[Basal Ganglia Circuit Mechanisms in Cognitive Learning].

Nihon shinkei seishin yakurigaku zasshi = Japanese journal of psychopharmacology Pub Date : 2017-04-01

Takatoshi Hikida, Tom MacPherson, Makiko Morita

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Abstract

The nucleus accumbens (NAc), the ventral part of the striatum, plays a critical role in motivation, learning, and cognition in the basal ganglia circuit. Outputs of the NAc are transmitted through two parallel direct and indirect pathways. We have developed a reversible neurotransmission blocking (RNB) technique, in which neurotransmission of each pathway in the NAc is selectively blocked by specific expression of a transmission-blocking tetanus toxin (D-RNB or I-RNB). In visual cue and reversal tasks in the cross-maze, the NAc direct pathway was critical for learning acquisition. In contrast, the NAc indirect pathway was essential not only for learning flexibility, but also for subsequent acquisition of a new strategy. In place discrimination and serial reversal learning tasks in the IntelliCage, we showed that the NAc indirect pathway controls behavioral flexibility by suppressing the influence of previously correct behavioral strategies during the reversal stage. These basal ganglia circuit mechanisms provide new insight into pathophysiologies associated with compulsive behaviors, including addiction and obesity.

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认知学习中的基底神经节回路机制。

伏隔核(NAc)是纹状体的腹侧部分，在基底神经节回路的动机、学习和认知中起着关键作用。NAc的输出通过两条平行的直接和间接路径传输。我们开发了一种可逆的神经传递阻断(RNB)技术，通过特异性表达一种传递阻断破伤风毒素(D-RNB或I-RNB)，选择性地阻断NAc中每个通路的神经传递。在交叉迷宫的视觉提示和反转任务中，NAc直接通路对学习习得至关重要。相反，NAc间接通路不仅对学习灵活性至关重要，而且对随后的新策略习得也至关重要。在智力智力的位置辨别和连续反转学习任务中，我们发现NAc间接通路通过抑制反转阶段先前正确的行为策略的影响来控制行为灵活性。这些基底神经节回路机制为强迫性行为(包括成瘾和肥胖)相关的病理生理学提供了新的见解。

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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Nihon shinkei seishin yakurigaku zasshi = Japanese journal of psychopharmacology

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