Increase of CSF inflammatory profile in a case of highly active multiple sclerosis.

BACKGROUND: Clinical and imaging follow-up coupled with cerebrospinal fluid (CSF) and possibly serum profiling could provide information on disease activity and disability evolution in multiple sclerosis patients. CASE PRESENTATION: We describe the case of a relapsing-remitting MS patient whose history was characterized by failure of several therapeutic approaches and sustained disease activity. By using a highly sensitive immunoassay methodology, we examined protein expression of 70 inflammatory/cytotoxic molecules in two consecutive paired CSF and serum samples, obtained respectively in 2006 and 2013. At disease diagnosis, elevated CSF protein levels of an inflammatory pattern, including CXCL13, CXCL12, IFNγ, TNF, sTNFR1, IL8, sCD163, APRIL, BAFF, pentraxin III and MMP2 were found compared with a group of controls. At the second lumbar puncture, sustained disease activity was accompanied by considerable (more than 2 fold changes) increase expression of most of these inflammatory molecules while no significant changes in serum inflammatory markers were detected in the two consecutive serum samples. CONCLUSIONS: Elevated CSF protein expression of pro-inflammatory mediators, possibly specifically associated to GM demyelination, could remain stable or increase over time in patients with active multiple sclerosis. We underline the role of fluid analysis in understanding the pathophysiology of the disease and providing information on possible markers of disease activity and evolution.

Effect of glatiramer acetate on cerebral grey matter pathology in patients with relapsing-remitting multiple sclerosis.

INTRODUCTION: In this two year longitudinal study we compare the progression of grey matter (GM) damage in MS patients treated with glatiramer acetate (GA) for relapsing-remitting multiple sclerosis (RRMS) respect to untreated patients. METHODS: We studied thirty-five treated with GA and thirty-five untreated RRMS subjects matched for age, gender, disease duration and EDSS. Each patient underwent neurological examination every 6 months and 3-Tesla MRI at study entry (T0), after 1 year (T1) and 2 years (T2). At T0, T1 and T2, the number of new cortical lesions (CLs) was assessed on double inversion recovery images. By using the longitudinal stream of FreeSurfer, the cortical thickness and volume changes of several cerebral structures were evaluated after 2 years. RESULTS: The mean number of new CLs was significantly lower in GA group compared to untreated patients both at T1 (0.9 ±â€¯1.0 vs 1.7 ±â€¯1.0, p < 0.05) and at T2 (1.4 ±â€¯1.3 vs 2.9 ±â€¯1.8, p < 0.001). Volume loss of thalamus (-0.5% ±â€¯0.2% vs. -1.1% ±â€¯0.4%; p < 0.001), globus pallidus (-4.4% ±â€¯3.1% vs. -8.2% ±â€¯4.5%; p < 0.001), hippocampus (-0.7% ±â€¯0.3% vs. -1.5% ±â€¯0.5%; p < 0.001) and cerebellum (-0.5% ±â€¯0.3% vs. -0.9% ±â€¯0.4%; p < 0.001) was also lower in the GA group. A more pronounced cortical thinning was observed in cingulate (p = 0.04), cuneus and frontomarginal gyrus (p = 0.01 for both comparisons) of the untreated patients. CONCLUSION: Our findings suggest that GA exerts its immunomodulatory action at the level of GM either reducing the accumulation of CLs and slowing down the GM atrophy progression. Despite a confirmation in a larger sample size is required, our results suggest a possible effect of GA on GM damage.

MRI of cortical lesions and its use in studying their role in MS pathogenesis and disease course.

Cortical grey matter (GM) demyelination is present from the earliest stages of multiple sclerosis (MS) and is associated with physical deficits and cognitive impairment. In particular, the rate of disability progression in MS, both in the relapsing and progressive phases, appears to be strictly associated with degenerative GM demyelination and diffuse cortical atrophy. In the last decade, several histopathological studies and advanced radiological methodologies have contributed to better identify the exact involvement/load of cortical pathology in MS, even if the specific inflammatory features and the precise cell and molecular mechanisms of GM demyelination and neurodegeneration in MS remain still not fully understood. It has been proposed that a combined neuropathology, imaging and molecular approach may help to define a more detailed characterization and precise assessment of the heterogeneous features of GM injury and inflammation in MS. This, in turn, will possibly identify specific imaging and biohumoral (cerebrospinal fluid/serum) correlates of cortical pathology that may have an important role in predicting and monitor the disease evolution.

Heterogeneity of Cortical Lesion Susceptibility Mapping in Multiple Sclerosis.

BACKGROUND AND PURPOSE: Quantitative susceptibility mapping has been used to characterize iron and myelin content in the deep gray matter of patients with multiple sclerosis. Our aim was to characterize the susceptibility mapping of cortical lesions in patients with MS and compare it with neuropathologic observations. MATERIALS AND METHODS: The pattern of microglial activation was studied in postmortem brain tissues from 16 patients with secondary-progressive MS and 5 age-matched controls. Thirty-six patients with MS underwent 3T MR imaging, including 3D double inversion recovery and 3D-echo-planar SWI. RESULTS: Neuropathologic analysis revealed the presence of an intense band of microglia activation close to the pial membrane in subpial cortical lesions or to the WM border of leukocortical cortical lesions. The quantitative susceptibility mapping analysis revealed 131 cortical lesions classified as hyperintense; 33, as isointense; and 84, as hypointense. Quantitative susceptibility mapping hyperintensity edge found in the proximity of the pial surface or at the white matter/gray matter interface in some of the quantitative susceptibility mapping-hyperintense cortical lesions accurately mirrors the microglia activation observed in the neuropathology analysis. CONCLUSIONS: Cortical lesion susceptibility maps are highly heterogeneous, even at individual levels. Quantitative susceptibility mapping hyperintensity edge found in proximity to the pial surface might be due to the subpial gradient of microglial activation.

Epilepsy in multiple sclerosis: The role of temporal lobe damage.

BACKGROUND: Although temporal lobe pathology may explain some of the symptoms of multiple sclerosis (MS), its role in the pathogenesis of seizures has not been clarified yet. OBJECTIVES: To investigate the role of temporal lobe damage in MS patients suffering from epilepsy, by the application of advanced multimodal 3T magnetic resonance imaging (MRI) analysis. METHODS: A total of 23 relapsing remitting MS patients who had epileptic seizures (RRMS/E) and 23 disease duration matched RRMS patients without any history of seizures were enrolled. Each patient underwent advanced 3T MRI protocol specifically conceived to evaluate grey matter (GM) damage. This includes grey matter lesions (GMLs) identification, evaluation of regional cortical thickness and indices derived from the Neurite Orientation Dispersion and Density Imaging model. RESULTS: Regional analysis revealed that in RRMS/E, the regions most affected by GMLs were the hippocampus (14.2%), the lateral temporal lobe (13.5%), the cingulate (10.0%) and the insula (8.4%). Cortical thinning and alteration of diffusion metrics were observed in several regions of temporal lobe, in insular cortex and in cingulate gyrus of RRMS/E compared to RRMS ( p< 0.05 for all comparisons). CONCLUSIONS: Compared to RRMS, RRMS/E showed more severe damage of temporal lobe, which exceeds what would be expected on the basis of the global GM damage observed.

Intracerebral regulation of immune responses.

Major progress has been made over the last years in our understanding of the mechanisms underlying immune privilege and immune surveillance of the central nervous system (CNS). Once considered a passive process relying only on physical barriers, immune privilege is now viewed as a more complex phenomenon, which involves active regulation of immune reactivity by the CNS microenvironment. Evidence has also emerged that the immune system continuously and effectively patrols the CNS and that dysregulated immune responses against CNS-associated (exogenous or self) antigens are involved in the pathogenesis of various neurological diseases. In this article we shall briefly review current knowledge of how the immune response is regulated locally in the CNS and which cell types and molecular mechanisms are involved in shaping intracerebral immune responses.