TY - JOUR
T1 - Spatial attention enhances cortical tracking of quasi-rhythmic visual stimuli
AU - Tabarelli, Davide
AU - Keitel, Christian
AU - Gross, Joachim
AU - Baldauf, Daniel
N1 - Funding Information:
We would like to thank the research groups of Uri Hasson. Angelika Lingnau, Olivier Collignon and Scott Fairhall for sharing previously acquired anatomical MRI scans for some of our experimental subjects. DT was funded in part by the Erasmus + program of the European Union. CK and JG were funded by a Wellcome Trust Senior Investigator Grant awarded to JG (#098433). CK received support from Wellcome Trust ISSF Secondment (204820/Z/16/Z) and BBSRC Flexible Talent Mobility funding (BB/R506576/1) awarded by the University of Glasgow.
Funding Information:
We would like to thank the research groups of Uri Hasson. Angelika Lingnau, Olivier Collignon and Scott Fairhall for sharing previously acquired anatomical MRI scans for some of our experimental subjects. DT was funded in part by the Erasmus + program of the European Union . CK and JG were funded by a Wellcome Trust Senior Investigator Grant awarded to JG (# 098433 ). CK received support from Wellcome Trust ISSF Secondment ( 204820/Z/16/Z ) and BBSRC Flexible Talent Mobility funding (BB/R506576/1) awarded by the University of Glasgow . Appendix A
Publisher Copyright:
© 2019
PY - 2020/3
Y1 - 2020/3
N2 - Successfully interpreting and navigating our natural visual environment requires us to track its dynamics constantly. Additionally, we focus our attention on behaviorally relevant stimuli to enhance their neural processing. Little is known, however, about how sustained attention affects the ongoing tracking of stimuli with rich natural temporal dynamics. Here, we used MRI-informed source reconstructions of magnetoencephalography (MEG) data to map to what extent various cortical areas track concurrent continuous quasi-rhythmic visual stimulation. Further, we tested how top-down visuo-spatial attention influences this tracking process. Our bilaterally presented quasi-rhythmic stimuli covered a dynamic range of 4–20 Hz, subdivided into three distinct bands. As an experimental control, we also included strictly rhythmic stimulation (10 vs 12 Hz). Using a spectral measure of brain-stimulus coupling, we were able to track the neural processing of left vs. right stimuli independently, even while fluctuating within the same frequency range. The fidelity of neural tracking depended on the stimulation frequencies, decreasing for higher frequency bands. Both attended and non-attended stimuli were tracked beyond early visual cortices, in ventral and dorsal streams depending on the stimulus frequency. In general, tracking improved with the deployment of visuo-spatial attention to the stimulus location. Our results provide new insights into how human visual cortices process concurrent dynamic stimuli and provide a potential mechanism – namely increasing the temporal precision of tracking – for boosting the neural representation of attended input.
AB - Successfully interpreting and navigating our natural visual environment requires us to track its dynamics constantly. Additionally, we focus our attention on behaviorally relevant stimuli to enhance their neural processing. Little is known, however, about how sustained attention affects the ongoing tracking of stimuli with rich natural temporal dynamics. Here, we used MRI-informed source reconstructions of magnetoencephalography (MEG) data to map to what extent various cortical areas track concurrent continuous quasi-rhythmic visual stimulation. Further, we tested how top-down visuo-spatial attention influences this tracking process. Our bilaterally presented quasi-rhythmic stimuli covered a dynamic range of 4–20 Hz, subdivided into three distinct bands. As an experimental control, we also included strictly rhythmic stimulation (10 vs 12 Hz). Using a spectral measure of brain-stimulus coupling, we were able to track the neural processing of left vs. right stimuli independently, even while fluctuating within the same frequency range. The fidelity of neural tracking depended on the stimulation frequencies, decreasing for higher frequency bands. Both attended and non-attended stimuli were tracked beyond early visual cortices, in ventral and dorsal streams depending on the stimulus frequency. In general, tracking improved with the deployment of visuo-spatial attention to the stimulus location. Our results provide new insights into how human visual cortices process concurrent dynamic stimuli and provide a potential mechanism – namely increasing the temporal precision of tracking – for boosting the neural representation of attended input.
KW - Cortical tracking
KW - Magnetoencephalography (MEG)
KW - Quasi-rhythmic
KW - Source localization
KW - Spatial attention
KW - Temporal dynamics
UR - http://www.scopus.com/inward/record.url?scp=85076678417&partnerID=8YFLogxK
U2 - 10.1016/j.neuroimage.2019.116444
DO - 10.1016/j.neuroimage.2019.116444
M3 - Article
C2 - 31816422
AN - SCOPUS:85076678417
SN - 1053-8119
VL - 208
JO - NeuroImage
JF - NeuroImage
M1 - 116444
ER -