Bilateral deep brain stimulation of the pedunculopontine and subthalamic nuclei in severe Parkinson's disease

Stefani, Alessandro; Lozano, Andrés M.; Peppe, Antonella; Stanzione, Paolo; Galati, Salvatore; Tropepi, Domenicantonio; Pierantozzi, Mariangela; Brusa, Livia; Scarnati, Eugenio; Mazzone, Paolo

doi:10.1093/brain/awl346

Cited by 738 publications

(577 citation statements)

References 43 publications

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“…DBS in the pedunculopontine nucleus (PPN), for example, is most effective at stimulation frequencies between 20 Hz and 60 Hz. 80 PPN neurons exhibit lower baseline firing rates (ϳ15 Hz on average) than those observed in other nuclei. 81,82 In dystonic cases, in which pathological GPi firing rates are thought to be lower than in PD, therapeutic DBS frequencies may also be lower.…”

Section: Regularization Of Pathological Activitymentioning

confidence: 72%

“…1) (see also other reviews of DBS elsewhere in this issue [128][129][130][131] ). The primary targets of DBS for PD include the sensorimotor STN and GPi, 132 and recent studies suggest that the PPN, 80 GPe, 47 and motor cortex 133 are also effective targets. For most dystonias, the posteroventral GPi is now the preferred site of stimulation.…”

Section: Why So Many Targets?mentioning

confidence: 99%

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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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Section: Regularization Of Pathological Activitymentioning

confidence: 72%

Section: Why So Many Targets?mentioning

confidence: 99%

Mechanisms and Targets of Deep Brain Stimulation in Movement Disorders

et al. 2008

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“…Vim receives strong inputs from the cerebellum, and the effectiveness of tremor control with DBS at this location is a strong argument in favor of cerebellar involvement in the pathophysiology of tremor. PPN DBS [226][227][228][229][230][231][232][233][234][235][236][237][238][239], alone or in combination with STN or GPi DBS, is currently under study for patients with advanced PD who develop levodopaunresponsive freezing of gait, balance impairments, and falls. DBS of the PPN has been shown to be most effective at low stimulation frequencies [240].…”

Section: Use Of Dbs In Pdmentioning

confidence: 99%

Deep Brain Stimulation for Movement Disorders of Basal Ganglia Origin: Restoring Function or Functionality?

2016

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Deep brain stimulation (DBS) is highly effective for both hypo-and hyperkinetic movement disorders of basal ganglia origin. The clinical use of DBS is, in part, empiric, based on the experience with prior surgical ablative therapies for these disorders, and, in part, driven by scientific discoveries made decades ago. In this review, we consider anatomical and functional concepts of the basal ganglia relevant to our understanding of DBS mechanisms, as well as our current understanding of the pathophysiology of two of the most commonly DBS-treated conditions, Parkinson's disease and dystonia. Finally, we discuss the proposed mechanism(s) of action of DBS in restoring function in patients with movement disorders. The signs and symptoms of the various disorders appear to result from signature disordered activity in the basal ganglia output, which disrupts the activity in thalamocortical and brainstem networks. The available evidence suggests that the effects of DBS are strongly dependent on targeting sensorimotor portions of specific nodes of the basal gangliathalamocortical motor circuit, that is, the subthalamic nucleus and the internal segment of the globus pallidus. There is little evidence to suggest that DBS in patients with movement disorders restores normal basal ganglia functions (e.g., their role in movement or reinforcement learning). Instead, it appears that high-frequency DBS replaces the abnormal basal ganglia output with a more tolerable pattern, which helps to restore the functionality of downstream networks.

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“…Early findings suggest that DBS at 25 Hz in the pedunculopontine nucleus (PPN) improves gait in PD. 78 Case reports evaluating bilateral GPi DBS for HD yielded conflicting results during DBS at 40 Hz; chorea was improved in one subject, 79 but it was poorly controlled in another. 80 Finally, studies examining the effects of the frequency of GPi DBS for subjects with dystonia yielded heterogeneous results.…”

Section: Dbs Mechanisms In Diseases and Targets Where Lowfrequency Dbmentioning

confidence: 99%

Mechanisms of Deep Brain Stimulation in Movement Disorders as Revealed by Changes in Stimulus Frequency

2008

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Summary: Deep brain stimulation (DBS) is an established treatment for symptoms in movement disorders and is under investigation for symptom management in persons with psychiatric disorders and epilepsy. Nevertheless, there remains disagreement regarding the physiological mechanisms responsible for the actions of DBS, and this lack of understanding impedes both the design of DBS systems for treating novel diseases and the effective tuning of current DBS systems. Currently available data indicate that effective DBS overrides pathological bursts, low frequency oscillations, synchronization, and disrupted firing patterns present in movement disorders, and replaces them with more regularized firing. Although it is likely that the specific mechanism(s) by which DBS exerts its effects varies between diseases and target nuclei, the overriding of pathological activity appears to be ubiquitous. This review provides an overview of changes in motor symptoms with changes in DBS frequency and highlights parallels between the changes in motor symptoms and the changes in cellular activity that appear to underlie the motor symptoms.

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Bilateral deep brain stimulation of the pedunculopontine and subthalamic nuclei in severe Parkinson's disease

Cited by 738 publications

References 43 publications

Mechanisms and Targets of Deep Brain Stimulation in Movement Disorders

Mechanisms and Targets of Deep Brain Stimulation in Movement Disorders

Deep Brain Stimulation for Movement Disorders of Basal Ganglia Origin: Restoring Function or Functionality?

Mechanisms of Deep Brain Stimulation in Movement Disorders as Revealed by Changes in Stimulus Frequency

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