Maternal-fetal-infant dynamics of the C3-epimer of 25-hydroxyvitamin D.

BACKGROUND: Poor vitamin D status (i.e. low serum 25-hydroxyvitamin D (25(OH)D)) has been associated with adverse clinical outcomes during pregnancy and childhood. However, the interpretation of serum 25(OH)D levels may be complicated by the presence of the C3-epimer of 25(OH)D. We aimed to quantify C3-epi-25(OH)D3 in pregnant women and fetuses, to explore the relationship of the C3-epimer between maternal and cord samples, and to establish whether infant C3-epimer abundance is explained by prenatal formation. METHODS: In a sub-study of a randomized trial of prenatal vitamin D3, 25(OH)D3 and C3-epi-25(OH)D3 were quantified by LC-MS/MS in 71 sets of mother-fetus-infant serum samples, including maternal delivery specimens, cord blood, and infant specimens acquired at 3-28 weeks of age. RESULTS: Without supplementation, median concentrations of C3-epi-25(OH)D3 were higher in infants (6.80 nmol/L) than mothers (0.45 nmol/L) and cord blood (0 nmol/L). However, there was substantial variation such that C3-epi-25(OH)D3 accounted for up to 11% (maternal), 14% (cord), and 25% (infant) of the total 25(OH)D3. Supplemental vitamin D3 significantly increased maternal-fetal C3-epi-25(OH)D3, and was a preferential source of C3-epi-25(OH)D3 compared to basal vitamin D, possibly due to C3-epi-cholecalciferol in the supplement. Multivariate regression did not suggest transplacental transfer of C3-epi-25(OH)D3, but rather indicated its generation within the fetal-placental unit from maternally-derived 25(OH)D3. Neither maternal nor fetal C3-epi-25(OH)D3 is accounted for the relatively high concentrations of infant C3-epi-25(OH)D3, suggesting rapid postnatal generation. CONCLUSIONS: C3-epi-25(OH)D3 is present in some pregnant women and fetuses, but does not appear to be efficiently transferred transplacentally. High C3-epimer concentrations in infancy are probably due to postnatal formation rather than fetal stores.

Analytical measurement and clinical relevance of vitamin D(3) C3-epimer.

With an ever-increasing clinical interest in vitamin D insufficiency, numerous automated immunoassays, protein binding assays, and in-house LC-MS/MS methods are being developed for the quantification of 25-hydroxyvitamin D(3) (25(OH)D(3)). Recently, LC-MS/MS methods have identified an epimeric form of 25(OH)D(3) that has been shown to contribute significantly to 25(OH)D(3) concentration, particularly in infant populations. This review describes the metabolic pathway and physiological functions of 3-epi-vitamin D, compares the capability of various 25(OH)D(3) methods to detect the epimer, and highlights recent publications quantifying 3-epi-25(OH)D(3) in infant, pediatric, and adult populations. In total, this review summarizes the information necessary for clinicians and laboratorians to decide whether or not to report/consider the C3-epimer in the analysis and clinical assessment of vitamin D status.

Analytical measurement of serum 25-OH-vitamin D3, 25-OH-vitamin D2 and their C3-epimers by LC-MS/MS in infant and pediatric specimens.

OBJECTIVES: To develop a simple and sensitive LC-MS/MS procedure for quantification of serum 25-OH-vitamin D3 (25-OH-D3), 25-OH-vitamin D2 (25-OH-D2), and their C3-epimers. METHODS: Serum 25-OH-vitamin D metabolites were extracted with MTBE and quantified by LC-MS/MS. Commercially available calibrators and QC materials were employed. The ion-transition 401.2→365.2 was monitored for 25-OH-D3 and C3-epi-25-OH-D3, 407.2→371.3 for d6-25-OH-D3, 413.2→331.2 for 25-OH-D2 and C3-epi-25-OH-D2 and 419.2→337.1 for, d6-25-OH-D2. As a proof-of-principle, 25-OH-D3 and C3-epi-25-OH-D3 were quantified in 200 pediatric subjects (0-20 years of age). Cholecalciferol supplements were examined as a potential source of C3-epimer. RESULTS: The assay provided an LLOQ of ≤2.8 nmol/L for all 25-OH-D metabolites, with a linear response up to 400 nmol/L. The CV was <10% for 25-OH-D2/3 and <15% for C3-epi-25-OH-D3. C3-epi-25-OH-D3 was quantified in all subjects, with higher concentrations observed in infants ≤1 year of age (11.44 nmol/L vs. 4.4 nmol/L; p<0.001). Within the first year of life, 25-OH-D3 concentrations increased linearly, while C3-epi-25-OH-D3 concentrations remained constant. At 12 months of age, C3-epi-25-OH-D3 concentration dropped by almost 50% (11.4 nmol/L in infants ≤1year of age vs. 5.4 nmol/L in infants 1-2years of age; p<0.001). Liquid vitamin D3 supplements did not contain appreciable amounts of C3-epi-D3. CONCLUSIONS: The proposed LC-MS/MS procedure is suitable for quantifying 25-OH-D3 metabolites. Although the C3-epimer is present in all pediatric subjects, it is significantly elevated in individuals ≤1 year of age and drops at 12 months of age. Oral vitamin D supplements are unlikely to be a significant source of C3-vitamin D epimer.