Investigating the effects of hydroxyvitamin D3 on clinical, radiologic and immunomodulatory markers in MS patients: A randomized, clinical trial- a pilot study
Vitamin D deficiency/insufficiency is a risk factor for developing MS and is linked to increased disease activity in those with established disease. Several clinical trials have already been conducted to consider the effect of vitamin D supplementation on clinical outcomes of the disease but the findings were inconsistent. This paradox may be explained by supplementation dose, trial duration and also an insufficient rise in serum 25-hydroxyvitamin D to be effective on immunomodulatory pathways and consequent clinical outcomes. Of note, it was revealed that MS patients have a lower rise in serum 25-hydroxyvitamin D \[25(OH)D\] levels compared with healthy controls (HCs), when given the same amount of oral cholecalciferol supplementation. Cholecalciferol is the main vitamin D supplement that was used in these trials. When vitamin D3 is ingested, it is incorporated into chylomicrons and enters the lymphatic system. The chylomicrons then enter into the bloodstream via the superior cava. Most of the vitamin D is incorporated into the body fat. Vitamin D3 in the circulation and the vitamin D3 that is slowly released from the body fat into the circulation is converted in the liver to 25(OH)D3, taking approximately 6-8 weeks to achieve a steady state concentration of 25(OH)D3. The more rapid increase in serum concentrations of 25(OH)D3, by treatment with calcifediol instead of cholecalciferol, may provide an advantage through rapid entry into its target innate and adaptive immune cells, resulting in the paracrine/autocrine production of 1α,25(OH)2D which interacts with the vitamin D receptor (VDR) to modulate immune function.
Study Type
INTERVENTIONAL
Allocation
RANDOMIZED
Purpose
BASIC_SCIENCE
Masking
SINGLE
Enrollment
54
calcifediol
Cholecalciferol
Number of relapses
neurologic symptoms lasting more than 24 hours which occur at least 30 days after the onset of a preceding event
Time frame: 6 months (baseline and end of 6th month) in each intervention arm
disability
Change in expanded disability status scale (EDSS) according to Kurtzke 1983. The minimum is 0 (no disability) and maximum value is 10 (Death due to MS)- higher scores mean a worse outcome.
Time frame: 6 months (baseline and end of 6th month) in each intervention arm
Change in MRI parameters
new lesions on T2 weighted images, gadolinium enhancing lesions in T1-weighted images
Time frame: 6 months (baseline and end of 6th month) in each intervention arm
changing in brain parameters of Diffusion tensor imaging (DTI)
the integrity of white matter (WM) by analyzing WM microstructure through DTI
Time frame: 6 months (baseline and end of 6th month) in each intervention arm
changing in Cognition
Changing in cognitive functions by the Minimal Assessment of Cognitive Function in MS (MACFIMS) battery. The lower the score the more disfunction. MACFIMS is consisting of 7 subtests including: 1. the California Verbal Learning Test second edition (CVLT-II), with the range score: 0-80 2. the Paced Auditory Serial Addition Test (PASAT), with the range score: 0-16 3. the Symbol Digit Modalities Test (SDMT), with the range score: 0-110 4. the Brief Visuospatial Memory Test-Revised (BVMT-R), with the range score: 0-36 5. the Controlled Oral Word Association Test (COWAT), with the range score: 0-12 6. the Delis-Kaplan Executive Function System (DKEFS) sorting Test, with the range score: 0- undetermined 7. the Judgment of Line Orientation Test (JLO), with the range score: 0-30 The higher score in each subtest means the better cognitive function
Time frame: 6 months (baseline and end of 6th month) in each intervention arm
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CD4+ T cell response
After six months, changing the balance of Th17 and Tregs subtypes of CD4+ T cells. Detecting interleukin (IL) 17 -expressing T cells and Tregs expressing T cells by flow cytometry.
Time frame: 6 months (baseline and end of 6th month) in each intervention arm
Differential gene expression
After six months of 25-hydroxy vitamin D supplementation, the differentially expressed genes (DEGs) in peripheral blood mononuclear cells at the transcriptome level will be considered by RNA-seq
Time frame: 6 months (baseline and end of 6th month) in each intervention arm
needing hospitalization
needing hospitalization due to remissions and exacerbations of the disease
Time frame: 6 months (baseline and end of 6th month) in each intervention arm
changing in quality of life
changing in quality of life that determined by the Short Form Health Survey that contains 36-item (Sf36). The score is between 0-100. The lower the score the more disability. The higher the score the less disability.
Time frame: 6 months (baseline and end of 6th month) in each intervention arm
effective in rapidly raising circulating levels of 25(OH)D3
Serum levels of 25-hydroxy vitamin D (25(OH)D will be measured by High-performance liquid chromatography (HPLC)
Time frame: 6 months (baseline and end of 6th month) in each intervention arm
changing in the circulating levels of interleukin 17 as a inflammatory marker
After six months of calcifediol/or cholecalciferol supplementation, measuring serum levels of IL-17 by enzyme-linked immunoassay (ELIZA) kit.
Time frame: 6 months (baseline and end of 6th month) in each intervention arm
changing in the levels of interleukin 10 as anti- inflammatory marker
After six months of calcifediol/or cholecalciferol supplementation, measuring serum levels of IL-10 by ELIZA kit.
Time frame: 6 months (baseline and end of 6th month) in each intervention arm
changing in the levels of Tumor Necrosis Factor alpha (TNF-a) as an inflammatory marker related the T-CD4 subsets
After six months of calcifediol/or cholecalciferol supplementation, measuring serum levels of TNF-a by ELIZA kit.
Time frame: 6 months (baseline and end of 6th month) in each intervention arm