Digital twin brain simulator for real-time consciousness monitoring and virtual intervention using primate electrocorticogram data

IF 12.4 1区医学 Q1 HEALTH CARE SCIENCES & SERVICES

NPJ Digital Medicine Pub Date : 2025-02-10 DOI:10.1038/s41746-025-01444-1

Yuta Takahashi, Hayato Idei, Misako Komatsu, Jun Tani, Hiroaki Tomita, Yuichi Yamashita

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Abstract

At the forefront of bridging computational brain modeling with personalized medicine, this study introduces a novel, real-time, electrocorticogram (ECoG) simulator, based on the digital twin brain concept. Utilizing advanced data assimilation techniques, specifically a Variational Bayesian Recurrent Neural Network model with hierarchical latent units, the simulator dynamically predicts ECoG signals reflecting real-time brain latent states. By assimilating broad ECoG signals from macaque monkeys across awake and anesthetized conditions, the model successfully updated its latent states in real-time, enhancing precision of ECoG signal simulations. Behind successful data assimilation, self-organization of latent states in the model was observed, reflecting brain states and individuality. This self-organization facilitated simulation of virtual drug administration and uncovered functional networks underlying changes in brain function during anesthesia. These results show that the proposed model can simulate brain signals in real-time with high accuracy and is also useful for revealing underlying information processing dynamics.

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在连接计算大脑建模与个性化医疗的最前沿，本研究基于数字孪生大脑概念，介绍了一种新颖、实时的心电图（ECoG）模拟器。该模拟器利用先进的数据同化技术，特别是具有分层潜伏单元的变异贝叶斯递归神经网络模型，动态预测反映实时大脑潜伏状态的心电图信号。通过同化猕猴在清醒和麻醉状态下的广泛心电信号，该模型成功地实时更新了潜在状态，提高了心电信号模拟的精确度。在成功同化数据的背后，还观察到模型中潜在状态的自组织，反映了大脑状态和个性。这种自组织促进了虚拟给药的模拟，并揭示了麻醉期间大脑功能变化的基础功能网络。这些结果表明，所提出的模型能够高精度地实时模拟大脑信号，并有助于揭示潜在的信息处理动态。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

NPJ Digital Medicine Multiple-

CiteScore

25.10

自引率

3.30%

发文量

170

审稿时长

15 weeks

期刊介绍： npj Digital Medicine is an online open-access journal that focuses on publishing peer-reviewed research in the field of digital medicine. The journal covers various aspects of digital medicine, including the application and implementation of digital and mobile technologies in clinical settings, virtual healthcare, and the use of artificial intelligence and informatics. The primary goal of the journal is to support innovation and the advancement of healthcare through the integration of new digital and mobile technologies. When determining if a manuscript is suitable for publication, the journal considers four important criteria: novelty, clinical relevance, scientific rigor, and digital innovation.