Link to bioRxiv paper: http://biorxiv.org/cgi/content/short/2020.11.09.374397v1?rss=1 Authors: Russo, A. G., Luehrs, M., Di Salle, F., Esposito, F., Goebel, R. W. Abstract: Objective: Real-time functional magnetic resonance imaging neurofeedback (rt-fMRI-NF) is a non-invasive MRI procedure allowing examined participants to learn to self-regulate brain activity by performing mental tasks. A novel two-step rt-fMRI-NF procedure is proposed whereby the feedback display is updated in real-time based on high level (semantic) representations of experimental stimuli via real-time representational similarity analysis of multi-voxel patterns of brain activity. Approach: In a localizer session, the stimuli become associated with anchored points on a two-dimensional representational space where distances approximate between-pattern (dis)similarities. In the NF session, participants modulate their brain response, displayed as a movable point, to engage in a specific neural representation. The developed method pipeline is verified in a proof-of-concept rt-fMRI-NF study at 7 Tesla using imagery of concrete objects. The dependence on noise is more systematically assessed on artificial fMRI data with similar (simulated) spatio-temporal structure and variable (injected) signal and noise. A series of brain activity patterns from the ventral visual cortex is evaluated via on-line and off-line analyses and the performances of the method are reported under different noise conditions. Main results: The participant in the proof-of-concept study exhibited robust activation patterns in the localizer session and managed to control the neural representation of a stimulus towards the selected target, in the NF session. The offline analyses validated the rt-fMRI-NF results, showing that the rapid convergence to the target representation is noise-dependent. Significance: Our proof-of-concept study demonstrates the potential of semantic NF designs where the participant navigates among different mental states. Compared to traditional NF designs (e.g. using a thermometer display to set the level of the neural signal), the proposed approach provides content-specific feedback to the participant and extra degrees of freedom to the experimenter enabling real-time control of the neural activity towards a target brain state without suggesting a specific mental strategy to the subject. Copy rights belong to original authors. Visit the link for more info