White Matter Diffusion Changes during the First Year of Natalizumab Treatment in Relapsing-Remitting Multiple Sclerosis

Study Design

The study was a prospective and observational study with 2 time points: baseline and month 12. The study population consisted of 22 patients with RRMS initiating natalizumab treatment and 12 healthy controls, age- and sex-matched to the patients. Before switching to natalizumab, 13 patients were receiving IFNb and 9 patients were receiving GA. To provide insight into the normal evolution of WM pathology in MS, we included 17 patients with RRMS following and continuing IFNb/GA. Patients receiving IFNb/GA were pooled (IFNb n = 11 and GA n = 6) and were matched to the patients initiating natalizumab for age, sex, disability (Expanded Disability Status Scale [EDSS]¹¹), and duration of prior IFNb/GA exposure.

Inclusion criteria for the patients with RRMS were a diagnosis of clinically definite MS¹² and being between 18 and 65 years of age. Exclusion criteria were the presence or history of psychiatric or neurologic disease (besides MS) and the presence or history of alcohol or drug abuse. The study protocol was approved by the institutional ethics review board of our center, and informed consent was obtained from all participants.

No serious or unanticipated adverse events attributed to MS medication developed in the patient groups.

Study Population

Patients initiating natalizumab at the outpatient neurology clinic of our center were screened according to the indication criteria used at our institution. These included at least 1 prior period of IFNb or GA with break-through disease with ≥1 relapse or rapidly evolving active RRMS defined by the occurrence of ≥2 relapses. Patients were only included in the study once the decision to start natalizumab treatment had already been made. At the baseline measurement, 6 patients were treatment-naïve for natalizumab; 13 patients had received 1, and 3 patients, 2 infusions. All patients continued natalizumab treatment (300 mg IV once every 4 weeks) for the duration of the study.

Patients receiving IFNb/GA were already receiving and continuing IFNb/GA as their regular medical treatment. Eleven patients were continuing IFN-b-1a/b (dose and route of administration dependent on type), and 6 patients were continuing GA (20 mg subcutaneous once daily). One patient from this group discontinued GA before the month 6 visit because of radiologic and clinically stable disease combined with occurrence of adverse effects (necrosis and scarring of the skin at injection sites). Another patient discontinued IFNb-1a 1 month before the month 12 visit due to conversion to secondary-progressive MS. Both patients remained in the study.

MR Imaging

All imaging was performed on a 1.5T whole-body scanner (Sonata; Siemens, Erlangen, Germany) by using an 8-channel phased array head coil. Structural imaging sequences included a 3D-T1-weighted magnetization-prepared rapid acquisition of gradient echo sequence (TR, 2.700 ms; TE, 5 ms; TI, 950 ms; 176 sagittal sections with 1.3-mm section thickness; 1.3 × 1.3 mm² in-plane resolution) for brain volume measurements and an axial turbo spin-echo proton-density/T2-weighted sequence (TR, 3.130 ms; TE, 24 and 85 ms; 46 contiguous 3-mm sections; 1 × 1 mm² in-plane resolution) for WM lesion detection. Diffusion-weighted echo-planar images (TR, 8.500 ms; TE, 86 ms; isotropic resolution, 2 × 2 × 2 mm) were acquired with 60 volumes with noncollinear diffusion gradients (b-value of 700 s/mm2) and 10 volumes without directional weighting.

Brain and Lesion Volumes

T2-hyperintense WM lesions were quantified by using an automated segmentation method.¹³ Normalized whole-brain (NBV), WM, and GM volumes were calculated by using the T1-weighted images and SIENAX (http://fsl.fmrib.ox.ac.uk/fsl/fslwiki/SIENA)¹⁴ Brain volumes were calculated after lesion filling, by using(part of FSL, Version 5.02; http://www.fmrib.ox.ac.uk/fsl). Brain volumes were calculated after lesion filling, by using an automated lesion-filling technique (Lesion Automated Preprocessing).¹⁵

Extent and Severity of WM Integrity Damage

The diffusion parameters fractional anisotropy (FA), mean diffusivity (MD), axial diffusivity (AD), and radial diffusivity (RD) were derived for each voxel by fitting a tensor model to the raw diffusion data after motion and eddy current correction. For statistical comparisons, Tract-Based Spatial Statistics (TBSS; http://fsl.fmrib.ox.ac.uk/fsl/fslwiki/TBSS),¹⁶ part of FSL, was used, in which all subjects' FA maps were aligned into a common space. The mean FA image was thinned to create a mean FA skeleton and thresholded at an FA of 0.2. Each subject's aligned FA and diffusivity data were then projected onto this WM skeleton, and the resulting data were fed into the FSL Randomize tool (http://fsl.fmrib.ox.ac.uk/fsl/fslwiki/Randomise).

At both time points, cross-sectional group differences in FA and MD of the mean WM skeleton were analyzed by using Randomize (500 permutations) by using a family-wise error–corrected threshold of P < .05 and correcting for age and sex.

Following the TBSS pipeline, we calculated the extent and severity of damage as follows:

1. The “extent” of damage was calculated per group, by calculating the percentage of significantly abnormal (P < .05) voxels within the WM skeleton for the diffusion parameters FA and MD, compared with healthy controls.

2. The “severity” of damage within the WM skeleton was calculated per patient by converting the diffusion measures FA and MD to z scores on the basis the mean and SDs of healthy control voxels. A single whole-skeleton mean z score was calculated for the diffusion parameters FA and MD, indicating the severity of damage across the entire WM skeleton per subject. As a post hoc exploration, the severities of AD and RD were additionally calculated at both time points.

Neuropsychological Evaluation

All subjects underwent an elaborate neuropsychological assessment on the day of scanning. The cognitive domains most frequently affected in MS were investigated by using tests from Rao's Brief Repeatable Battery for Neurologic Disease,¹⁷ including the Symbol Digit Modalities Test for information-processing speed, the Spatial Recall Task (SPART 10/36) for visuospatial memory, and the Word List Generation test for verbal fluency. Additionally, the Verbal Learning and Memory Task (the Dutch equivalent of the California Verbal Learning Test for verbal memory), the Stroop Color and Word Test for attention and inhibition, the Digit Span Forward and Digit Span Backward (part of the Wechsler Adult Intelligence Scale) for working memory, and the Delis-Kaplan Executive Function System Trail-Making Test for executive functioning were administered. Parallel versions were used for the different subtests when available (Symbol Digit Modalities Test, SPART 10/36, and Verbal Learning and Memory Task).

To uniformly quantify the deviation compared with test or subtest scores of the healthy controls, we converted the test or subtest raw baseline scores to z scores. An average (overall) cognition z score was also calculated.

The raw test or subtest scores were converted to Reliable Change Indices (RCI) to correct subtle learning effects in the longitudinal analysis.¹⁸ With this method, the reliable change on an individual test score is based on the difference between baseline and retest scores for the normative subject sample. RCI was computed as follows: where X is a single-subject test score, mean[hc] is the mean of the healthy controls' test scores, and 1 and 2 are the different time points at which cognitive testing was performed. The SD of the mean Δ score of the healthy controls was used as the standard error of the difference score (SED).

An RCI score above zero indicates a better performance, whereas an RCI score below zero indicates a worse performance than can be expected by the normal learning curve of healthy controls.

Patient Reported Outcome Measures

Fatigue and symptoms of anxiety and depression were measured by using the Checklist Individual Strength¹⁹ and the Hospital Anxiety and Depression Scale²⁰ questionnaires, respectively.

Statistical Analysis

Statistical analyses were performed with SPSS for Windows, Version 20.0 (IBM, Armonk, New York). When the variables were normally distributed, a multivariate GLM was used to test for group differences, with age, sex, and education included as covariates. Longitudinal analyses were performed by using paired t tests comparing baseline with month 12. Nonparametric analysis was performed by using the Kruskall-Wallis and (post hoc) Mann-Whitney tests. All analyses were Bonferroni-corrected, and P < .05 was considered statistically significant.