Acute psychotropic effects of bilateral subthalamic nucleus stimulation and levodopa in Parkinson's disease

Funkiewiez, Aurélie; Ardouin, Claire; Krack, Paul; Fraix, Valérie; Blercom, N. Van; Xie, Jing; Moro, Elena; Benabid, Alim‐Louis; Pollak, Pierre

doi:10.1002/mds.10441

Cited by 237 publications

(174 citation statements)

References 65 publications

(73 reference statements)

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“…For example, Baunez and colleagues reported that bilateral STN lesions enhance motivation for food, as measured by progressive ratio performance and conditioned place preference (Baunez et al, 2002(Baunez et al, , 2005. Furthermore, HFS of the STN, which is thought to mimic ablation of the STN by inducing depolarization block (Benazzouz et al, 1993(Benazzouz et al, , 1995(Benazzouz et al, , 2000Lozano et al, 2002) (but see Garcia et al, 2005), enhances motivation and decreases apathy and also increases the therapeutic potency of the dopamine-enhancing drug L-3,4-dihydroxyphenylalanine (L-DOPA) in patients with Parkinson's disease (Limousin et al, 1998;Houeto et al, 2002;Funkiewiez et al, 2003;Ashkan et al, 2004).…”

Section: Discussionmentioning

confidence: 99%

“…However, recently, it has been shown that amphetamine and cocaine induce robust c-fos expression in the STN (Uslaner et al, 2001a), which sensitizes as a result of repeated drug administration (Uslaner et al, 2003b) and that bilateral lesions of the STN increase responding for food rewards (Baunez et al, 2002). Furthermore, high-frequency electrical stimulation (HFS) of the STN, which is used to treat symptoms of Parkinson's disease, also enhances motivation and other limbic system-related processes in these patients (Funkiewiez et al, 2003;Takeshita et al, 2005). These studies suggest, therefore, that in addition to its involvement in motor control, the STN may play a role in motivational processes and the behavioral response to drugs of abuse.…”

Section: Introductionmentioning

confidence: 99%

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Subthalamic Nucleus Lesions Enhance the Psychomotor-Activating, Incentive Motivational, and Neurobiological Effects of Cocaine

Uslaner

Yang

Robinson³

2005

J. Neurosci.

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The subthalamic nucleus (STN) is traditionally thought to be involved in motor control, and dysfunction of the STN is thought to contribute to movement disorders. Here, we show that the STN also plays an important role in motivational processes and the response to drugs of abuse. Specifically, bilateral STN lesions produced a dose-dependent increase in the psychomotor-activating effects of cocaine, the rate at which animals acquired cocaine self-administration, and the motivation for cocaine assessed using a progressive ratio schedule. Furthermore, bilateral STN lesions enhanced the ability of cocaine to induce gene expression in the nucleus accumbens and caudate-putamen, two structures known to be involved in mediating the psychomotor-activating and incentive motivational effects of drugs of abuse. These findings suggest that engagement of the STN serves to dampen the psychomotor-activating and incentive motivational effects of drugs of abuse. Thus, the STN may serve as a novel target for therapeutic interventions aimed at treating drug dependence.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Subthalamic Nucleus Lesions Enhance the Psychomotor-Activating, Incentive Motivational, and Neurobiological Effects of Cocaine

Uslaner

Yang

Robinson³

2005

J. Neurosci.

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“…STN-DBS itself has a positive eff ect on offperiod apathy, contributing to improvement of off -period cognitive and emotional aspects in apathy. 92,[104][105][106] However, with regard to the on-period motivational aspects of the antiparkinsonian drugs, a slowly progressive desensitisation of the psychotropic eff ects of dopaminergic treatment after drug decrease 107 explains why the hypodopaminergic withdrawal syndrome in patients on chronic STN-DBS typically occurs with a substantial delay of several months after surgery 83,92 (unlike the much more acute withdrawal syndrome after cessation of dopamine agonists in patients not receiving chronic STN-DBS). 93 The potential to reverse postoperative apathy after D2 or D3 receptor stimulation with oral dopamine receptor agonists 108,109 clearly suggests a Parkinson's disease-related symptom that has been unmasked by a decrease in drug treatment.…”

Section: Apathy After Deep Brain Stimulation In Parkinson's Diseasementioning

confidence: 99%

Apathy in Parkinson's disease: clinical features, neural substrates, diagnosis, and treatment

Pagonabarraga

Kulisevsky

Strafella

et al. 2015

The Lancet Neurology

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405

391

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Normal maintenance of human motivation depends on the integrity of subcortical structures that link the prefrontal cortex with the limbic system. Structural and functional disruption of diff erent networks within these circuits alters the maintenance of spontaneous mental activity and the capacity of aff ected individuals to associate emotions with complex stimuli. The clinical manifestations of these changes include a continuum of abnormalities in goal-oriented behaviours known as apathy. Apathy is highly prevalent in Parkinson's disease (and across many neurodegenerative disorders) and can severely aff ect the quality of life of both patients and caregivers. Diff erentiation of apathy from depression, and discrimination of its cognitive, emotional, and auto-activation components could guide an individualised approach to the treatment of symptoms. The opportunity to manipulate dopaminergic treatment in Parkinson's disease allows researchers to study a continuous range of motivational states, from apathy to impulse control disorders. Parkinson's disease can thus be viewed as a model that provides insight into the neural substrates of apathy.

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“…Worsening of dyskinesia or dystonia can appear during initial DBS programming sessions, but these symptoms decline after several hours of continuous stimulation. 160 Deep brain stimulation can generate cognitive side effects as well, including mood changes, 161 depression, 162 decreased working memory performance, 163,164 impulsivity, 165 and hallucinations. 166 One explanation for the emergence of such cognitive side effects is that suprathreshold currents spread into nonmotor regions within the basal ganglia and thalamocortical networks.…”

Section: What To Avoid: Targets That Lead To Undesirable Side Effectsmentioning

confidence: 99%

Mechanisms and Targets of Deep Brain Stimulation in Movement Disorders

et al. 2008

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Summary:Chronic electrical stimulation of the brain, known as deep brain stimulation (DBS), has become a preferred surgical treatment for medication-refractory movement disorders. Despite its remarkable clinical success, the therapeutic mechanisms of DBS are still not completely understood, limiting opportunities to improve treatment efficacy and simplify selection of stimulation parameters. This review addresses three questions essential to understanding the mechanisms of DBS. 1) How does DBS affect neuronal tissue in the vicinity of the active electrode or electrodes? 2) How do these changes translate into therapeutic benefit on motor symptoms? 3) How do these effects depend on the particular site of stimulation? Early hypotheses proposed that stimulation inhibited neuronal activity at the site of stimulation, mimicking the outcome of ablative surgeries. Recent studies have challenged that view, suggesting that although somatic activity near the DBS electrode may exhibit substantial inhibition or complex modulation patterns, the output from the stimulated nucleus follows the DBS pulse train by direct axonal excitation. The intrinsic activity is thus replaced by high-frequency activity that is time-locked to the stimulus and more regular in pattern. These changes in firing pattern are thought to prevent transmission of pathologic bursting and oscillatory activity, resulting in the reduction of disease symptoms through compensatory processing of sensorimotor information. Although promising, this theory does not entirely explain why DBS improves motor symptoms at different latencies. Understanding these processes on a physiological level will be critically important if we are to reach the full potential of this powerful tool.

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Acute psychotropic effects of bilateral subthalamic nucleus stimulation and levodopa in Parkinson's disease

Cited by 237 publications

References 65 publications

Subthalamic Nucleus Lesions Enhance the Psychomotor-Activating, Incentive Motivational, and Neurobiological Effects of Cocaine

Subthalamic Nucleus Lesions Enhance the Psychomotor-Activating, Incentive Motivational, and Neurobiological Effects of Cocaine

Apathy in Parkinson's disease: clinical features, neural substrates, diagnosis, and treatment

Mechanisms and Targets of Deep Brain Stimulation in Movement Disorders

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