Digital twin brain: a bridge between biological intelligence and artificial intelligence

IF 2.2 Q3 COMPUTER SCIENCE, CYBERNETICS
Hui Xiong, Congying Chu, Lingzhong Fan, Ming Song, Jiaqi Zhang, Yawei Ma, Ruonan Zheng, Junyang Zhang, Zhengyi Yang, Tianzi Jiang
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Abstract

In recent years, advances in neuroscience and artificial intelligence have paved the way for unprecedented opportunities to understand the complexity of the brain and its emulation using computational systems. Cutting-edge advancements in neuroscience research have revealed the intricate relationship between brain structure and function, and the success of artificial neural networks has highlighted the importance of network architecture. It is now time to bring these together to better understand how intelligence emerges from the multiscale repositories in the brain. In this Perspective, we propose the Digital Twin Brain (DTB)—a transformative platform that bridges the gap between biological and artificial intelligence. It comprises three core elements: the brain structure, which is fundamental to the twinning process, bottom-layer models for generating brain functions, and its wide spectrum of applications. Crucially, brain atlases provide a vital constraint that preserves the brain’s network organization within the DTB. Furthermore, we highlight open questions that invite joint efforts from interdisciplinary fields and emphasize the far-reaching implications of the DTB. The DTB can offer unprecedented insights into the emergence of intelligence and neurological disorders, holds tremendous promise for advancing our understanding of both biological and artificial intelligence, and ultimately can propel the development of artificial general intelligence and facilitate precision mental healthcare.
数字孪生大脑:生物智能和人工智能之间的桥梁
近年来,神经科学和人工智能的进步为理解大脑的复杂性以及使用计算系统进行模拟铺平了前所未有的机会。神经科学研究的前沿进展揭示了大脑结构与功能之间的复杂关系,人工神经网络的成功凸显了网络架构的重要性。现在是时候把这些结合起来,更好地理解智力是如何从大脑的多尺度存储库中产生的。从这个角度来看,我们提出了数字双脑(DTB)——一个弥合生物智能和人工智能之间差距的变革性平台。它包括三个核心要素:大脑结构,这是孪生过程的基础,生成大脑功能的底层模型,以及它的广泛应用。至关重要的是,脑地图集提供了一个重要的约束,在DTB内保留了大脑的网络组织。此外,我们强调了需要跨学科领域共同努力的开放性问题,并强调了DTB的深远影响。DTB可以为智能和神经系统疾病的出现提供前所未有的见解,对推进我们对生物和人工智能的理解有着巨大的希望,最终可以推动人工通用智能的发展,促进精确的精神卫生保健。
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来源期刊
CiteScore
6.80
自引率
4.70%
发文量
26
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