Low wintertime vitamin D levels in a sample of healthy young adults of diverse ancestry living in the Toronto area: associations with vitamin D intake and skin pigmentation

Study recruitment took place at the University of Toronto at Mississauga (Ontario, Canada) during the winter of 2007. The study was advertised to the University of Toronto community online, and also via the use of advertisements at the University of Toronto at Mississauga campus. Most of the participants were either students or employees of the university.

Participant eligibility for the study was assessed using a questionnaire that was completed prior to study enrollment. The following were exclusion criteria: age (only participants between the ages of 18 and 30 were recruited for this study), diagnosis of kidney/liver damage or other disorders or diseases that may affect vitamin D metabolism or absorption (including osteomalacia, osteopenia, Crohn's disease, etc.), use of medications that affect vitamin D metabolism (steroids, anticonvulsants, etc.) and recent exposure to UVB (such as visits to tanning salons or trips to sunny destinations less than three months before recruitment). Use of vitamin D supplements was not an exclusionary variable because we were interested in evaluating how many participants take vitamin D supplements, and the effect of supplementation on 25(OH)D levels. Participant ancestry was assessed based on responses to a personal questionnaire, which asked questions pertaining to the birthplace, migration history, native languages and self-reported ethnicity of the participants, their parents and grandparents.

In total, one hundred and seven subjects (58 females, 49 males) were eligible and agreed to participate. This study was approved by the University of Toronto Health Sciences Research Ethics Board, and all participants provided written informed consent.

Participants met with the researchers twice during the study. During the initial visit, which took place between February 14 and March 16, the participants completed a personal questionnaire that assessed ancestry (personal, parental, and grandparental places of birth, ethnicity, language, migration history, and present residence). Anthropometric measurements (weight and height) were also taken, from which body mass index (BMI) was calculated for each participant. All participants were instructed to complete a 7-day food diary, which recorded all beverages and food items consumed over a 7-day period, and a blood sample was drawn. During the second visit, which in most cases took place within two weeks of the first visit, participants returned the completed food diaries and were reimbursed for their participation.

Melanin content was measured in the inner upper arm using a narrow band reflectometer during the initial visit (Dermaspectrometer, Cortex Technology, Hadsund, Denmark) [42]. Measurements taken on the upper inner arm represent constitutive skin pigmentation (pigmentation in unexposed areas of the skin). The Dermaspectrometer estimates the amount of melanin in the skin from the amount of light reflected back to the machine in the red and green wavelengths of the light spectrum [42]. Skin color is primarily influenced by two pigments: hemoglobin and melanin, with hemoglobin showing a large optical absorption peak in the green wavelengths and a sharp drop off in the red wavelengths (this is why blood appears red), while melanin shows absorption of light at all wavelengths [42]. Based on the differences in the spectral curves of the two pigments, Diffey et al. [43] suggested that the reflectance of light in the red spectrum would generate an estimate of the melanin content of human skin, following the equation, Melanin = log₁₀ (1% red reflectance). Melanin Index values calculated using the Dermaspectrometer range from the low 20s to more than 100, with individuals with the lightest skin pigmentation having the lowest values and those with the darkest pigmentation having the highest [42].

An aliquot of whole blood was centrifuged and the serum fraction was removed after clotting and stored at -80°C. Serum parathyroid hormone (PTH), calcium, phosphate, and creatinine, were measured on the automated Modular Analytics Serum Work Area (Roche, Basel, Switzerland). Serum 25-hydroxyvitamin D [25(OH)D] concentrations were determined by the DiaSorin "25-OH Vitamin D TOTAL" competitive chemiluminescence immunoassay on the automated LIAISON^® analyzer (Stillwater, MN). This method has 100% specificity for both 25(OH) vitamin D₂ and 25(OH) vitamin D₃. This assay has a limit of detection of 10 nmol/L, an intra-assay coefficient of variation (CV) of 5%, and an inter-assay CV of 7%. Samples were analyzed in one continuous batch with quality control samples inserted at periodic intervals.

This 25(OH)D "total" method was previously validated with a different sample set in which serum 25(OH)D was measured using both the "total" method and the DiaSorin radioimmunoassay (RIA) (DiaSorin, Stillwater, MN). A comparison showed a strong correlation between the methods (r² = 0.814). Statistically, serum 25(OH)D concentrations determined by both methods were indistinguishable from one another (p = 0.17, paired t-test).

Daily intake of vitamin D from dietary and supplemental sources was estimated using a 7-day food diary. Subjects were provided with portion size aids and recorded their food, beverage and supplement intake for seven consecutive days. Vitamin D intake was analyzed with the computer program Food Processor (version 8.0 and its revisions, ESHA Research Inc., Salem OR, which included the 1997 Canadian Nutrient File from Health Canada); Canadian foods were always chosen where fortification was different from USA, e.g., margarine, breakfast cereals.

Differences between population groups in serum 25(OH)D levels and vitamin D intake were evaluated using ANOVA. For these analyses, serum 25(OH)D was log transformed and vitamin D intake was transformed using the square-root transformation. The effects of age, sex, BMI, total vitamin D intake and skin pigmentation (melanin content) on log serum 25(OH)D levels were explored using multiple linear regression. All statistical tests were performed with SPSS (Version 15.0, SPSS Inc., 2006). A power analysis using the software G*Power (Version 3) [44] indicated that, using a significance level of α = 0.05, our study has approximately 87% power to detect a large effect size (f = 0.40) in an ANOVA analysis (with a sample size of 75 individuals in three groups) and approximately 87% power to detect a medium effect size (f² = 0.15) in a multiple regression analysis (with a sample size of 107 individuals with five predictors).

Participants were divided into broadly defined subsets based on self-reported geographic origin gathered in the personal questionnaire. Most of the participants self-identified as being of either African, East Asian, European or South Asian ancestry. Individuals who reported being of other ancestries or of multiple ancestries were placed into another subgroup designated as "Other". Table 1 summarizes the clinical and biochemical characteristics for the total sample and the three population groups well represented in the sample (East Asian, European and South Asian). Because of the small sample size of individuals in the African and "Other" subgroups, these subgroups were not included in the statistical analyses. The following variables showed significant differences between the sexes: age (mean male = 21.5, female mean = 20.1 p = 0.002), BMI (male mean = 21.2 female mean = 18.7, p = 0.002), creatinine (male mean = 81.4, female mean = 59.4, p < 0.001) and calcium (male mean = 2.43, female mean = 2.38, p = 0.003). An ANOVA showed that, after controlling for age and sex, there were no significant differences in PTH, calcium, phosphate, and creatinine concentrations between the three ancestral groups (European, East Asian and South Asian). However, there were significant differences in serum 25(OH)D concentrations among the three groups (see below). The mean melanin index for the total sample was 33.0, and ranged from 22.4–53.5. Mean melanin index values (and ranges) for the different groups were as follows: East Asian = 32.0 (range 26.7–40.4); European = 28.6 (range 22.4–32.3); and South Asian = 38.3 (range 29.8–53.5). An ANOVA showed that that there was a significant difference in pigmentation among the groups, even after controlling for sex and age.

Figure 1 shows the distribution of serum 25(OH)D concentrations according to ancestry. Only one individual had serum measurements below the 10 nmol/L limit of detection. Table 2 reports vitamin D status for all participants, and stratified according to ancestry using three widely used cutoffs: < 25 nmol/L, < 50 nmol/L, < 75 nmol/L and finally, optimal vitamin D levels (≥ 75 nmol/L).

The mean serum 25(OH)D concentration in the global sample was 39.4 ± 21 nmol/L (range: 10–111 nmol/L). The mean was highest in Europeans (55.9, range 16.4–110.0 nmol/L), followed by East Asians (34.5, range 10.9–111.0 nmol/L) and lowest in South Asians (30.5, range 10–57.8 nmol/L). Only 6.6% of the total sample had optimal 25(OH)D concentrations, defined as > 75 nmol/L. Almost three-quarters (74%) of the sample had concentrations below 50 nmol/L. More importantly, 25(OH)D levels showed substantial variation according to ancestry: 34.4% of the subjects of European ancestry had concentrations < 50 nmol/L, while 85.2% of East Asians and 93.5% of South Asians had 25(OH)D levels < 50 nmol/L (Fisher's exact test, p < 0.001).

Analysis of the ancestry-specific group means for log serum 25(OH)D concentrations by ANOVA showed significant differences for the European, East Asian and South Asian samples (p < 0.001). Post-hoc tests (Tukey HSD) revealed that these results were driven by the significantly higher serum 25(OH)D concentrations in the European group with respect to the other two groups: East Asian and European (p < 0.001), and South Asian and European (p < 0.001). No significant pairwise differences in mean serum 25(OH)D were found between East Asians and South Asians (p = 0.775).

Mean vitamin D intake in the total sample and stratified by ancestry is reported in Table 3. Mean daily total vitamin D intake was substantially higher in the European sample (231.0 ± 173.5 International Units-IU) than in the East Asian (133.4 ± 101.7 IU) and South Asian (164.3 ± 144.3 IU) samples. In all groups, mean daily dietary intake of vitamin D was greater than mean daily intake from supplements. Only 22.9% of the participants reported the use of supplements. Vitamin D intake from food sources was highest in the European group as was vitamin D intake from supplements.

Total daily vitamin D intake (from diet and supplements, transformed using the square-root transformation) differed significantly among groups (ANOVA for East Asian, European and South Asian samples; p = 0.034). No significant differences in vitamin D intake were observed between the sexes.

The current recommendation for Adequate Intake (AI) of vitamin D is 200 IU/day for individuals between the ages of 19–50 [29]. The availability of vitamin D intake data in our study allowed us to further evaluate 25(OH)D levels in individuals with a vitamin D daily intake higher than 200 IU. When the sample was stratified according to total vitamin D intake and we analyzed only the 25(OH)D levels of the individuals with intakes higher than 200 IU/day, 84.4% of the individuals had serum 25(OH)D concentrations < 75 nmol/L and 40.6% of the individuals showed 25(OH)D levels < 50 nmol/L.

Several variables are known to affect vitamin D status and these were assessed for their influence on serum 25(OH)D: age [14, 18], BMI [19‐22], vitamin D intake [37, 45] and constitutive skin pigmentation [16, 17, 46]. A linear regression analysis was performed with log serum as the dependent variable and age, sex, BMI, total vitamin D intake and skin pigmentation as the independent variables. The regression analysis revealed that almost 35% of the variation in log serum 25(OH)D concentrations was explained by the linear combination of the variables tested (r² = 0.339, F_(5,98) = 10.049, p < 0.001). Table 4 shows the bivariate and partial correlations for each of the variables tested in the model. Only two of the five tested variables had a statistically significant relationship with serum 25(OH)D concentrations: total vitamin D intake (p < 0.001) and skin pigmentation (p = 0.033). On the basis of this analysis, we can infer that both total vitamin D intake and constitutive skin pigmentation are predictors of serum 25(OH)D in this sample. Total vitamin D intake showed a positive correlation with total vitamin D intake and it alone explained 30.4% of the variance in serum 25(OH)D concentrations. Controlling for all the other variables in the analysis (age, BMI, sex and total vitamin D intake), total vitamin D intake explained 28.9% of the variance in serum 25(OH)D (see partial correlations in Table 4). Constitutive skin pigmentation shows a negative correlation with serum 25(OH)D and explained 6.5% of the variation in serum 25(OH)D. When controlling for all the other variables, skin pigmentation explained 4.5% of the variance in serum 25(OH)D.

Examination of the partial regression plots suggested the presence of an outlier and the dataset was checked for outliers by examining casewise diagnostics, leverage statistic (h) and Mahalanobis distance. The following criteria were used: casewise diagnostics set at > 3 standard deviations, h > 0.2 and Mahalanobis distance > 20.52 (χ² = 20.52, with df = 5 and α = 0.001). One outlier was identified by both leverage statistics and Mahalanobis distance. This case was investigated and it was observed that this participants' pigmentation was the darkest in the sample (Melanin Index was 15 points higher than the second darkest person). The outlier was removed and the regression was performed again with no report of other outliers.

With the removal of the outlier, the strength of the multiple regression model improved (r² = 0.374, F_(5,97) = 11.597, p < 0.001). Once again, only total vitamin D intake (p < 0.001) and skin pigmentation (p = 0.003) had a significant effect on serum 25(OH)D concentrations. With the removal of the outlier, total vitamin D intake explained 30.9% of the variation in serum 25(OH)D. The relationship between serum 25(OH)D and skin pigmentation also increased with the removal of the outlier and skin pigmentation accounted for 9.2% of the variation in serum 25(OH)D (compared to 6.5% when the outlier was present in the dataset).