Leksell Radiosurgery for Movement Disorders.

Tremor is the most prevalent movement disorder in adults. Patients who are refractory to medical management can explore surgical intervention. Deep-brain stimulation (DBS) and radiofrequency thalamotomy (RFT) are surgical procedures for intractable tremor that target the ventralis intermedius (VIM) nucleus to relieve contralateral tremor. For patients who are not candidates for surgical procedures, stereotactic radiosurgery (SRS) is a minimally invasive management option for tremor relief. SRS has been used for the elderly, those considered high surgical risk for other surgical procedures, those who are unresponsive to either DBS or RFT, and those who prefer a less invasive option. Radiosurgical thalamotomy is performed using a central dose of 130-140 Gy delivered to the VIM nucleus of the thalamus. The critical aspect of the dose planning procedure is the selection of the target, which requires a neurosurgeon experienced with movement disorder surgery. More than 90% of patients experience improvements in their tremor and quality of life after radiosurgical thalamotomy. Adverse radiation effects rates are low (4%). In selected cases, staged bilateral procedure can also be performed to relieve bilateral refractory tremor. In patients with tremor-predominant Parkinson's disease, VIM thalamotomy is also effective.

[Neurofeedback-based motor imagery training for rehabilitation after stroke]. / Neurofeedback-gestütztes Bewegungsvorstellungstraining zur Rehabilitation nach einem Schlaganfall.

Mental training, including motor observation and motor imagery, has awakened much academic interest. The presumed functional equivalence of motor imagery and motor execution has given hope that mental training could be used for motor rehabilitation after a stroke. Results obtained from randomized controlled trials have shown mixed results. Approximately half of the studies demonstrate positive effects of motor imagery training but the rest do not show an additional benefit. Possible reasons why motor imagery training has so far not become established as a robust therapeutic approach are discussed in detail. Moreover, more recent approaches, such as neurofeedback-based motor imagery or closed-loop systems are presented and the potential importance for motor learning and rehabilitation after a stroke is discussed.

A valuable animal model of spinal cord injury to study motor dysfunctions, comorbid conditions, and aging associated diseases.

Most animal models of contused, compressed or transected spinal cord injury (SCI) require a laminectomy to be performed. However, despite advantages and disadvantages associated with each of these models, the laminectomy itself is generally associated with significant problems including longer surgery and anaesthesia (related post-operative complications), neuropathic pain, spinal instabilities, deformities, lordosis, and biomechanical problems, etc. This review provides an overview of findings obtained mainly from our laboratory that are associated with the development and characterization of a novel murine model of spinal cord transection that does not require a laminectomy. A number of studies successfully conducted with this model provided strong evidence that it constitutes a simple, reliable and reproducible transection model of complete paraplegia which is particularly useful for studies on large cohorts of wild-type or mutant animals - e.g., drug screening studies in vivo or studies aimed at characterizing neuronal and non-neuronal adaptive changes post-trauma. It is highly suitable also for studies aimed at identifying and developing new pharmacological treatments against aging associated comorbid problems and specific SCI-related dysfunctions (e.g., stereotyped motor behaviours such as locomotion, sexual response, defecation and micturition) largely related with 'command centers' located in lumbosacral areas of the spinal cord.