Layer-dependent multiplicative effects of spatial attention on contrast responses in human early visual cortex

• Published in: Progress in neurobiology Vol. 207; p. 101897
• Main Authors: Liu, Chengwen, Guo, Fanhua, Qian, Chencan, Zhang, Zihao, Sun, Kaibao, Wang, Danny JJ, He, Sheng, Zhang, Peng
• Format: Journal Article
• Language: English
• Published: England Elsevier Ltd 01.12.2021
• Subjects: 7T fMRI; Contrast response function; Feedback; Feedforward; Layer; Spatial attention; 7T fMRI; Feedforward; Feedback; Layer; Spatial attention; Contrast response function
• ISSN: 0301-0082; 1873-5118
• DOI: 10.1016/j.pneurobio.2020.101897

•Response or activity gain of spatial attention in superficial and deep layers•Contrast gain or baseline shift of attention in V1 middle layer•Nonlinearity of large blood vessel causes additive effect of attention on T2*w BOLD Attention mechanisms at different cortical layers of human visual cortex remain poorly understood. Using submillimeter-resolution fMRI at 7 Tesla, we investigated the effects of top-down spatial attention on the contrast responses across different cortical depths in human early visual cortex. Gradient echo (GE) T2* weighted BOLD signal showed an additive effect of attention on contrast responses across cortical depths. Compared to the middle cortical depth, attention modulation was stronger in the superficial and deep depths of V1, and also stronger in the superficial depth of V2 and V3. Using ultra-high resolution (0.3 mm in-plane) balanced steady-state free precession (bSSFP) fMRI, a multiplicative scaling effect of attention was found in the superficial and deep layers, but not in the middle layer of V1. Attention modulation of low contrast response was strongest in the middle cortical depths, indicating baseline enhancement or contrast gain of attention modulation on feedforward input. Finally, the additive vs. scaling effect of attention from GE-EPI and bSSFP signals can be explained by stronger nonlinearity of BOLD signals from large than small blood vessels, suggesting multiplicative effect of attention on neural activity. These findings support that top-down spatial attention mainly operates through feedback connections from higher order cortical areas, and a distinct mechanism of attention may also be associated with feedforward input through subcortical pathway.