Inter-individual and inter-site neural code conversion and image reconstruction without shared stimuli

The human brain demonstrates substantial inter-individual variability in fine-grained functional topography, posing challenges in identifying common neural representations across individuals. Functional alignment has the potential to harmonize these individual differences. However, it typically requires an identical set of stimuli presented to different individuals, which is often unavailable. To address this, we propose a content loss-based neural code converter, designed to convert brain activity from one subject to another representing the same content. The converter is optimized so that the source subject's converted brain activity is decoded into a latent image representation that closely resembles that of the stimulus given to the source subject. We show that converters optimized using hierarchical image representations achieve conversion accuracy comparable to those optimized by paired brain activity as in conventional methods. The brain activity converted from a different individual and even from a different site sharing no stimuli produced reconstructions that approached the quality of within-individual reconstructions. The converted brain activity had a generalizable representation that can be read out by different decoding schemes. The converter required much fewer training samples than that typically required for decoder training to produce recognizable reconstructions. These results demonstrate that our method can effectively combine image representations to convert brain activity across individuals without the need for shared stimuli, providing a promising tool for flexibly aligning data from complex cognitive tasks and a basis for brain-to-brain communication.