Neuroanatomical considerations for optimizing thalamic deep brain stimulation in Tourette syndrome.

OBJECTIVE: Deep brain stimulation (DBS) of the centromedian thalamic nucleus has been reportedly used to treat severe Tourette syndrome, yielding promising outcomes. However, it remains unclear how DBS electrode position and stimulation parameters modulate the specific area and related networks. The authors aimed to evaluate the relationships between the anatomical location of stimulation fields and clinical responses, including therapeutic and side effects. METHODS: The authors collected data from 8 patients with Tourette syndrome who were treated with DBS. The authors selected the active contact following threshold tests of acute side effects and gradually increased the stimulation intensity within the therapeutic window such that acute and chronic side effects could be avoided at each programming session. The patients were carefully interviewed, and stimulation-induced side effects were recorded. Clinical outcomes were evaluated using the Yale Global Tic Severity Scale, the Yale-Brown Obsessive-Compulsive Scale, and the Hamilton Depression Rating Scale. The DBS lead location was evaluated in the normalized brain space by using a 3D atlas. The volume of tissue activated was determined, and the associated normative connective analyses were performed to link the stimulation field with the therapeutic and side effects. RESULTS: The mean follow-up period was 10.9 ± 3.9 months. All clinical scales showed significant improvement. Whereas the volume of tissue activated associated with therapeutic effects covers the centromedian and ventrolateral nuclei and showed an association with motor networks, those associated with paresthesia and dizziness were associated with stimulation of the ventralis caudalis and red nucleus, respectively. Depressed mood was associated with the spread of stimulation current to the mediodorsal nucleus and showed an association with limbic networks. CONCLUSIONS: This study addresses the importance of accurate implantation of DBS electrodes for obtaining standardized clinical outcomes and suggests that meticulous programming with careful monitoring of clinical symptoms may improve outcomes.

[Magnetic resonance imaging with 21.1 T and pathological correlations--diffuse Lewy body disease].

We investigated fixed basal ganglia specimens, including globus pallidus and putamen, with 21.1-Tesla MRI allowing us to achieve a microscopic level resolution from a patient with pathologically confirmed dementia with Lewy bodies (DLB) and a neurologically normal control case. We acquired T2 and T2 * weighted images that demonstrated diffuse and patchy lower intensities in the basal ganglia compared to control. There are several paramagnetic substances in brain tissue that could potentially reduce both T2 and T2 * relaxation times, including ferritin, iron (Fe3+), manganese, copper and others. Because iron is most abundant, low intensities on T2 and T2 * weighted images most likely reflect iron deposition. Iron, especially Fe3+, deposition was visible in the pathological specimens stained with Prussian blue after images were obtained. Although radiological-pathological comparisons are not straightforward with respect to either the MRI signal or relaxation quantification, there appears to be a correlation between the relative increase in iron as assessed by Prussian blue staining and the decrease in T2 * value between the DLB and control specimens. As such, this exceptionally high field MRI technique may provide details about the role that iron deposition plays either directly or indirectly as a biomarker in neurodegenerative processes.