Neuronal firing patterns outweigh circuitry oscillations in parkinsonian motor control
Ming-Kai Pan, … , Wen-Sung Lai, Chung-Chin Kuo
Ming-Kai Pan, … , Wen-Sung Lai, Chung-Chin Kuo
Published October 31, 2016
Citation Information: J Clin Invest. 2016;126(12):4516-4526. https://doi.org/10.1172/JCI88170.
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Research Article Neuroscience

Neuronal firing patterns outweigh circuitry oscillations in parkinsonian motor control

Abstract

Neuronal oscillations at beta frequencies (20–50 Hz) in the cortico-basal ganglia circuits have long been the leading theory for bradykinesia, the slow movements that are cardinal symptoms in Parkinson’s disease (PD). The beta oscillation theory helped to drive a frequency-based design in the development of deep brain stimulation therapy for PD. However, in contrast to this theory, here we have found that bradykinesia can be completely dissociated from beta oscillations in rodent models. Instead, we observed that bradykinesia is causatively regulated by the burst-firing pattern of the subthalamic nucleus (STN) in a feed-forward, or efferent-only, mechanism. Furthermore, STN burst-firing and beta oscillations are two independent mechanisms that are regulated by different NMDA receptors in STN. Our results shift the understanding of bradykinesia pathophysiology from an interactive oscillatory theory toward a feed-forward mechanism that is coded by firing patterns. This distinct mechanism may improve understanding of the fundamental concepts of motor control and enable more selective targeting of bradykinesia-specific mechanisms to improve PD therapy.

Authors

Ming-Kai Pan, Sheng-Han Kuo, Chun-Hwei Tai, Jyun-You Liou, Ju-Chun Pei, Chia-Yuan Chang, Yi-Mei Wang, Wen-Chuan Liu, Tien-Rei Wang, Wen-Sung Lai, Chung-Chin Kuo

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Figure 2

Suppression of burst-generating capacity in STN rescues bradykinesia but not beta oscillations in 6-OHDA–lesioned hemiparkinsonian rats.

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Suppression of burst-generating capacity in STN rescues bradykinesia but...
(A) Subthalamic infusion of NiCl2 (Ni2+), a T-type calcium channel blocker, in 6-OHDA rats. (B) Sample sweeps of single-unit recordings and quantitative burst analysis. Ni2+ suppressed burst firings without changing the intra-burst profiles in 6-OHDA rats (n = 25). (CF) Behavioral assessments. (C) Typical traces showing Ni2+ effects in free-moving activities. Ni2+ ameliorated (D) motion difficulties and (E) asymmetries (n = 9). Note that moving velocity was rescued in both (D) free-moving and (F) forced-moving (n =8) paradigms. (GJ) Oscillatory profiles. (G and H) In situ synchronization. Ni2+ had no effect on STN or cortical powers in beta frequency (20-50 Hz) in both rest and moving conditions. Quantitative analysis in these rats showed no change in beta power (bar plots, n = 11). (I) Long-range cortico-subthalamic oscillations. Dark gray section of the bar above indicates Ni2+ infusion. (J) Quantitative analysis of coherence shows that Ni2+ did not change the pathological state of interlocking power (right panel) or frequency (left panel) in beta ranges. Statistical analyses were performed using a nonparametric Wilcoxon signed-rank test. Data are presented as mean ± SEM; *P < 0.05, **P < 0.01.