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使用机器人技术、电生理学和 TMS 相结合的方法,恢复问题物质使用者的奖励功能。

Recovery of reward function in problematic substance users using a combination of robotics, electrophysiology, and TMS.

机构信息

Center for Molecular and Behavioral Neuroscience, Rutgers University-Newark, Newark, NJ 07102, United States of America.

Center for Molecular and Behavioral Neuroscience, Rutgers University-Newark, Newark, NJ 07102, United States of America.

出版信息

Int J Psychophysiol. 2020 Dec;158:288-298. doi: 10.1016/j.ijpsycho.2020.08.008. Epub 2020 Oct 14.

DOI:10.1016/j.ijpsycho.2020.08.008
PMID:33068631
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10353476/
Abstract

BACKGROUND

Theoretical and empirical work suggest that addictive drugs potentiate dopaminergic reinforcement learning signals and disrupt the reward function of its neural targets, including the anterior midcingulate cortex (aMCC) and the basal ganglia. Here, we aim to use prefrontal 10-Hz TMS to enhance aMCC reward activity and reward learning by the basal ganglia in problematic substance users.

METHODS

22 problematic substance users were randomized into an Active and SHAM (coil flipped) TMS group. We recorded the reward positivity-an electrophysiological signal believed to index sensitivity of the aMCC to rewards-while participants engaged in 4 blocks (100 trials per block) of a reward-based choice task. A robotic arm positioned a TMS coil over a prefrontal cortex target, and 50 pulses were delivered at 10-Hz before every 10 trials of blocks 2-4 (1500 pulses, 400 trials). Participants then completed a decision-making task that is diagnostic of striatal dopamine dysfunction.

RESULTS

The present study revealed three main findings. First, both groups failed to elicit a reward positivity during the first two task blocks. Second, applying robot-assisted TMS enhanced the amplitude of the reward positivity in the Active group, but not the SHAM group, across the last two task blocks. Third, the Active group performed relatively better at reward-based learning than the SHAM group.

CONCLUSION

These results demonstrate that 10-Hz TMS is successful in modulating the reward function of the aMCC and basal ganglia in problematic substance users, which may have utility in the treatment of reward-related neural dysfunction commonly associated with substance use disorders.

摘要

背景

理论和实证研究表明,成瘾药物增强多巴胺能强化学习信号,并破坏其神经靶点的奖赏功能,包括前扣带皮层(aMCC)和基底神经节。在这里,我们旨在使用前额叶 10HzTMS 来增强问题物质使用者的 aMCC 奖赏活动和基底神经节的奖赏学习。

方法

22 名问题物质使用者被随机分为主动和 SHAM(线圈翻转)TMS 组。我们记录了奖赏正波——一种被认为反映 aMCC 对奖赏敏感性的电生理信号——而参与者则参与了 4 个基于奖赏的选择任务块(每个块 100 次试验)。机器人手臂将 TMS 线圈定位在前额叶皮层目标上,在第 2-4 块的每 10 次试验之前(50 个脉冲,400 次试验)以 10Hz 传递 50 个脉冲。然后,参与者完成了一项决策任务,该任务可诊断纹状体多巴胺功能障碍。

结果

本研究揭示了三个主要发现。首先,两组在前两个任务块中都没有引起奖赏正波。其次,应用机器人辅助 TMS 增强了主动组在最后两个任务块中奖赏正波的幅度,但 SHAM 组没有。第三,主动组在基于奖赏的学习方面的表现优于 SHAM 组。

结论

这些结果表明,10HzTMS 成功地调节了问题物质使用者的 aMCC 和基底神经节的奖赏功能,这可能对治疗与物质使用障碍相关的奖赏相关神经功能障碍有用。

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