Abnormal pattern of cortical activation associated with voluntary movement in obsessive-compulsive disorder: an EEG study.

OBJECTIVE: Converging evidence in patients with obsessive-compulsive disorder (OCD) shows abnormalities of prefrontal areas and basal ganglia, which are also involved in motor control. Event-related desynchronization of mu and beta EEG rhythms is considered a correlate of motor activation during motor preparation and execution, followed by cortical idling or inhibition indicated by event-related synchronization. The authors investigated the circuits involved in motor behavior in OCD by using event-related desynchronization/synchronization. METHOD: Data on alpha and beta event-related desynchronization/synchronization with self-paced movement of the right thumb were obtained by using 29-channel EEG in 10 untreated OCD patients and 10 normal subjects. RESULTS: OCD patients showed delayed onset of mu event-related desynchronization with movement preparation and less postmovement beta synchronization, compared to normal subjects. CONCLUSIONS: Delayed event-related desynchronization in OCD is consistent with involvement of structures related to motor programming, such as basal ganglia. Lower levels of postmovement beta synchronization suggest impairment of the inhibitory system in OCD.

Whole brain volume changes in patients with progressive MS treated with cladribine.

OBJECTIVE: To compare changes in whole brain volume measured using MRI scans in patients with progressive MS enrolled in a double-blind, placebo-controlled trial assessing the efficacy of two doses of cladribine (0.7 and 2.1 mg/kg) and to assess the correlations between change in whole brain volume and change in other conventional MRI measures. BACKGROUND: Measuring brain parenchymal volumes is an objective and reliable surrogate for the destructive pathologic process in MS. The dynamics and the mechanisms of tissue loss in progressive MS are unclear. METHODS: Whole brain volumes were measured using postcontrast T1-weighted scans with 3 mm slice thickness from 159 patients with progressive MS (70% secondary progressive and 30% primary progressive) enrolled in a double-blind, placebo-controlled trial of 12-month duration. RESULTS: Whole brain volumes were similar in the placebo and cladribine-treated patients on the baseline scans. A significant decrease of brain volume over time was observed both in the entire population of patients (p = 0.001) and in the placebo patients in isolation (p = 0.04). No significant treatment effect of either dose of cladribine on brain volume changes over time was found. In the 54 patients who received placebo, the change in brain volume was not significantly correlated with other MRI measures at baseline (enhancing lesion number and volume and T2-hyperintense and T1-hypointense lesion volumes) or at follow-up (cumulative number of enhancing lesions and absolute and percentage changes of enhancing T2- and T1-hypointense lesion volumes). CONCLUSIONS: This study shows in a large cohort of patients that brain parenchymal loss occurs, even over a short period of time, in progressive MS and that cladribine is not able to alter this process significantly. It also suggests that MRI-visible inflammation and new lesion formation has a marginal role in the development of brain atrophy in patients with progressive MS.

A comparison of MR imaging with fast-FLAIR, HASTE-FLAIR, and EPI-FLAIR sequences in the assessment of patients with multiple sclerosis.

BACKGROUND AND PURPOSE: Fast fluid-attenuated inversion-recovery (FLAIR) sequences are sensitive for detecting lesions in patients with multiple sclerosis (MS). More rapid fast-FLAIR imaging of the brain can be achieved by the concomitant use of half-Fourier acquisition single-shot turbo spin-echo (HASTE-FLAIR) and echo-planar imaging (EPI-FLAIR). The present study was performed in a large cohort of subjects to assess and compare the number and volume of brain lesions detected by the fast-FLAIR, HASTE-FLAIR, and EPI-FLAIR sequences in patients with MS. METHODS: Fast-FLAIR, HASTE-FLAIR, and EPI-FLAIR sequences were obtained from 46 consecutive MS patients. Lesions seen on each type of sequence were counted and classified by consensus by two observers. Lesion volumes were measured using a semiautomated segmentation technique based on local thresholding. RESULTS: The quality of the fast-FLAIR images was significantly better than that of HASTE-FLAIR and EPI-FLAIR images. Fast-FLAIR revealed significantly more lesions and higher lesion volumes than did HASTE-FLAIR and EPI-FLAIR. A similar number of large lesions was detected by the three sequences, but HASTE-FLAIR and EPI-FLAIR showed significantly fewer small and intermediate lesions than did fast-FLAIR. The number of lesions seen on HASTE-FLAIR and EPI-FLAIR images was similar. CONCLUSION: HASTE-FLAIR and EPI-FLAIR sequences revealed as many large MS lesions as fast-FLAIR. Because their acquisition times are only a fraction of that needed for fast-FLAIR sequences, they may be useful for making a rapid diagnosis of MS in uncooperative patients. Their reduced ability to detect smaller lesions indicates that they should not be used as a routine approach to imaging patients with MS.