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奖赏重新校准了人类杏仁核和海马体颅内记录中的规则表示。

Reward recalibrates rule representations in human amygdala and hippocampus intracranial recordings.

机构信息

Department of Neurosurgery, RuiJin Hospital, Shanghai Jiao Tong University School of Medicine, Shanghai, China.

Department of Psychiatry, Addenbrookes Hospital, University of Cambridge, Cambridge, CB2 0QQ, United Kingdom.

出版信息

Nat Commun. 2024 Nov 4;15(1):9518. doi: 10.1038/s41467-024-53521-w.

DOI:10.1038/s41467-024-53521-w
PMID:39496589
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11535001/
Abstract

Adaptive behavior requires the ability to shift responding within (intra-dimensional) or between (extra-dimensional) stimulus dimensions when reward contingencies change. Studies of shifting in humans have focused mainly on the prefrontal cortex and/ or have been restricted to indirect measures of neural activity such as fMRI and lesions. Here, we demonstrate the importance of the amygdala and hippocampus by recording local field potentials directly from these regions intracranially in human epilepsy patients. Reward signals were coded in the high frequency gamma activity (HFG; 60-250 Hz) of both regions and synchronised via low frequency (3-5 Hz) phase-locking only after a shift when patients did not already know the rule and it signalled to stop shifting ("Win-Stay"). In contrast, HFG punishment signals were only seen in the amygdala when the rule then changed and it signalled to start shifting ("Lose-Shift"). During decision-making, hippocampal HFG was more inhibited on non-shift relative to shift trials, suggesting a role in preventing interference in rule representation and amygdala HFG was sensitive to stimulus novelty. The findings expand our understanding of human amygdala-hippocampal function and shifting processes, the disruption of which could contribute to shifting deficits in neuropsychiatric disorders.

摘要

适应行为需要在奖励条件变化时,在(内维度)或(外维度)刺激维度之间转换反应的能力。人类的转换研究主要集中在前额叶皮层,或者仅限于 fMRI 和损伤等间接测量神经活动的方法。在这里,我们通过直接记录人类癫痫患者颅内这些区域的局部场电位,证明了杏仁核和海马体的重要性。奖励信号在这两个区域的高频伽马活动(HFG;60-250Hz)中被编码,并且仅在患者不知道规则且信号停止转换时(“Win-Stay”)通过低频(3-5Hz)相位锁定进行同步。相比之下,当规则发生变化且信号表示开始转换时(“Lose-Shift”),仅在杏仁核中观察到 HFG 惩罚信号。在决策过程中,海马体的 HFG 在非转换相对于转换试验中受到更大的抑制,这表明其在防止规则表示干扰方面具有作用,而杏仁核的 HFG 对刺激新颖性敏感。这些发现扩展了我们对人类杏仁核-海马体功能和转换过程的理解,这些过程的破坏可能导致神经精神障碍中的转换缺陷。

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