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NeurIPS: Neuro-anatomical Inductive Priors for Sphere-based Brain Decoding

Artificial Intelligence 2026-05-26 v1 Computer Vision and Pattern Recognition

Abstract

Current fMRI decoders face a performance-fidelity trade-off where efficient ID encoders outperform geometrically faithful surface-based models. We argue this is partly driven by inefficient surface tokenization and the failure to use anatomy as a predictive signal. We present NeurIPS, a framework that improves surface-based decoding by reframing anatomical variation from a nuisance to a powerful inductive prior. NeurIPS unites two innovations: a Selective ROI Spherical Tokenizer (SRST) for efficient geometric encoding, and a Structure-Guided Mixture of Experts (SG-MoE) that explicitly models individual anatomy using cortical features. On the Natural Scenes Dataset, NeurIPS establishes a new state-of-the-art for surface decoders and achieves performance comparable to strong 1D baselines. This is achieved with unprecedented efficiency, as the model converges dramatically faster (10 vs. 600 epochs). This efficiency enables rapid adaptation to new subjects using only 20% of data and ensures robust scalability as the training cohort is expanded. Ablations provide causal evidence that these gains are driven by the model's use of cortical features, not by memorizing subject IDs. By leveraging anatomical priors, NeurIPS provides a principled and scalable path toward robust, generalizable brain decoding.

Keywords

Cite

@article{arxiv.2605.24993,
  title  = {NeurIPS: Neuro-anatomical Inductive Priors for Sphere-based Brain Decoding},
  author = {Sijin Yu and Zijiao Chen and Zhenyu Yang and Zihao Tan and Jiakun Xu and Zhongliang Liu and Shengxian Chen and Wenxuan Wu and Xiangmin Xu and Xin Zhang},
  journal= {arXiv preprint arXiv:2605.24993},
  year   = {2026}
}

Comments

International Conference on Machine Learning (ICML) 2026