Peter Riederer, Sabrina Strobel, Toshiharu Nagatsu, Hirohisa Watanabe, Xiqun Chen, Peter-Andreas Löschmann, Jeswinder Sian-Hulsmann, Wolfgang H Jost, Thomas Müller, Johannes M Dijkstra, Camelia-Maria Monoranu
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引用次数: 0
Abstract
Treatment with levodopa, a precursor of dopamine (DA), to compensate for the loss of endogenous DA in Parkinson's disease (PD), has been a success story for over 50 years. However, in late stages of PD, the progressive degeneration of dopaminergic neurons and the ongoing reduction in endogenous DA concentrations make it increasingly difficult to maintain normal-like DA function. Typically, in late PD, higher doses of levodopa are required, and the fluctuations in striatal DA concentrations-reflecting the timing pattern of levodopa administrations-become more pronounced. These DA fluctuations can include highs that induce involuntary movements (levodopa-induced dyskinesia, LID) or lows that result in insufficient suppression of PD symptoms ("OFF" phases). The enhanced fluctuations primarily arise from the loss of DA buffering capacity, resulting from the degeneration of DA neurons, and an increased reliance on levodopa-derived DA release as a "false neurotransmitter" by serotonergic neurons. In many patients, the LID and OFF-phases can be alleviated by modifying the levodopa therapy to provide a more continuous delivery or by using additional medications, such as monoamine oxidase-B (MAO-B) inhibitors, amantadine, or dopaminergic receptor agonists. Understanding the challenges faced by levodopa therapy also requires considering that the PD striatum is characterized not only by the loss of DA neurons but also by neuroplastic adaptations and PD-induced degenerations of other neural populations. This review provides a broad overview on the use of levodopa in treating PD, with a focus on the underlying science of the challenges encountered in late stages of the disease.
50多年来,用多巴胺(DA)前体左旋多巴治疗帕金森氏病(PD),以补偿内源性DA的损失,一直是一个成功的故事。然而,在PD的晚期,多巴胺能神经元的进行性变性和内源性DA浓度的持续降低使得维持正常的DA功能变得越来越困难。通常,在帕金森晚期,需要更高剂量的左旋多巴,纹状体DA浓度的波动(反映左旋多巴给药的时间模式)变得更加明显。这些DA波动可能包括导致不自主运动的高位(左旋多巴引起的运动障碍,LID)或导致PD症状抑制不足的低位(“OFF”阶段)。波动增强主要是由于多巴胺神经元退化导致的多巴胺缓冲能力丧失,以及血清素能神经元对左旋多巴衍生的多巴胺释放作为“假神经递质”的依赖增加。在许多患者中,可以通过修改左旋多巴治疗以提供更连续的给药或使用额外的药物,如单胺氧化酶- b (MAO-B)抑制剂、金刚烷胺或多巴胺能受体激动剂来缓解LID期和off期。理解左旋多巴治疗面临的挑战还需要考虑到PD纹状体的特征不仅是DA神经元的丧失,还包括神经可塑性适应和PD诱导的其他神经群的变性。本文综述了左旋多巴在帕金森病治疗中的应用,重点介绍了该疾病晚期遇到的挑战的基础科学。
期刊介绍:
The investigation of basic mechanisms involved in the pathogenesis of neurological and psychiatric disorders has undoubtedly deepened our knowledge of these types of disorders. The impact of basic neurosciences on the understanding of the pathophysiology of the brain will further increase due to important developments such as the emergence of more specific psychoactive compounds and new technologies.
The Journal of Neural Transmission aims to establish an interface between basic sciences and clinical neurology and psychiatry. It intends to put a special emphasis on translational publications of the newest developments in the field from all disciplines of the neural sciences that relate to a better understanding and treatment of neurological and psychiatric disorders.
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