Intra-voxel and inter-voxel coherence in patients with multiple sclerosis assessed using diffusion tensor MRI

Previous diffusion tensor magnetic resonance imaging (DT-MRI) studies reported mean diffusivity () and fractional anisotropy (FA) changes in lesions and normal-appearing white matter (NAWM) of patients with multiple sclerosis (MS), but neglected the additional information which can be obtained by the analysis of the inter-voxel coherence (C). The present study is based on a large sample of patients with MS and it is aimed at assessing the potential role of C in the quantification of MS-related tissue damage of T2-visible lesions and NAWM. We obtained dual-echo, T1-weighted and DT-MRI scans from 78 patients with relapsing-remitting (RR), secondary progressive (SP), or primary progressive (PP) MS and from 26 healthy volunteers. We calculated , FA and C of T2-hyperintense lesions, T1-isointense lesions, T1-hypointense lesions and several areas of the NAWM. and FA of the majority of NAWM regions studied from MS patients were different from the corresponding quantities of the white matter from controls. NAWM C from patients was lower than white matter C from controls only for the parietal pericallosal areas. SPMS patients had higher corpus callosum and lower corpus callosum FA and C than patients with either RRMS or PPMS. Average lesion was higher, and average FA and C lower than the corresponding quantities measured in the NAWM. Average T1-hypointense lesion was higher and average FA lower than the corresponding quantities of T1-isointense lesions, whereas average C of these two lesion populations were not different. SPMS had higher average lesion than both PPMS and RRMS patients. NAWM and C of the corpus callosum were moderately correlated with disability. This study confirms the role of DT-MRI metrics to identify MS lesions with different amounts of tissue damage and to detect diffuse changes in the NAWM. It also shows that measuring C enables us to obtain additional information about tissue damage, which is complementary to that given by the analysis of and FA. Received: 27 July 2001, Received in revised form: 15 January 2002, Accepted: 22 January 2002     

A quantitative study of water diffusion in multiple sclerosis lesions and normal-appearing white matter using echo-planar imaging

OBJECTIVES: We used an optimized echo-planar pulse sequence for isotropically weighted diffusion imaging (1) to measure mean diffusivity (D) in lesions and normal-appearing white matter (NAWM) in the entire brain from patients with mildly disabling relapsing-remitting multiple sclerosis (MS), (2) to compare the D of NAWM from patients with that of white matter from normal controls, (3) to evaluate whether lesions classified on the basis of their appearance on enhanced T1-weighted scans have different D, and (4) to investigate the relationship between diffusion changes in lesions and NAWM. METHODS: Dual-echo and diffusion-weighted scans were obtained from 35 patients with relapsing-remitting MS and 24 sex- and age-matched normal controls. Postcontrast T1-weighted images were also obtained from the patients. After creating D maps and image coregistration, D values were measured for MS lesions larger than 5 mm and for 22 NAWM areas from each subject. RESULTS: All NAWM areas studied had significantly higher D in patients than in controls. A total of 173 lesions were identified on the dual-echo scans from patients. The average D for these lesions was significantly higher than that of NAWM. Twenty-two lesions were enhancing and 60 were classified as T1-hypointense. No significant difference in D values was found between enhancing and nonenhancing lesions, while the average D of T1-hypointense lesions was significantly higher than the average D of T1-isointense lesions. There was no significant correlation between the average D in lesions and NAWM. CONCLUSIONS: This study shows that diffusion-weighted imaging is able to identify MS lesions with severe tissue disruption. It also shows that widespread increased diffusion can be measured in the NAWM from patients with MS, and suggests that such changes are, at least partially, independent of larger abnormalities.     

A comparative assessment of cerebral white matter by magnetization transfer imaging in early- and adult-onset multiple sclerosis patients matched for disease duration

A more favorable clinical course in early-onset (EO) multiple sclerosis (MS) than adult-onset (AO) disease is reported. Our aim was to assess white matter with/without lesions by magnetization transfer (MT) imaging in EO and AO MS patients matched for duration of the disease. Relapsing-remitting MS patients with disease onset at age ≤18 years and >18 years (n = 11 for each) were matched according to sex, age, disease duration, and 22 sex-and age-matched healthy subjects were studied with MT imaging. MT ratios (MTR) of manually outlined ROIs from T1-hypointense, T1-isointense lesions and perilesional normal appearing white matter (NAWM) as well as NAWM of the left frontal lobe of the patients and healthy subjects were calculated. MTR differences between two patient groups and control subjects, and correlation of MTR with EDSS, disease onset age, disease duration and relapse rate were analyzed statistically. In comparison with NAWM of the patients and healthy subjects, the greatest MTR reductions were observed in T1-hypointense lesions followed by T1-isointense lesions and perilesional NAWM, respectively, in EO and AO MS. Both groups’ NAWM MTR were reduced; greater and more significantly in EO patients. No correlation was found between MTR of any ROI and EDSS, duration of the disease, disease onset age, or relapse rate. Although normalization does not occur, abnormality of white matter in MS decreases as distance from the lesions increases. Greater NAWM abnormality in EO MS may relate to inherent myelin abnormalities and different repair/reorganization processes in this particular group.     

White matter and lesion T1 relaxation times increase in parallel and correlate with disability in multiple sclerosis

Previous studies have established the clinical relevance of hypointense lesions (“black holes”) on T1-weighted MRI as a surrogate marker for pathological change [36]. In contrast to measuring the volume of “black holes”, the direct measurement of T1 values allows an objective assessment of the changes contributing to hypointensity both in the focal lesions and in the normal appearing white matter (NAWM). The aims of this study were first, to determine the relationship between T1 values in the NAWM and in discrete lesions, second, to test the relationship between white matter T1 changes and measures of disability and third, to determine whether pathology leading to T1 change occurred in thalamic grey matter of patients with multiple sclerosis. 24 patients with clinically definite multiple sclerosis (13 with relapsing-remitting multiple sclerosis and 11 with secondary progressive multiple sclerosis) and 11 controls participated. White matter T1 histograms and mean T1 values for the thalamus were generated from whole brain T1 relaxation time maps measured using a novel echo-planar imaging based MRI sequence at 3Tesla. Tissue segmentation based on T2- and T1-weighted images allowed independent study of changes in lesions and NAWM. White matter T1 histograms from the patient group showed a reduced peak height and a shift towards higher T1 values (p = 0.028) relative to controls. The mean thalamic T1 was greater for secondary progressive patients than for healthy controls (p = 0.03). Mean white matter T1 values correlated significantly with disability (r = 0.48, p = 0.02). The mean T1 value in the T1-hypointense lesions correlated strongly with the mean T1 value in the NAWM (r = 0.80, p < 0.001). No significant relationship was found between mean white matter T1 value and cerebral volume (r = −0.23, p = 0.31). The T1 measurements extend previous observations suggesting that changes in the NAWM occur in parallel with pathology in lesions of MS. T1 measurements of either the total or NAWM therefore may provide a potentially observer- and scanner- independent marker of pathology relevant to disability in MS. Received: 1 October 2001, Received in revised form: 7 January 2002, Accepted: 15 January 2002     

Diffusion tensor imaging in early relapsing-remitting multiple sclerosis.

Diffusion tensor magnetic resonance imaging (DTI) indices are abnormal in patients with established multiple sclerosis (MS). The objective of this study was to examine the diffusion characteristics of MS lesions, normal appearing white matter (NAWM) and normal appearing grey matter (NAGM) in MS patients with early relapsing-remitting disease. A further objective was to investigate the relationship between three DTI parameters (fractional anisotropy (FA), mean diffusivity (MD) and volume ratio (VR)) and clinical outcome measures (Kurtzke expanded disability status scale (EDSS) and MS Functional Composite Measure) in early disease. DTI was performed in 28 patients and 27 controls. Analysis was carried out using a region of interest (ROI) approach. ROIs were placed in 12 NAWM and nine NAGM regions. Significant differences were found in FA, MD and VR between lesions and NAWM (P< 0.001 for all three DTI parameters). No significant differences were found between patients and controls when examining NAWM or NAGM, although there was a trend for abnormal NAWM FA and VR in some regions. No correlation was found between DTI parameters in lesions, NAWM or NAGM and the clinical outcome measures. The lack of significant DTI abnormality in the NAWM and NAGM may reflect a lack of pathological change or a limited sensitivity of DTI using ROI methodology. Previous studies have shown abnormalities in TI relaxation time, magnetisation transfer ratio (MTR) and N-Acetyl aspartate (NM) in this cohort of patients, and as such, DTI using a region of interest (ROI) approach may not be as sensitive as other MR techniques in detecting subtle changes in normal appearing brain     

The relationship between lesion and normal appearing brain tissue abnormalities in early relapsing remitting multiple sclerosis

Background In multiple sclerosis (MS), pathological changes have been found both in macroscopic lesions and normal appearing tissue. Magnetisation transfer ratio (MTR) and T1 relaxation time are abnormal in normal appearing tissues in established MS. This study used these MR techniques in early MS to study normal appearing tissues and lesions. The purpose was to determine whether abnormalities are already detectable in normal appearing tissues in early MS, and if so how they correlate with lesion characteristics. Methods Twenty two patients with early relapsing remitting (RR) MS (median disease duration 2 years, range 7 months–3 years) and 11 age-matched controls were studied. MTR and T1 relaxation times were measured in 9 regions of normal appearing white matter (NAWM) and 7 of normal appearing grey matter (NAGM). Gadolinium enhancing, T1-hypointense and T2 lesion loads were measured in all patients. Results When all regions were combined, there was a significant difference between patient and control NAWM for both T1 and MTR; T1 was abnormal in 6/9 and MTR in 3/9 NAWM regions. Global assessment of NAGM revealed a significant difference between patients and controls for T1 but not for MTR; T1 was significantly abnormal only in frontal NAGM. There was no significant correlation between NAWM T1 or MTR and any of the lesion load measurements. Conclusions This study reveals quantitative MR abnormalities in both NAWM and NAGM in early RR MS, with more extensive changes in the former. The lack of correlation between NAWM and lesion abnormalities suggests that they have developed by at least partly independent mechanisms. T1 may be more sensitive than MTR in detecting subtle pathological changes in NAWM and NAGM. Received: 3 April 2001, Received in revised form: 15 June 2001, Accepted: 18 June 2001     

The normal appearing grey matter in primary progressive multiple sclerosis

Background: In 10–15 % of patients with multiple sclerosis (MS), the clinical course is characterized by slow progression in disability without relapses (primary progressive (PP) MS). The mechanism of disability in this form of MS is poorly understood. Using magnetization transfer ratio (MTR) imaging, we investigated normal appearing white matter (NAWM) and normal appearing grey matter (NAGM) in PPMS and explored the relationship of MTR measures with disability. Methods: Thirty patients with PPMS and 30 age matched controls had spin echo based MTR imaging to study lesions and normal appearing tissues. The brain was segmented into NAWM and NAGM using SPM99 with lesions segmented using a semiautomated local thresholding technique. A 75 % probability threshold for classification of NAWM and NAGM was used to diminish partial volume effects. From normalized histograms of MTR intensity values, six MTR parameters were measured. Mean lesion MTR and T2 lesion volume were also measured. Disability was assessed using Kurtzke's expanded disability status scale (EDSS). Results: Compared with controls, patients exhibited a significant reduction in mean NAWM (p = 0.001) and NAGM (p = 0.004) MTR. Spearman's rank correlation of EDSS with the six MTR parameters in NAWM and NAGM, mean lesion MTR, and T2 lesion volume, was only significant with mean NAGM MTR (r = −0.41, p = 0.02), the 25th percentile of NAGM MTR intensity (r = −0.37, p = 0.05), and T2 lesion volume (r = 0.39, p = 0.04). Multiple regression analysis of the relationship between EDSS and 4 MR parameters representing each tissue type (mean NAWM MTR, mean NAGM MTR, mean lesion MTR, T2 lesion volume) showed that the association of EDSS with mean NAGM MTR remained significant. Conclusions: There appear to be significant abnormalities in the NAGM in PP MS. Further investigation of the pathological basis and functional significance of grey matter abnormality in PPMS is warranted. Received: 7 September 2001, Received in revised form: 3 January 2002, Accepted: 16 January 2002 Correspondence to D. H. Miller     

Progressive change in primary progressive multiple sclerosis normal-appearing white matter: a serial diffusion magnetic resonance imaging study

In spite of marked disability, patients with primary progressive multiple sclerosis (PPMS) display smaller lesion volumes on conventional magnetic resonance imaging (MRI) compared with other forms of multiple sclerosis (MS). Hence, damage to the normal-appearing brain tissue (NABT) may play an important role in explaining the pathogenesis of disability in PPMS. Diffusion-weighted MRI (DW-MRI) probes water diffusion in vivo that can be altered by pathologic changes. Using DW-MRI we investigated diffusion in the NABT of 15 patients with PPMS over one year. The average apparent diffusion coefficient (ADCav) was measured in 10 regions of interest located in the normal-appearing thalamus and the normal-appearing white matter (NAWM). Six healthy subjects served as a reference. In contrast to healthy subjects, patients with PPMS showed an increment within 12 months of the ADCav in NAWM which was associated with an increase of the T2- and T1-lesion volumes. The ADCav in frontal NAWM was associated with disability as measured by the MS Functional Composite Measure. Serial DW-MRI depicts progressive changes in the NAWM of patients with PPMS. Our preliminary findings suggest that the processes causing structural damage in NAWM and lesions in patients with PPMS are partially linked and that changes of water diffusion in NAWM depicted by DW-MRI are clinically relevant.     

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.     

Multislice Brain Myelin Water Fractions at 3T in Multiple Sclerosis

PURPOSE: To evaluate a multislice nonlinearly-spaced 12-echo imaging sequence at 3T covering the supratentorial brain for the quantification of myelin water fraction (MWF) in multiple sclerosis (MS) patients. METHODS: Eighty-nine patients with, or at risk of, MS (69 relapsing remitting MS [RRMS], 7 secondary progressive MS [SPMS], 13 clinically isolated syndrome [CIS]) and 28 controls were studied. Twelve-echo datasets were acquired using a multislice T2 prep spiral imaging sequence and were fitted using a nonnegative least squares algorithm. The mean MWF within normal appearing white matter (NAWM), contrast-enhancing (CE), and nonenhancing T2 lesions were calculated. RESULTS: Mean MWF in white matter for controls was 11.3%. Mean MWF was significantly reduced in NAWM of MS patients (10.6%, P= .004) relative to controls. SPMS/RRMS patients with disease duration >5 years (10.3%) had lower MWF compared to CIS/RRMS with disease duration 相似文献   

Magnetization transfer changes in the normal appering white matter precede the appearance of enhancing lesions in patients with multiple sclerosis

Serial monthly magenetization transfer (MT) imaging was performed to evaluate whether a change of the normal appearing white matter (NAWM), which precedes the appearance of enhancing lesions, is seen in patients with multiple sclerosis (MS). Every 4 weeks for 3 months, 10 patients with relapsing-remitting MS were scanned with a T1-weighted sequence, 20 minutes after injection with 0.3 mmol/kg gadolinium-DTPA (Gd-DTPA). During each of the monthy sessions, MT and dual dual echo scans were also performed before Gd-DTPA injection. On coregistered images, the same slices but outside any present or future MR abnormality, and in enhancing lesions at the time of their apperance. Forty-eight new enhancing lesions with no corressponding abnormalities, the mean MTR in NAWM, measured from areas corresponding to future enhancing lesions, was significantly lower than the mean MTR in NAWM outside enhancing areas; the MTR decreased steadily as the time when the enhanced lesion approached. These results suggest that changes in the NAWM of patients with MS occur before lesions becomes evident on conventional MRI scans.     

Grey matter magnetization transfer ratio independently correlates with neurological deficit in secondary progressive multiple sclerosis

Although there is substantial brain grey matter pathology in secondary progressive multiple sclerosis (MS), there has been limited investigation of its contribution to disability. This study investigated the correlation of magnetization transfer ratio (MTR) measures taken from brain grey matter, normal appearing white matter (NAWM) and lesions with neurological deficit and disability in 113 people with secondary progressive MS. In order to adjust for the potential effects of focal white matter lesions and global brain atrophy, T2 lesion volume and normalized brain volume (NBV) were also calculated for each subject. Clinical measures included the expanded disability status scale (EDSS) and the multiple sclerosis functional composite (MSFC) scores. Linear regression analysis was used to assess the age- and gender-adjusted correlation of MTR histogram mean, peak height and peak location with the MSFC and individual component measures. Logistic regression analysis was used to determine whether imaging measures could be used to predict if subjects were in the higher disability group (EDSS ≥ 6.5). Significant correlations were detected between MSFC composite and mean MTR in (i) normal appearing white matter (NAWM; r = 0.327, p < 0.0001), (ii) grey matter (r = 0.460, p < 0.0001) and (iii) lesions (r = 0.394, p < 0.0001). Although NBV and T2 lesion volume correlated significantly with MSFC, grey matter histogram mean emerged as the best predictor of MSFC score. None of the MRI measures significantly predicted higher EDSS. These results suggest that brain grey matter pathology plays an important role in determining neurological impairment. The apparent paucity of correlation between MRI measures and EDSS is likely to represent the relative insensitivity of the latter measure in this study group.     

Diffusion tensor imaging in multiple sclerosis: a tool for monitoring changes in normal-appearing white matter

Our objectives were to determine the reproducibility of diffusion tensor imaging (DTI) in volunteers and to evaluate the ability of the method to monitor longitudinal changes occurring in the normal-appearing white matter (NAWM) of patients with multiple sclerosis (MS). DTI was performed three-monthly for one year in seven MS patients: three relapsing-remitting (RRMS), three secondary progressive (SPMS) and one relapsing SP. They were selected with a limited cerebral lesion load. Seven age- and sex-matched controls also underwent monthly examinations for three months. Diffusivity and anisotropy were quantified over the segmented whole supratentorial white matter, with the indices of trace (Tr) and fractional anisotropy (FA). Results obtained in volunteers show the reproducibility of the method. Patients had higher trace and lower anisotropy than matched controls (P < 0.0001). Over the follow-up, both Tr and FA indicated a recovery after the acute phase in RRMS and a progressive shift towards abnormal values in SPMS. Although this result is not statistically significant, it suggests that DTI is sensitive to microscopic changes occurring in tissue of normal appearance in conventional images and could be useful for monitoring the course of the disease, even though it was unable to clearly distinguish between the various physiopathological processes involved.     

A study of the mechanisms of normal-appearing white matter damage in multiple sclerosis using diffusion tensor imaging

Diffusion tensor imaging (DTI) investigates brain tissue microstructure in vivo. In multiple sclerosis (MS) Wallerian degeneration of axons traversing focal lesions is a potential mechanism of damage in normal-appearing white matter. In vivo evidence for this hypothesis is limited. The present study investigated the relationship between DTI-derived indices in the normal-appearing corpus callosum (CC) and the lesion loads (LLs) in connected cerebral regions. DTI was performed in 39 MS patients and in 21 age-matched controls. Fractional anisotropy (FA) and mean diffusivity (MD) were estimated in the genu, body and splenium of CC. Patients showed lower FA and higher MD in the CC than controls and both correlated with the total LL (r = −0.56 and r = 0.54, p < 0.0001). The LL of individual cerebral lobes correlated with both FA and MD in the corresponding callosal regions, with the body showing the strongest correlations with frontal and parietal LL (p < 0.0001). The strong correlations between DTI indices in the CC and the extent of lesions in connected brain regions support the hypothesis that Wallerian degeneration of axons transected by remote, but connected focal lesions, is an important pathogenic mechanism of damage in MS. Received: 16 July 2002, Received in revised form: 8 October 2002, Accepted: 14 October 2002 Correspondence to Prof. A. J. Thompson     

Abnormalities in normal appearing tissues in early primary progressive multiple sclerosis and their relation to disability: a tissue specific magnetisation transfer study

BACKGROUND: Patients with primary progressive multiple sclerosis (PPMS) often develop severe disability despite low levels of abnormality on conventional magnetic resonance imaging (MRI). This may relate to diffuse pathological processes occurring in normal appearing brain tissue (NABT) involving both white matter (NAWM) and grey matter (NAGM). Magnetisation transfer imaging (MTI) is capable of identifying these processes and may be particularly informative when applied to patients with early PPMS. AIM: To assess the relationship between abnormalities in NABT identified by MTI and disability and other radiological data in patients with early PPMS. METHODS: We studied 43 patients within 5 years of disease onset and 43 controls. The Expanded Disability Status Scale (EDSS) and the Multiple Sclerosis Functional Composite (MSFC) were scored. Magnetisation transfer ratios (MTR) of NABT, NAWM, and NAGM were calculated and the following MTR parameters were measured: mean, peak height, peak location, and MTR value at the 25th, 50th, and 75th percentiles. Proton density, T2, T1, and gadolinium enhancing lesion loads were also calculated. RESULTS: Differences were found between patients and controls in mean, peak height, and peak location of NAWM and NAGM (p < or = 0.001). Weak to moderate correlations were found between MTR parameters and disability in both NAWM and NAGM. Strong correlations between MTR parameters and lesion loads were found, particularly in NAWM. CONCLUSION: MTR abnormalities are seen in NAWM and NAGM in early PPMS and both are associated with disability. NAWM MTR abnormalities are more closely related to conventional MRI measures than those seen in NAGM.     

Effect of natalizumab on conversion of gadolinium enhancing lesions to T1 hypointense lesions in relapsing multiple sclerosis

Abstract.Background: Natalizumab, a humanized monoclonal anti-adhesion molecule antibody, reduces the frequency of new gadolinium (Gd) enhancing lesions and relapses in multiple sclerosis (MS). Its effect on evolution of new Gd enhancing lesions to T1 hypointense lesions is unknown.Methods: 213 patients were randomized to receive 3 mg/kg or 6 mg/kg natalizumab or placebo monthly for 6 months and then followed for a further 6 months. A subset of patients who had one or more new gadolinium enhancing lesions from Month 0 to Month 6 and available electronic data were analysed. Each new Gd enhancing lesion that developed during treatment (months 1–6) was investigated for conversion to a new T1 hypointense lesion at month 12. Lesions were classified as large or small if their cross-sectional area was greater or less than 20mm². Because of the similarity of both doses of natalizumab on the frequency of new Gd enhancing lesions, the two natalizumab arms were combined in all analyses.Results: Compared with the placebo group, the natalizumab group exhibited significant decreases in: (i) the proportion of patients with new Gd enhancing lesions that evolved to T1-hypointense lesions (10/38 [26 %] versus 27/40 [68 %]; p < 0.01); (ii) the proportion of patients who developed large T1 hypointense lesions (2/38 [5 %] versus 16/40 [40 %]; p < 0.01); (iii) the proportion of new Gd enhancing lesions that became T1 hypointense (11/75 [15 %] versus 118/466 [25 %]; p = 0.045); (iv) the mean proportion per patient of new Gd enhancing lesions that converted to T1-hypointense lesions (0.15 versus 0.28; p = 0.005), and (v) the odds ratio (OR) of converting from Gd enhancing to T1-hypointense lesions (OR = 0.48; 95% CI = 0.24, 0.94, p = 0.031)).Conclusion: Natalizumab significantly suppresses the evolution of new Gd enhancing to T1-hypointense lesions. This may reflect several mechanisms including reduced cell migration across the blood brain barrier, reduced T cell activation within lesions, an inhibitory effect on subsequent axonal damage within the new central nervous system lesion, and a reduced likelihood of recurrent lesion inflammation.     

The use of multiparametric quantitative magnetic resonance imaging for evaluating visually assigned lesion groups in patients with multiple sclerosis

In multiple sclerosis (MS), inflammatory lesions present a broad spectrum of histopathologic processes. For a better discrimination, lesions are visually defined into different lesion groups according to their appearance on conventional magnetic resonance imaging (MRI). The aim of this study was to investigate the properties of different MS lesion groups using multiparametric quantitative MRI. 35 patients diagnosed with relapsing–remitting MS received 3 Tesla MRI including magnetization-prepared 2 rapid acquisition gradient echo, diffusion tensor imaging and magnetization transfer imaging. Lesion segmentation was performed for T2 lesions, black holes and contrast-enhancing lesions. A subtraction mask was created including only T2 lesions that did not correspond to a black hole or contrast-enhancing lesion. T1 relaxation time (T1-RT), magnetization transfer ratio (MTR), mean diffusivity (MD) and fractional anisotropy (FA) were determined for every lesion and in normal-appearing white matter. Only MD differed significantly between all lesion groups and NAWM (p < 0.05), while FA differed between all lesion groups but not NAWM. T1-RT and MTR were not useful imaging biomarkers to distinguish between lesion groups. A lack of sensitivity and specificity and unproportional alterations of quantitative MRI measures, due to heterogenous histopathologic processes within lesions, may be a possible explanation for missing discrimination. Thus, not only interpretation of visually defined MS lesion but also interpretation of quantitative MRI measures remains challenging and should be conducted carefully.     

Diffusion tensor imaging of lesions and normal-appearing white matter in multiple sclerosis.

OBJECTIVE: To determine whether diffusion tensor imaging (DTI) can detect structural changes in normal-appearing white matter, and to distinguish between plaques of different pathologic severity, in patients with MS. BACKGROUND: Conventional MRI detects lesions sensitively in MS but has limited pathologic specificity. The diffusion of water molecules in brain tissue, most fully expressed mathematically by a tensor quantity, reflects its intrinsic microstructure. It is now possible to estimate the diffusion tensor noninvasively in the human brain using MR DTI. This method is unique in providing precise and rotationally invariant measurements of the amount and directional bias (anisotropy) of diffusion in white matter tracts relating to tissue integrity and orientation. METHODS: DTI was performed in six patients with MS and in six age-matched control subjects. Diffusion was characterized in normal-appearing white matter in both groups, and in lesions of different pathologic subtypes (inflammatory, noninflammatory, T1 hypointense, and T1 isointense). RESULTS: DTI identified significantly altered water diffusion properties in the normal-appearing white matter of patients compared with control subjects (p < 0.001), and distinguished between lesion types. The highest diffusion was seen in destructive (T1 hypointense) lesions, whereas the greatest change in anisotropy was found in inflammatory (gadolinium-enhancing) lesions. CONCLUSIONS: DTI detects diffuse abnormalities in the normal-appearing white matter of MS patients, and the findings in lesions appear to relate to pathologic severity. Its use in serial studies and in larger clinical cohorts may increase our understanding of pathogenetic mechanisms of reversible and persistent disability.     

1H MRSI comparison of white matter and lesions in primary progressive and relapsing-remitting MS

OBJECTIVE: To compare brain metabolite levels in patients with primary progressive (PP) and relapsing remitting (RR) MS and controls. Hypotheses: (1) creatine (Cr), a putative marker of gliosis, is elevated and N-acetylaspartate (NAA), a putative marker of axonal density and functional integrity, is reduced in PPMS lesions and normal appearing white matter (NAWM) compared to control white matter; (2) The pattern of metabolite change in PPMS is different than in RRMS. METHODS: MRI and proton magnetic resonance spectroscopic imaging (1H MRSI) were collected from 15 PPMS patients, 13 RRMS patients, and 20 controls. RESULTS: Cr was increased in PPMS NAWM compared to controls (P=0.035), and compared to RRMS NAWM (P=0.038). Cr was increased in focal MRI lesions from PPMS compared to lesions from RRMS (P=0.044) and compared to control white matter (P=0.041). NAA was similarly reduced in PPMS and RRMS NAWM compared to control. NAA was similarly reduced in PPMS and RRMS lesions, compared to control white matter. CONCLUSIONS: Creatine is higher in PPMS than RRMS NAWM and focal lesions. This observation is consistent with the notion that progressive disability in PPMS reflects increased gliosis and axonal loss whereas disability in RRMS reflects the cumulative effects of acute inflammatory lesions and axonal loss.     

Water content and myelin water fraction in multiple sclerosis

BACKGROUND: Measurements of the T2 decay curve provide estimates of total water content and myelin water fraction in white matter in-vivo, which may help in understanding the pathological progression of multiple sclerosis (MS). METHODS: Thirty-three MS patients (24 relapsing remitting, 8 secondary progressive, 1 primary progressive) and 18 controls underwent MR examinations. T2 relaxation data were acquired using a 32-echo measurement. All controls and 18 of the 33 MS patients were scanned in the transverse plane through the genu and splenium of the corpus callosum. Five white matter and 6 grey matter structures were outlined in each of these subjects. The remaining 15 MS patients were scanned in other transverse planes. A total of 189 lesions were outlined in the MS patients. Water content and myelin water fraction were calculated for all regions of interest and all lesions. RESULTS: The normal appearing white matter (NAWM) water content was, on average, 2.2% greater than that from controls, with significant differences occurring in the posterior internal capsules, genu and splenium of the corpus callosum, minor forceps and major forceps (p<0.0006). On average, MS lesions had 6.3% higher water content than contralateral NAWM (p<0.0001). Myelin water fraction was 16% lower in NAWM than for controls, with significant differences in the major and minor forceps, internal capsules, and splenium (p<0.05). The myelin water fraction of MS lesions averaged 52 % that of NAWM. CONCLUSIONS: NAWM in MS has a higher water content and lower myelin water fraction than control white matter. The cause of the myelin water fraction decrease in NAWM could potentially be due to either diffuse edema, inflammation, demyelination or any combination of these features. We present a simple model which suggests that myelin loss is the dominant feature of NAWM pathology.