A multi-network model of Parkinson's disease tremor: exploring the finger-dimmer-switch theory and role of dopamine in thalamic self-inhibition.

Fatemeh Sadeghi, Mariia Popova, Francisco Páscoa Dos Santos, Simone Zittel, Claus C Hilgetag
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Abstract

Background. Tremor is a cardinal symptom of Parkinson's disease (PD) that manifests itself through complex oscillatory activity across multiple neuronal populations. According to the finger-dimmer-switch (FDS) theory, tremor is triggered by transient pathological activity in the basal ganglia-thalamo-cortical (BTC) network (the finger) and transitions into an oscillatory form within the inner circuitry of the thalamus (the switch). The cerebello-thalamo-cortical (CTC) network (the dimmer) is then involved in sustaining and amplifying tremor amplitude. In this study, we aimed to investigate the generation and progression dynamics of PD tremor oscillations by developing a comprehensive and interacting FDS model that transitions sequentially from healthy to PD to tremor and then to tremor-off state.Methods.We constructed a computational model consisting of 700 neurons in 11 regions of BTC, CTC, and thalamic networks. Transition from healthy to PD state was simulated through modulating dopaminergic synaptic connections; and further from PD to tremor and tremor-off by modulating projections between the thalamic reticular nucleus (TRN), anterior ventrolateral nucleus (VLa), and posterior ventrolateral nucleus (VLp).Results.Sustained oscillations in the frequency range of PD tremor emerged in thalamic VLp (5 Hz) and cerebellar dentate nucleus (3 Hz). Increasing self-inhibition in the thalamus through dopaminergic modulation significantly decreased tremor amplitude.Conclusion/Significance.Our results confirm the mechanistic power of the FDS theory in describing the PD tremor phenomenon and emphasize the role of dopaminergic modulation on thalamic self-inhibition. These insights pave the way for novel therapeutic strategies aimed at reducing the tremor by strengthening thalamic self-inhibition, particularly in dopamine-resistant patients.

帕金森病震颤的多网络模型:探索手指调光开关理论和多巴胺在丘脑自我抑制中的作用。
背景:震颤是帕金森病(PD)的主要症状,它通过多个神经元群的复杂振荡活动表现出来。根据 "手指-开关"(FDS)理论,震颤是由基底节-丘脑-皮层(BTC)网络(手指)中的短暂病理活动引发的,并在丘脑内部电路(开关)中转变为振荡形式。然后,小脑-丘脑-皮层(CTC)网络(调光器)参与维持和放大震颤幅度。在这项研究中,我们旨在通过建立一个从健康到帕金森病再到震颤再到震颤-关闭状态依次过渡的全面、相互作用的 FDS 模型,研究帕金森病震颤振荡的产生和发展动态:我们构建了一个由 BTC、CTC 和丘脑网络 11 个区域的 700 个神经元组成的计算模型。通过调节多巴胺能突触连接,模拟从健康状态到震颤状态的转变;通过调节丘脑网状核(TRN)、前腹外侧核(VLa)和后腹外侧核(VLp)之间的投射,模拟从震颤状态到震颤和震颤消失的转变:丘脑 VLp(5 Hz)和小脑齿状核(3 Hz)出现了与震颤麻痹症频率范围一致的持续振荡。通过多巴胺能调节增加丘脑的自我抑制可显著降低震颤幅度:我们的研究结果证实了 FDS 理论在描述帕金森病震颤现象方面的机理,并强调了多巴胺能调节丘脑自我抑制的作用。这些见解为旨在通过加强丘脑自我抑制来减轻震颤的新型治疗策略铺平了道路,尤其是在多巴胺耐药患者中。
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