疼痛的层次模型：推理、信息寻求与适应性控制。

Hierarchical models of pain: Inference, information-seeking, and adaptive control.

作者信息

Seymour Ben, Mancini Flavia

机构信息

Computational and Biological Learning Lab, Department of Engineering, University of Cambridge, United Kingdom; Center for Information and Neural Networks, National Institute of Information and Communications Technology, Osaka, Japan.

Computational and Biological Learning Lab, Department of Engineering, University of Cambridge, United Kingdom.

出版信息

Neuroimage. 2020 Nov 15;222:117212. doi: 10.1016/j.neuroimage.2020.117212. Epub 2020 Jul 30.

DOI:10.1016/j.neuroimage.2020.117212

PMID:32739554

Abstract

Computational models of pain consider how the brain processes nociceptive information and allow mapping neural circuits and networks to cognition and behaviour. To date, they have generally have assumed two largely independent processes: perceptual inference, typically modelled as an approximate Bayesian process, and action control, typically modelled as a reinforcement learning process. However, inference and control are intertwined in complex ways, challenging the clarity of this distinction. Here, we consider how they may comprise a parallel hierarchical architecture that combines inference, information-seeking, and adaptive value-based control. This sheds light on the complex neural architecture of the pain system, and takes us closer to understanding from where pain 'arises' in the brain.

摘要

疼痛的计算模型考虑大脑如何处理伤害性信息，并允许将神经回路和网络映射到认知和行为。迄今为止，它们通常假定两个基本独立的过程：感知推理，通常建模为近似贝叶斯过程；行动控制，通常建模为强化学习过程。然而，推理和控制以复杂的方式相互交织，这一区分的清晰性受到挑战。在此，我们考虑它们如何可能构成一个并行分层架构，该架构结合了推理、信息寻求和基于自适应价值的控制。这为疼痛系统复杂的神经架构提供了线索，并使我们更接近于理解疼痛在大脑中“产生”的位置。

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疼痛的层次模型：推理、信息寻求与适应性控制。

Hierarchical models of pain: Inference, information-seeking, and adaptive control.

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