eye-blink artifacts from EEG data. Biomedical Signal Processing and Control, 45, 246-255.
  38. Van Driel, Ort E. , Fahrenfort, C., & Olivers, C. (2018). Beta and theta oscillations differentially support free versus forced control over target selection in visual search. BioRxiv preprint. doi: 10.1101/422691
  39. Martin, J. G., Davis, C. E., Riesenhuber, M., & Thorpe, S. J. (2018). High resolution human eye tracking during continuous visual search. Frontiers in Human Neuroscience, 12, 374.
  40. Adelhöfer, N., Mückschel, M., Teufert, B., Ziemssen, T., & Beste, C. (2019). Anodal tDCS affects neuromodulatory effects of the norepinephrine system on superior frontal theta activity during response inhibition. Brain Structure and Function, 1-10.
  41. Degno, F., Loberg, O., Zang, C., Zhang, M., Donnelly, N., & Liversedge, S. P. (2019). Parafoveal Previews and Lexical Frequency in Natural Reading: Evidence from Eye Movements and Fixation-Related Potentials. Journal of Experimental Psychology: General
  42. Ehinger, B. & Dimigen, O. (2019). Unfold: An integrated toolbox for overlap correction, nonlinear modeling, and regression-based EEG analysis. PeerJ [link]
  43. Driller, K., Dimigen, O., Stephani, T., & Sommer, W. (in press). Large lateralized EDAN-like brain potentials in a gaze-shift detection task.Psychophysiology
  44. Pertermann, M., Mückschel, et al. (2019). On the interrelation of 1/f neural noise and norepinephrine system activity during motor response inhibition. Journal of Neurophysiology [link]
  45. Schreiter, M. L., Chmielewski, W. X., Mückschel, M., Ziemssen, T., & Beste, C. (2019). How the depth of processing modulates emotional interference - evidence from EEG and pupil diameter data. Cognitive, Affective, & Behavioral Neuroscience, 1-16.
  46. Schweitzer, R. & Rolfs, M. (2019). An adaptive algorithm for fast and reliable online saccade detection. BioRxiv doi: http://dx.doi.org/10.1101/693309.
  47. Dimigen, O. & Ehinger, B.V. (2020). Analyzing combined eye-tracking/EEG experiments with (non)linear deconvolution models. Journal of Vision Preprint: [link]
  48. Hauser, M. F., Heba, S., Schmidt-Wilcke, T., Tegenthoff, M., & Manahan-Vaughan, D. (2019). Cerebellar-hippocampal processing in passive perception of visuospatial change: An ego-and allocentric axis? Human brain mapping
  49. Coco, M., Nuthmann, A., & Dimigen, O. (2020). Fixation-related brain activity during semantic integration of object-scene information. Journal of Cognitive Neuroscience, 32, 571-589 [link]
  50. Mückschel, M., Ziemssen, T., & Beste, C. (2020). Properties of lower level processing modulate the actions of the norepinephrine system during response inhibition. Biological Psychology, 107862/
  51. Buonocore, A., Dimigen, O., & Melcher, D. (2020). Post-saccadic face processing is modulated by pre-saccadic preview: Evidence from fixation-related potentials. Journal of Neuroscience. 0861-19. doi: 10.1523/JNEUROSCI.0861-19.2020
  52. Zhou, Y., & Yu, Y. (2020). Human Visual Search Follows Suboptimal Bayesian Strategy Revealed by a Spatiotemporal Computational Model. bioRxiv [link]
  53. Giller, F., Mückschel, Ziemssen, & Beste (2020). A possible role of the norepinephrine system during sequential cognitive flexibility: evidence from EEG and pupil diameter data. Cortex
  54. Ceh, S., Annerer-Walcher, S., Körner, C., Rominger, C., Kober, S. E., Fink, A., & Benedek, M. (2020). Neurophysiological indicators of internal attention: An EEG-eye-tracking co-registration study. PsyArXiv Preprint
  55. Gopalan, P., Loberg, O., et al. (2020). Attentional Processes in Children With Attentional Problems or Reading Difficulties as Revealed Using Brain Event-Related Potentials and Their Source Localization. Frontiers in Human Neuroscience doi: 10.3389/fnhum.2020.00160
  56. Ceh, Annerer-Walcher et al. & Benedek (2020). Neurophysiological indicators of internal attention: An electroencephalography-eye-tracking coregistration study. Brain & Behavior. doi: 10.1002/brb3.1790
  57. Scharinger, C., Schüler, A., & Gerjets, P. (2020). Using eye-tracking and EEG to study the mental processing demands during learning of text-picture combinations. International Journal of Psychophysiology
  58. Domic-Siede, M., Irani, M. et al. & Ossandon (2020). Theta Activity from Frontopolar Cortex, mid-Cingulate Cortex and Anterior Cingulate Cortex Shows Different Role in Cognitive Planning Performance. NeuroImage
  59. Baum, J., Främer, & Abdel-Rahman (2020). Fake news and metacognition: Emotional contents enhance confidence in social judgments based on untrustworthy headlines. PsyArXiv
  60. Zhou, Y., & Yu, Y. Human visual search follows a suboptimal Bayesian strategy revealed by a spatiotemporal computational model and experiment. Communications Biology, 4(1), 1-16.
  61. Domic-Siede, Irani, Valdes et al. (2021). Theta activity from frontopolar cortex, mid-cingulate cortex and anterior cingulate cortex shows different roles in cognitive planning performance. NeuroImage, 226, 117557
  62. Dahl, M. J., Mather, M., Sander, M. C., & Werkle-Bergner, M. (2020). Noradrenergic responsiveness supports selective attention across the adult lifespan. Journal of Neuroscience, 40(22), 4372-4390.
  63. Huber-Huber, C., Steininger, J. et al. (2021). Psychophysical dual-task setups do not measure pre-saccadic attention but saccade-related strengthening of sensory representations. Psychophysiology, doi:10.1111/psyp.13787
  64. Daniel, E & Dinstein, I. (2021). Individual Magnitudes of Neural Variability Quenching are Associated with Motion Perception Abilities. Journal of Neurophysiology
  65. Pereira, J., Kobler, R. J., Ofner, P., Schwarz, A., & Müller-Putz, G. R. (2021). Online detection of movement during natural and self-initiated reach-and-grasp actions from EEG signals. Journal of Neural Engineering.
  66. Van Zoest, W., Huber-Huber, C., Weaver, M. & Hickey, C. (2021). Strategic distractor suppression improves selective control in human vision. Journal of Neuroscience, JN-RM-0553-21; https://doi.org/10.1523/JNEUROSCI.0553-21.2021
  67. Wu, Q. et al. (2021). Emotion classification on eye-tracking and electroencephalograph fused signals employing deep gradient neural networks. Applied Soft Computing, Vol. 110, 107752
  68. van Zoest, W., Huber-Huber, C., Weaver, M. D., & Hickey, C. (2021). Strategic distractor suppression improves selective control in human vision. Journal of Neuroscience, 41(33), 7120-7135.
  69. Li, M., Guo, F., Ren, Z., & Duffy, V. G. (2021). A visual and neural evaluation of the affective impression on humanoid robot appearances in free viewing. International Journal of Industrial Ergonomics, 103159.
  70. Yu, S., Mückschel, M., Beste, C. (2021). Superior frontal regions reflect the dynamics of task engagement and theta band-related control processes in time-on task effects. Scientific Reports
  71. Zhang, Q., Huang, Z., Li, L., & Li, S. (2022). Visual search training benefits from the integrative effect of enhanced covert attention and optimized overt eye movements. bioRxiv https://doi.org/10.1101/2022.01.03.474790
  72. Yu, S., Ghin, F., Mückschel, M., Ziemssen, T., Stock, A. K., & Beste, C. (2022). A role of the norepinephrine system or effort in the interplay of different facets of inhibitory control. Neuropsychologia, 108143.
  73. Li, N., Dimigen, O., Sommer, W., & Wang, S. (2022). Parafoveal words can modulate sentence meaning: Electrophysiological evidence from an RSVP-with-flanker task. Psychophysiology, https://doi.org/10.1111/psyp.14053
  74. Zhang, Q. et al. (2022). Visual search training benefits from the integrative effect of enhanced covert attention and optimized overt eye movements. Journal of Visiondoi: 10.1167/jov.22.8.7

 

(Not keeping track of all recent papers using EYE-EEG, please send me your paper and I'll add it)