Movement disorders : official journal of the Movement Disorder Society
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Deep brain stimulation for the alleviation of movement disorders and pain is now an established therapy. However, very little has been published on the topic of hardware failure in the treatment of such conditions irrespective of clinical outcome. Such device-related problems lead to significant patient morbidity and increased cost of therapy in the form of prolonged antibiotics, in-patient hospitalization, repeat surgery, and device replacement. ⋯ Overall there is a 20% rate of hardware-related problems in this series, which falls between the 7% and 65% rates reported by other groups. The majority of these failures occurred early on in the series, and numbers declined with experience. Some of the problems may be idiosyncratic to the methodology of individual groups.
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The postoperative neurologic management of patients with deep brain stimulation (DBS) of the subthalamic nucleus (STN) for Parkinson' s disease is a complex dynamic process that involves a progressive increase in stimulation intensity and a parallel decrease in antiparkinsonian medication while assessing the interactions of both treatments. Neurologists responsible for postoperative management of patients receiving STN DBS must have expert knowledge of the electroanatomy of the subthalamic area and be familiar with the medical treatment of motor and nonmotor symptoms, including the management of long-term complications of levodopa treatment. Neurosurgeons who perform DBS need to understand the principles that guide the postoperative adaptation of treatment. This article defines guidelines for setting stimulation parameters, adapting drugs and managing adverse effects.
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Deep brain stimulation (DBS) is a neurosurgical treatment of Parkinson's disease that is applied to three targets: the ventral intermediate nucleus of the thalamus (Vim), the globus pallidus internas (GPi) and the subthalamic nucleus (STN). Vim DBS mainly improves contralateral tremor and, therefore, is being supplanted by DBS of the two other targets, even in patients with tremor dominant disease. STN and GPi DBS improve off-motor phases and dyskinesias. ⋯ Adverse effects more specific of the DBS procedure are infection, cutaneous erosion, and lead breaking or disconnection. Intracranial electrode implantation can induce a hematoma or contusion. Most authors agree that the benefit to risk ratio of DBS is favorable.
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Bilateral subthalamic nucleus stimulation (STN-DBS) is used to improve parkinsonian symptoms and attenuate levodopa-induced motor complications. In some patients, such clinical improvement allows antiparkinsonian medication (ApMed) withdrawal. We show the clinical outcome at the long-term follow-up of patients with advanced Parkinson's disease (PD) in which STN-DBS was used in monotherapy, and compare the clinical results of patients without medication with those obtained in parkinsonian patients in which ApMed were reduced but could not be totally displaced after surgery. ⋯ No significant differences were seen in most of clinical outcome measures when comparing patients still taking ApMed with patients in STN-DBS monotherapy but a few patients still taking ApMed presented mild dyskinesias and motor fluctuations and patients with STN-DBS monotherapy did not. STN-DBS is useful in the treatment of advanced PD and in some patients it is possible to maintain this therapy alone in the long term. The therapeutic effect of STN-DBS on motor signs can be equipotent to that of levodopa with the additional benefit of avoiding motor fluctuations and dyskinesias.
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Microelectrode recordings of single unit neuronal activity were used during stereotactic surgery to define the subthalamic nucleus for chronic deep brain stimulation in the treatment of Parkinson's disease. By using five parallel trajectories, often two to three microelectrodes allow us to recognize subthalamic nucleus (STN) neuronal activity. STN neurons were easily distinguished from cells of the overlying zona incerta and the underlying substantia nigra. ⋯ The pattern of single cell activity in the SNr is a more regular tonic activity that can easily be distinguished from the bursting pattern in the STN. The most useful criteria to select a trajectory are (1) the length of an individual trajectory displaying typical STN activity, (2) the bursting pattern of activity, and (3) motor responses typical of the sensorimotor part of the nucleus. In conclusion, microelectrode recording of the subthalamic area improves the accuracy of targeting the STN.