小脑和基底节的时间信息处理

4区 医学 Q2 Biochemistry, Genetics and Molecular Biology Advances in experimental medicine and biology Pub Date : 2024-01-01 DOI:10.1007/978-3-031-60183-5_6
Masaki Tanaka, Masashi Kameda, Ken-Ichi Okada
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引用次数: 0

摘要

从几百毫秒到几秒钟的时间信息处理涉及小脑和基底神经节。在本章中,我们将介绍对非人灵长类动物的最新研究。在本章前半部分介绍的研究中,我们训练猴子在视觉线索出现后经过一定时间时做出眼球运动(时间产生任务)。动物必须根据固定点的颜色报告从几百毫秒到几秒钟不等的时间间隔。在这项任务中,囊回潜伏期随测量的时间长度而变化,并在不同试验之间呈现随机变化。在相同条件下,每次试验之间的变化与瞳孔直径以及小脑深核和运动丘脑的准备活动密切相关。当被要求报告亚秒级的时间间隔时,这些脑区的失活会延迟囊回视。这些结果表明,随每次试验而变化的内部状态可能会导致小脑神经元活动的波动,从而产生自我计时的变化。在测量不同的时间间隔时,无论测量的时间间隔长短如何,小脑的准备活动总是在运动前大约 500 毫秒开始。然而,纹状体中的准备活动会持续整个强制性延迟期,最长可达 2 秒,而且活动增加的速度各不相同。此外,在纹状体中,紧接着时间测量前的视觉反应和低频振荡活动会因预期时间间隔的长短而改变。这些结果表明,包括纹状体在内的网络状态会随着预定时间的改变而改变,从而导致准备活动的时间进程不同。因此,基底神经节似乎负责测量几百毫秒到几秒范围内的时间,而小脑则负责调节亚秒范围内的自我计时可变性。本章后半部分介绍与周期性计时有关的研究。在眼球运动与定期交替的目标同步时,小脑核中的不同神经元会表现出与运动定时、预测刺激定时和同步的时间误差有关的活动。其中,与目标出现相关的活动在同步运动时尤其增强,可能代表了刺激序列时间结构的内部模型。我们还考虑了在没有运动的情况下感知周期性定时的神经机制。在感知节奏的过程中,我们会预测下一个刺激的时间,并将注意力集中在那个时刻。在缺失奇异球范式中,受试者必须检测到有规律重复刺激的遗漏。结果显示,人类预测每次刺激时机的最快时间限制约为 0.25 秒(4 赫兹)。在执行这项任务的猴子身上,小脑核、纹状体和运动丘脑中的神经元表现出周期性活动,不同的脑区有不同的时间进程。由于电刺激或记录部位失活会改变对刺激遗漏的反应时间,因此这些神经元活动一定参与了周期性时间处理。节律感知似乎由皮质-小脑和皮质-基底节通路共同处理,今后的研究需要阐明节律感知的机制。
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Temporal Information Processing in the Cerebellum and Basal Ganglia.

Temporal information processing in the range of a few hundred milliseconds to seconds involves the cerebellum and basal ganglia. In this chapter, we present recent studies on nonhuman primates. In the studies presented in the first half of the chapter, monkeys were trained to make eye movements when a certain amount of time had elapsed since the onset of the visual cue (time production task). The animals had to report time lapses ranging from several hundred milliseconds to a few seconds based on the color of the fixation point. In this task, the saccade latency varied with the time length to be measured and showed stochastic variability from one trial to the other. Trial-to-trial variability under the same conditions correlated well with pupil diameter and the preparatory activity in the deep cerebellar nuclei and the motor thalamus. Inactivation of these brain regions delayed saccades when asked to report subsecond intervals. These results suggest that the internal state, which changes with each trial, may cause fluctuations in cerebellar neuronal activity, thereby producing variations in self-timing. When measuring different time intervals, the preparatory activity in the cerebellum always begins approximately 500 ms before movements, regardless of the length of the time interval being measured. However, the preparatory activity in the striatum persists throughout the mandatory delay period, which can be up to 2 s, with different rate of increasing activity. Furthermore, in the striatum, the visual response and low-frequency oscillatory activity immediately before time measurement were altered by the length of the intended time interval. These results indicate that the state of the network, including the striatum, changes with the intended timing, which lead to different time courses of preparatory activity. Thus, the basal ganglia appear to be responsible for measuring time in the range of several hundred milliseconds to seconds, whereas the cerebellum is responsible for regulating self-timing variability in the subsecond range. The second half of this chapter presents studies related to periodic timing. During eye movements synchronized with alternating targets at regular intervals, different neurons in the cerebellar nuclei exhibit activity related to movement timing, predicted stimulus timing, and the temporal error of synchronization. Among these, the activity associated with target appearance is particularly enhanced during synchronized movements and may represent an internal model of the temporal structure of stimulus sequence. We also considered neural mechanism underlying the perception of periodic timing in the absence of movement. During perception of rhythm, we predict the timing of the next stimulus and focus our attention on that moment. In the missing oddball paradigm, the subjects had to detect the omission of a regularly repeated stimulus. When employed in humans, the results show that the fastest temporal limit for predicting each stimulus timing is about 0.25 s (4 Hz). In monkeys performing this task, neurons in the cerebellar nuclei, striatum, and motor thalamus exhibit periodic activity, with different time courses depending on the brain region. Since electrical stimulation or inactivation of recording sites changes the reaction time to stimulus omission, these neuronal activities must be involved in periodic temporal processing. Future research is needed to elucidate the mechanism of rhythm perception, which appears to be processed by both cortico-cerebellar and cortico-basal ganglia pathways.

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来源期刊
Advances in experimental medicine and biology
Advances in experimental medicine and biology 医学-医学:研究与实验
CiteScore
5.90
自引率
0.00%
发文量
465
审稿时长
2-4 weeks
期刊介绍: Advances in Experimental Medicine and Biology provides a platform for scientific contributions in the main disciplines of the biomedicine and the life sciences. This series publishes thematic volumes on contemporary research in the areas of microbiology, immunology, neurosciences, biochemistry, biomedical engineering, genetics, physiology, and cancer research. Covering emerging topics and techniques in basic and clinical science, it brings together clinicians and researchers from various fields.
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