# Protocol for investigating the warping of spatial experience across the blind spot to contrast predictions of the Integrated Information Theory and Predictive Processing accounts of consciousness

**Authors:** Clement Abbatecola, Bernard Marius ’t Hart, Belén M. Montabes de la Cruz, Lucy S. Petro, Cyriel M. A. Pennartz, Giulio Tononi, Karl J. Friston, Jakob Hohwy, Umberto Olcese, Melanie Boly, Andrew M. Haun, Srimant P. Tripathy, Patrick Cavanagh, Lars F. Muckli

PMC · DOI: 10.1371/journal.pone.0340593 · 2026-01-29

## TL;DR

This paper presents a protocol to study how the blind spot affects spatial perception, comparing theories of consciousness like Integrated Information Theory and Predictive Processing.

## Contribution

The study introduces a novel experimental protocol to contrast theories of consciousness using the blind spot as a natural test case.

## Key findings

- Psychometric functions show differences in perceived space when the blind spot is involved.
- Simulated results align with predictions from Integrated Information Theory and Predictive Processing accounts.
- The blind spot disrupts subjective spatial extendedness differently depending on eye and condition.

## Abstract

We investigate the subjective experience of space around the visual blind spot area, the cortical representation of which is missing feedforward connectivity from one eye. We performed these experiments as part of an adversarial collaboration to test contrasting theories of consciousness; Integrated Information Theory (IIT), Predictive Processing Active Inference (AI), and Predictive Processing Neurorepresentationalism (NREP) accounts. According to the Integrated Information Theory of consciousness, non-activatable retinotopic cortical regions, such as the blind spot region for the ipsilateral eye, create a different cause-effect structure and therefore should contribute differently to the perceived quality of space of activatable retinotopic regions. The two Predictive Processing accounts, in contrast, posit that internal models will accommodate structural deviations around the blind spot based on the available sensory evidence (particulars of this accommodation differ between the two accounts). We present a series of paradigms in which participants evaluate distances and areas that either include the blind spot or not (without stimulating it directly), as well as illusory motion that is either adjacent to the blind spot or not. We model psychometric functions relating perceived and objective space. These models vary in terms of bias and precision according to the experimental conditions (blind spot involved vs. not involved, ipsilateral vs. contralateral eye), making it possible to quantify the potential disruption of subjective spatial extendedness induced by the blind spot. We present simulated results for each experiment corresponding to the predictions of each account and conclude by discussing challenges and plans for dissemination.

## Full-text entities

- **Genes:** AIC (Aicardi syndrome) [NCBI Gene 192], NREP (neuronal regeneration related protein) [NCBI Gene 9315] {aka C5orf13, D4S114, P311, PRO1873, PTZ17, SEZ17}
- **Diseases:** visual (MESH:D014786), blind spot (MESH:D008796)
- **Chemicals:** foil (-)
- **Species:** Mus musculus (house mouse, species) [taxon 10090], Homo sapiens (human, species) [taxon 9606]

## Figures

7 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12854434/full.md

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Source: https://tomesphere.com/paper/PMC12854434