Universal scale-free representations in human visual cortex

TL;DR

This study reveals that human visual cortex encodes visual information in a universal, scale-free, high-dimensional manner, with neural representations following a power-law variance decay across individuals and brain regions.

Contribution

It uncovers a universal, scale-free organization of visual representations in the human cortex, emphasizing the importance of high-dimensional analysis for understanding neural coding.

Findings

Neural representations follow a power-law decay across four orders of magnitude.

The scale-free structure is consistent across different visual regions and individuals.

Shared high-dimensional visual representations emerge despite individual differences.

Abstract

How does the human brain encode complex visual information? While previous research has characterized individual dimensions of visual representation in cortex, we still lack a comprehensive understanding of how visual information is organized across the full range of neural population activity. Here, analyzing fMRI responses to natural scenes across multiple individuals, we discover that neural representations in human visual cortex follow a remarkably consistent scale-free organization -- their variance systematically decays as a power law, detected across four orders of magnitude of latent dimensions. This scale-free structure appears consistently across multiple visual regions and across individuals, suggesting it reflects a fundamental organizing principle of visual processing. Critically, when we align neural responses across individuals using hyperalignment, we find that these representational dimensions are largely shared between people, revealing a universal high-dimensional spectrum of visual information that emerges despite individual differences in brain anatomy and visual experience. Traditional analysis approaches in cognitive neuroscience have focused primarily on a small number of high-variance dimensions, potentially missing crucial aspects of visual representation. Our results demonstrate that visual information is distributed across the full dimensionality of cortical activity in a systematic way, suggesting we need to move beyond low-dimensional characterizations to fully understand how the brain represents the visual world. This work reveals a new fundamental principle of neural coding in human visual cortex and highlights the importance of examining neural representations across their full dimensionality.