Neuromodulation : journal of the International Neuromodulation Society
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Deep Brain Stimulation (DBS) is an established adjunctive surgical intervention to treat poorly controlled motor symptoms in Parkinson's disease (PD). Both surgical targets (the subthalamic nucleus and globus pallidus) have proven equally efficacious in treating motor symptoms but unique differences may exist in effects on nonmotor symptoms. Sleep dysfunction, a common disabling symptom in PD, has only been examined directly in the subthalamic target, demonstrating some beneficial changes in sleep quality. We aimed to explore sleep changes after pallidal stimulation; hypothesizing similar benefits would be seen. ⋯ In this small pilot trial, pallidal DBS failed to demonstrate statistically significant improvements in sleep metrics postimplantation but did reveal improving trends in several PSG measures including sleep efficiency and latency to sleep onset as well as sleep survey scores. A larger, blinded clinical trial is needed to more definitively determine whether pallidal DBS may benefit sleep.
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Deep brain stimulation (DBS), which uses an implantable device to modulate brain activity, is clinically superior to medical therapy for treating advanced Parkinson's disease (PD). We studied the cost-effectiveness of DBS in conjunction with medical therapy compared to best medical therapy (BMT) alone, using the latest clinical and cost data for the U.S. healthcare system. ⋯ DBS is a cost-effective treatment strategy for advanced PD in the U.S. healthcare system across a wide range of assumptions. DBS yields substantial improvements in health-related quality of life at a value profile that compares favorably to other well-accepted therapies.
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Spinal cord stimulation (SCS) is not typically recommended for the treatment of central poststroke pain (CPSP). We examined whether the pharmacological evaluation of CPSP is useful for selecting the candidates for SCS. ⋯ We speculate that the pharmacological evaluation of CPSP patients can be a useful tool for selecting candidates for SCS.
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The ability to safely place viable intracerebral grafts of human-derived therapeutic stem cells in three-dimensional (3D) space was assessed in a porcine model of human stereotactic surgery using the Intracerebral Microinjection Instrument (IMI) compared to a conventional straight cannula. ⋯ In contrast to traditional straight cannulas, the IMI enables the delivery of multiple precise cellular injection volumes in accurate 3D arrays. In this porcine large animal model of human neurosurgery, the IMI reduced surgical time and appeared to reduce neural trauma associated with multiple penetrations that would otherwise be required using a conventional straight delivery cannula.