Sarah Owen scite author profile

Deep brain stimulation (DBS) has shown remarkable therapeutic benefits for patients with otherwise treatment-resistant movement and affective disorders. This technique is not only clinically useful, but it can also provide new insights into fundamental brain functions through direct manipulation of both local and distributed brain networks in many different species. In particular, DBS can be used in conjunction with non-invasive neuroimaging methods such as magnetoencephalography to map the fundamental mechanisms of normal and abnormal oscillatory synchronization that underlie human brain function. The precise mechanisms of action for DBS remain uncertain, but here we give an up-to-date overview of the principles of DBS, its neural mechanisms and its potential future applications.

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Deep brain stimulation for pain relief: A meta-analysis

Bittar

Kar-Purkayastha

Owen

et al. 2005

Journal of Clinical Neuroscience

341

208

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Utility of multimaterial 3D printers in creating models with pathological entities to enhance the training experience of neurosurgeons

Waran

Narayanan

Karuppiah

et al. 2014

JNS

180

126

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The advent of multimaterial 3D printers allows the creation of neurosurgical models of a more realistic nature, mimicking real tissues. The authors used the latest generation of 3D printer to create a model, with an inbuilt pathological entity, of varying consistency and density. Using this model the authors were able to take trainees through the basic steps, from navigation and planning of skin flap to performing initial steps in a craniotomy and simple tumor excision. As the technology advances, models of this nature may be able to supplement the training of neurosurgeons in a simulated operating theater environment, thus improving the training experience.

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Deep brain stimulation can regulate arterial blood pressure in awake humans

Green¹,

Wang

Owen

et al. 2005

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The periaqueductal grey matter is known to play a role in cardiovascular control in animals. Cardiovascular responses to electrical stimulation of the periventricular/periaqueductal grey matter were measured in 15 awake human study participants following implantation of deep brain stimulating electrodes for treatment of chronic pain. We found that stimulation of the ventral periventricular/periaqueductal grey matter caused a mean reduction in systolic blood pressure of 14.2+/-3.6 mmHg in seven patients and stimulation of the dorsal periventricular/periaqueductal grey matter caused a mean increase of 16.7+/-5.9 mmHg in six patients. A comparison between ventral and dorsal electrodes demonstrated significant differences (P<0.05). These changes were accompanied by analogous changes in diastolic blood pressure, pulse pressure, maximum dP/dt but not in the time interval between each R wave on the electrocardiogram.

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Deep brain stimulation for the alleviation of post-stroke neuropathic pain

et al. 2006

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Our aim was to asses the efficacy of deep brain stimulation in post-stroke neuropathic pain. Since 2000, 15 patients with post-stroke intractable neuropathic pain were treated with deep brain stimulation of the periventricular gray area (PVG), sensory thalamus (Ventroposterolateral nucleus-VPL) or both. Pain was assessed using both a visual analogue scale and the McGill's pain questionnaire. VAS scores show a mean improvement of 48.8% (SD 8.6%). However, there is a wide variation between patients. This study demonstrates that it is an effective treatment in 70% of such patients.

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Sarah Owen

Translational principles of deep brain stimulation

Deep brain stimulation for pain relief: A meta-analysis

Utility of multimaterial 3D printers in creating models with pathological entities to enhance the training experience of neurosurgeons

Deep brain stimulation can regulate arterial blood pressure in awake humans

Deep brain stimulation for the alleviation of post-stroke neuropathic pain

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