# Transfer learning for subject-independent motor imagery EEG classification using convolutional relational networks

**Authors:** Zhenis Otarbay, Abzal Kyzyrkanov

PMC · DOI: 10.3389/fnins.2025.1691929 · Frontiers in Neuroscience · 2026-01-02

## TL;DR

This paper introduces a transfer learning framework using Convolutional Relational Networks to improve subject-independent motor imagery EEG classification for brain-computer interfaces.

## Contribution

The novel contribution is a transfer learning framework (ConvoReleNet) that enhances subject-independent MI-EEG classification by minimizing inter-subject variability and catastrophic forgetting.

## Key findings

- The framework improved classification accuracy on BNCI IV-2a from 72.22% to 79.44% and on BNCI IV-2b from 75.10% to 83.85%.
- Best-case performance reached 87.55% on BNCI IV-2a and 83.85% on BNCI IV-2b with reduced inter-subject variance by up to 45.9%.

## Abstract

Motor imagery (MI) based electroencephalography (EEG) classification is central to brain-computer interface (BCI) research but practical deployment remains challenging due to poor generalization across subjects. Inter-individual variability in neural activity patterns significantly limits the development of subject-independent BCIs for healthcare and assistive technologies. To address this limitation, we present a transfer learning framework based on Convolutional Relational Networks (ConvoReleNet) designed to extract subject-invariant neural representations while minimizing the risk of catastrophic forgetting. The method integrates convolutional feature extraction, relational modeling, and lightweight recurrent processing, combined with pretraining on a diverse subject pool followed by conservative fine-tuning. Validation was conducted on two widely used benchmarks, BNCI IV-2a (four-class motor imagery) and BNCI IV-2b (binary motor imagery), to evaluate subject-independent classification performance. Results demonstrate clear improvements over training from scratch: accuracy on BNCI IV-2a increased from 72.22 (±20.49) to 79.44% (±11.09), while BNCI IV-2b improved from 75.10 (±17.17) to 83.85% (±10.30). The best-case performance reached 87.55% on BNCI IV-2a with Tanh activation and 83.85% on BNCI IV-2b with ELU activation, accompanied by reductions in inter-subject variance of 45.9 and 40.0%, respectively. These findings establish transfer learning as an effective strategy for subject-independent MI-EEG classification. By enhancing accuracy, reducing variability, and maintaining computational efficiency, the proposed framework strengthens the feasibility of robust and user-friendly BCIs for rehabilitation, clinical use, and assistive applications.

## Full-text entities

- **Diseases:** BNCI 4-2a (MESH:C536042), degenerative diseases (MESH:D019636), ALS (MESH:D000690), BNCI 4-2b (MESH:C536043), neurological disorders (MESH:D009461), spinal cord injury (MESH:D013119), MI (MESH:D000068079), stroke (MESH:D020521)
- **Chemicals:** BNCI 4-2b (-)
- **Species:** Homo sapiens (human, species) [taxon 9606]

## Full text

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## Figures

13 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12808372/full.md

## References

62 references — full list in the complete paper: https://tomesphere.com/paper/PMC12808372/full.md

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Source: https://tomesphere.com/paper/PMC12808372