The general structure and information flow of RL-based spike generation. Credit: Nature Computational Science (2026). DOI: 10.1038/s43588-025-00915-5
Researchers at The Hong Kong University of Science and Technology (HKUST) School of Engineering have developed a novel reinforcement learning–based generative model to predict neural signals, creating an artificial information pathway that effectively bypasses damaged brain areas. This research opens …
The general structure and information flow of RL-based spike generation. Credit: Nature Computational Science (2026). DOI: 10.1038/s43588-025-00915-5
Researchers at The Hong Kong University of Science and Technology (HKUST) School of Engineering have developed a novel reinforcement learning–based generative model to predict neural signals, creating an artificial information pathway that effectively bypasses damaged brain areas. This research opens up new possibilities for neural rehabilitation in patients suffering from motor or cognitive impairments caused by conditions such as stroke or spinal cord injury.
Their study, titled "A generative spike prediction model using behavioral reinforcement for re-establishing neural functional connectivity," has been published in Nature Computational Science.
How neural pathways break down
Different regions of the brain encode and transmit information through electrical impulses between neurons, known as "neural spikes." When these neural transmission pathways are disrupted due to neurological diseases and injuries, it can result in severe functional impairments, such as memory disorder or paralysis.
A neural prosthesis creates an artificial information pathway to transmit information from upstream neural signals to downstream brain regions, bypassing damaged sites and restoring lost motor or cognitive functions. The primary challenge lies in determining the effective pattern of downstream neural activity that can restore behavioral function, using upstream activities.
A new reinforcement learning model
To address this, a research team, led by Prof. Wang Yiwen, Associate Professor of the Department of Electronic and Computer Engineering at HKUST, has introduced a reinforcement learning-based transregional neural spike prediction model. Unlike conventional methods, this approach does not rely on spike recordings from downstream brain areas to assess the functional integrity of neural pathways, which are often unavailable in patients with damaged pathways.
Instead, it utilizes behavioral success as a feedback signal to guide model training. The model learns to transform spiking activities from active upstream neurons into real-time predictions for downstream neurons, facilitating biomimetic communication between disconnected brain regions.
"The core idea is to enable the model to learn the transregional mapping through trial-and-error, much like how the brain itself learns," explained Prof. Wang. "This approach allows us to construct an ‘information bypass’ for patients with impaired neural pathways, thereby re-establishing functional connectivity."
The team validated the proposed method by collecting motor control pathways data through behavioral experiments involving rats at HKUST’s Computational Cognitive Engineering Lab. The results showed that the model-generated spike signals can drive desired behaviors through a decoder, achieving significantly higher behavioral success rates than traditional methods. Moreover, the encoding properties of the generated signals closely resemble the biological modulation patterns observed in healthy neural recordings.
Potential impact on future treatments
The method demonstrates excellent adaptability, maintaining high performance across different decoder settings and enabling rapid adaptation to new subjects with minimal calibration. This significantly enhances its potential for future clinical translation.
Prof. Wang added, "This approach not only provides new avenues for motor rehabilitation for patients with functional impairments due to neural damage, but also holds promise for optimal rehabilitation treatment for those with advanced cognitive function injuries. We will further explore the integration of this computational framework with neural modulation technologies and collaborate with clinical institutions to advance its practical application."
Publication details
Shenghui Wu et al, A generative spike prediction model using behavioral reinforcement for re-establishing neural functional connectivity, Nature Computational Science (2026). DOI: 10.1038/s43588-025-00915-5
Journal information: Nature Computational Science
Clinical categories
Citation: Computational models predict neural activity for re-establishing connectivity after stroke or injury (2026, February 3) retrieved 3 February 2026 from https://medicalxpress.com/news/2026-02-neural-injury.html
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