Key words
25(OH)D - 25-Hydroxyvitamin D - Pre-participation examination - Supplementation -
Season - Youth
Main Points
-
Desirable vitamin D concentrations corresponding to 75 nmol/L of 25(OH)D or more have
been associated with improved muscle function, regeneration and performance, optimal
bone health and immune function in athletes.
-
The prevalence of insufficient vitamin D concentrations was high with one in two athletes
presenting insufficient concentrations of 25(OH)D (<75 nmol/L).
-
Younger age, type of sport with mainly indoor training, the lack of vitamin D supplementation,
lower BMI, and the sun-deprived seasons (fall, winter and spring) were found to be
potential risk factors for low 25(OH)D concentrations.
-
Vitamin D supplementation in athletes should be considered, especially during sun-deprived
seasons.
Introduction
Higher vitamin D concentrations [25(OH)D] are associated with multiple health benefits
such as higher bone mass and acquisition, and protective effects against cardiovascular
diseases, cancer and other chronic diseases [4]
[26]. Nevertheless, there is still controversy about the clinical relevance of 25(OH)D
[55]. In general, 25(OH)D is increased by sun radiation (sun angle >30°) on non-covered
skin, nutrition, and vitamin D supplementation, and decreased by various diseases
(e. g. obesity, liver failure) [26]. Further studies suggest that higher age [30], higher BMI or fat mass [24]
[49], darker skin colour [8]
[9], sunscreen use [27]
[36], and indoor compared to outdoor sports activities [14]
[35]
[44] are associated with lower 25(OH)D concentrations as an expression of inadequate
intake or production by the skin or altered metabolic pathways. The influence of sex
is controversial [30]
[37].
On a population level, most international authorities classify 25(OH)D of >50 nmol/L
as sufficient and ≥75 nmol/L as desirable [11]
[12]
[27]
[41]
[47]. The higher 75 nmol/L target is supported by studies that show multiple beneficial
effects such as increased peak bone mass and mineral density, muscle strength, a maximal
suppression of parathyroid hormone, optimized intestinal calcium resorption and immunological
benefits [4]
[11]
[20]
[23]
[26]
[27].
In athletes, circulating 25(OH)D has been associated with maintained muscle function
including improvements in muscle contractions, enhanced growth and regeneration following
muscle damage, and optimal bone health [7]
[17]
[43]
[48]
[56]. Athletes with desirable 25(OH)D concentrations show an improved immune function
including, but not limited to, lower incidence of upper respiratory tract infections
[20]
[28]. Yet, inadequate concentrations of 25(OH)D are highly prevalent in athletes especially
during the winter months [3]
[14].
Several predictors of vitamin D insufficiency have been reported in the past that
allow detecting populations at risk that may deserve more preventive attention. Because
we are dealing with an athlete population that may differ from the general population,
predictors from the general population (e. g. age, sex, BMI, skin colour and protection,
vitamin D substitution, season, latitude) may differ [8]
[9]
[27]
[30]
[36]
[37]
[49], and selective factors in athletes such as training hours or location of sports
activity as a proxy for sun exposure may play a role [14].
Previous studies that investigated the prevalence and predictors of insufficient 25(OH)D
in athletes lacked external validity, limiting their generalisability for central
Europe (e. g. Switzerland) due to different reasons: studies used different analytical
approaches for 25(OH)D concentrations (e. g. RIA, CLIA) which affects comparability
of results [2]
[14]
[18]
[34]
[50], included non-comparable populations (e. g. Northern countries like the UK, other
races as in Qatar, Middle East) [10]
[14]
[18], used small sample sizes of<30 [14]
[16]
[63]
[64], or focussed on only one specific season or selective predictors without controlling
for others [14].
To address the study limitations mentioned, the objective of this study was to assess
the prevalence and predictors of insufficient 25(OH)D concentrations by conducting
a cross-sectional study on a large diverse (e. g. age, type of sport) sample of competitive
athletes in Switzerland over the period of one year. We hypothesised a high prevalence
of vitamin D insufficiency and variables like sex, age, BMI, vitamin D substitution,
skin colour, sunscreen use, hours of training (proxy variable for sun exposure), location
of sport activities (indoor vs. outdoor sports), and season to be associated with
25(OH)D concentrations.
Materials and Methods
Participants
This is a cross-sectional study that was conducted on a convenience sample of 603
Swiss Olympic athletes corresponding to 3.4% of a total of 17,927 active Swiss Olympic
card holders [54]. All athletes with a National Olympic Committee (Swiss Olympic) card reflecting
a regional, national or international competitive sport level were eligible to participate.
No other eligibility criteria were applied. All participants were healthy (e. g. no
diagnosis of renal insufficiency). A total of 24 (out of 39) National Olympic Committee-accredited
sports medical centres participated in the study and recruited study participants
during the pre-participation evaluation (PPE) over a period of 13 months (5/2014–6/2015).
Participation was voluntary for centres. The PPE by the physician included a medical
examination, routine blood sample examination and the completion of a questionnaire.
Blood samples were processed and analysed at a single certified central laboratory
(Canton hospital Aarau AG, Aarau, Switzerland) after being sent by express mail within
12 h. Participation was voluntary and written informed consent was obtained for all
participants. Data protection was ensured through pseudonymisation. According to Swiss
regulations no ethical approval from national authorities had to be obtained for this
type of study, which met the ethical standards in sport and exercise science research
[19].
Vitamin D
Vitamin D (cholecalciferol/25-hydroxyvitamin D3) was analysed using a kit for the
quantification of vitamin D2 and vitamin D3 (PerkinElmer, Turku, Finland). The kit
employed isotope dilution and HPLC coupled with mass spectrometry (ID-LC-APCI-MS/MS)
and was installed on an Ultimate 3000 HPLC (Thermo Fisher, Waltham, MA, USA) and a
QTRAP 5500 mass spectrometer (Sciex, Framingham, MA, USA) [50]
[57]. The detection limit (detection of lowest concentration) was 5 nmol/L. According
to the manufacturer, intra-assay variability is between 4.45 and 5.0% and inter-assay
variability lies between 4.3% and 5.6%. For the main analysis, 25(OH)D was dichotomized,
with concentrations<75 nmol/L defining insufficient and concentrations ≥75 nmol/L
defining desirable levels.
Predictors
Information about sociodemographic factors, sports and training, clinical information,
clinical symptoms and further variables potentially related to 25(OH)D was gathered
via a questionnaire. Age was included in years. Body mass index (BMI, kg/m2) and BMI-for-age
z-scores were calculated according to the World Health Organization references (athletes
above 19 years were set to 19 years) [65]. Season was categorized based on the four astronomic seasons that take solar radiation
into account; spring (March 21 to June 20), summer (June 21 to September 20), fall
(September 21 to December 20) and winter (21 December to 20 March). The main sport
activities were divided into indoor sports (e. g. hockey, gymnastics, swimming) and
outdoor sports (e. g. football, snow sports, marathon). Training hours were assessed
as average hours per week over the last three months. Skin colour was assessed at
five levels and subsequently dichotomized into fair skin (pale/fair skin, fair skin=northern
European and Scandinavian type) and dark skin (brown, dark skin and black=southern
European, Indian, and African type) due to low case numbers in some categories [15]. Sunscreen use was rated on a 5-point Likert scale from regular to never use (in
100%, 75%, 50%, 25%, or 0% of time). The first three answers were categorized as “regular”
use and the latter two as “seldom/never”. Information about vitamin D (cholecalciferol)
supplementation was collected by asking for intake frequency, dosage and the trade
name. All reported supplements were checked for cholecalciferol/ergocalciferol content,
but exact dosage IU could not be determined due to partially imprecise product information
from participants. A binary variable (yes/no) was coded indicating cholecalciferol/ergocalciferol
supplementary intake. If no trade name was stated for multivitamins, vitamin D supplementation
was assumed and coded as “yes”.
Statistical analysis
Sample characteristics are presented as means±standard deviations (SD) for continuous
variables and as counts and frequencies for categorical variables. The two sample
proportion (z-test) or chi-squared test was used to detect differences in 25(OH)D
(insufficient versus desirable) fractions for each level of all independent categorical
variables. Mean differences of continuous variables (across the binary outcome variable)
were tested by independent t-test with unequal variances (Welch's t-test).
A binary logistic regression (main model) was calculated to detect potential risk
factors of 25(OH)D concentrations<75 nmol/L. Coefficients are reported as odds ratio
including 95% confidence interval. To obtain additional information on the extent
of influence of the predictors, a multiple linear regression was calculated reporting
beta coefficients and 95% confidence interval. To minimize potential bias, loss of
precision and power due to item non-response (missing values of single athlete on
one or more variables), we imputed the data (m=40) using a chained equation approach
(MI) [51]
[52]
[62]. All variables used in the analytical models were also used in the imputation models
including the outcome [38]
[51]. Additionally, a complete case analysis (CCA) was performed in order to compare
the results with the multiple imputation-based analysis (differences between complete
case and imputed analysis are reported). Predicted probabilities of all independent
variables (predictive margins) including a 95% confidence interval (holding other
variables constant at their mean values) were calculated to graphically display the
effects of the predictors in the logistic regression model. Data analysis was performed
using Stata for Windows version 13.1 (StataCorp LP, College Station, TX, USA).
Results
The characteristics of the total sample of athletes and athletes stratified by 25(OH)D
categories (desirable ≥75 nmol/L or insufficient<75 nmol/L) are shown in [Table 1]. Athletes (63% male) ranged from 9 to 46 years of age and showed a mean (SD) weight
of 63.4 (15.1). Missing values were present for BMI, training hours, skin colour,
sunscreen use, and outdoor/indoor sports ranging from 0.3 to 15.6%.
Table 1 Sample characteristics by 25(OH)D category (desirable ≥75 nmol/l and insufficient<75 nmol/l)
and in the total sample (n=603) including missing values.
|
Desirable level (n=297)
|
Insufficient level (n=303)
|
Total sample (n=603)
|
Mean differences
|
|
n (%)
|
Mean (SD)
|
n (%)
|
Mean (SD)
|
n (%)
|
Mean (SD)
|
Diff.
|
(95% CI )
|
|
Outcome
|
|
25(OH)D
|
297 (49.5)
|
|
303 (50.5)
|
|
600 (99.5)
|
75.9 (23.4)
|
|
|
|
25(OH)D unknown, missing
|
|
|
|
|
3 (0.5)
|
|
|
|
|
Predictors
|
|
Sex a
|
|
Female
|
91 (40.4)
|
|
134 (59.6)
|
|
225 (37.3)
|
|
14.5**
|
(22.6; 6.3)
|
|
Male
|
206 (54.9)
|
|
169 (45.1)
|
|
378 (62.7)
|
|
|
|
|
Age (years) b
|
297
|
20.4 (5.7)
|
303
|
17.2 (5.3)
|
603
|
18.8 (5.8)
|
3.2**
|
(2.3; 4.1)
|
|
BMI & BMI z-score
|
|
BMI b
|
271
|
22.1 (2.9)
|
235
|
20.4 (2.9)
|
509 (84.4)
|
21.3 (3.0)
|
1.8**
|
(1.3; 2.3)
|
|
BMI unknown, missing
|
|
|
|
|
94 (15.6)
|
|
|
|
|
BMI z-score b
|
|
0.22 (0.80)
|
|
− 0.10 (0.84)
|
|
0.07 (0.8)
|
0.31**
|
(0.16; 0.45)
|
|
Vitamin D supplementation a
|
|
Yes
|
93 (57.1)
|
|
70 (42.9)
|
|
164 (27.2)
|
|
|
|
|
No
|
204 (46.7)
|
|
233 (53.3)
|
|
439 (72.8)
|
|
10.4*
|
(1.5; 19.3)
|
|
Skin colour a
|
|
Pale, fair
|
205 (48.8)
|
|
215 (51.2)
|
|
421 (69.8)
|
|
5.6
|
(–3.8; 15.0)
|
|
Brown, dark
|
80 (54.4)
|
|
67 (45.6)
|
|
149 (24.7)
|
|
|
|
|
Sun protection unknown, missing
|
|
|
|
|
33 (5.5)
|
|
|
|
|
Sunscreen use a
|
|
0% to 25%
|
109 (46.0)
|
|
128 (54.0)
|
|
238 (39.5)
|
|
7.4
|
(−1.0; 15.8)
|
|
50% to 100%
|
173 (53.4)
|
|
151 (46.6)
|
|
326 (54.1)
|
|
|
|
|
Sun protection unknown, missing
|
|
|
|
|
39 (6.5)
|
|
|
|
|
Training hours / week b
|
285
|
13.3 (5.7)
|
282
|
12.3 (6.9)
|
570 (94.5)
|
12.8 (6.3)
|
1.0*
|
(0.0; 2.1)
|
|
Training hours / week unknown, missing
|
|
|
|
33 (5.5)
|
|
|
|
|
|
Location of sport a
|
|
Outdoor
|
177 (52.7)
|
|
159 (47.3)
|
|
337 (55.9)
|
|
7.3
|
(–1.0; 15.0)
|
|
Indoor
|
119 (45.4)
|
|
143 (54.6)
|
|
264 (43.8)
|
|
|
|
|
Outdoor sports unknown, missing
|
|
|
|
|
2 (0.3)
|
|
|
|
|
Season c
|
|
Summer
|
90 (83.3)
|
|
18 (16.7)
|
|
108 (17.9)
|
|
0.00**
|
|
|
Fall
|
98 (50.0)
|
|
98 (50.0)
|
|
197 (32.7)
|
|
|
|
|
Winter
|
43 (32.1)
|
|
91 (67.9)
|
|
135 (22.4)
|
|
|
|
|
Spring
|
66 (40.7)
|
|
96 (59.3)
|
|
163 (27.0)
|
|
|
|
* Sig (p<0.05)/** highly sig (p<0.01) based on two-sided tests; a Difference (%) based on two sample proportion z-test (e. g. proportion (female insufficient)
- proportion (male insufficient)); b Two-sample t-test with unequal variances (Welch approximation) ; c Chi-squared test
Insufficient 25(OH)D concentrations<75 nmol/L were present in 50.5% of athletes while
a deficiency<50 nmol/L was present in 14%. Insufficient concentrations of 25(OH)D
were significantly more prevalent in females, in athletes without vitamin D supplementation,
and in fall, winter and spring compared with summer. Age, BMI (unstandardised and
standardised), and training hours per week were significantly lower in athletes with
insufficient 25(OH)D concentrations compared with the desirable group. Mean (SD) and
median (interquartile range) 25(OH)D concentrations were 75.9 (23.4) and 74.8 (31.3)
nmol/L, respectively. Further sample characteristics (type of sport) are given in
Appendix Table 1S).
Tested predictors of insufficient 25(OH)D concentrations investigated by logistic
and linear regression are shown in [Table 2]. By logistic regression, younger age, lower BMI z-scores, the lack of vitamin D
supplementation, indoor versus outdoor sport activities and the seasons of fall, winter,
and spring as compared with summer significantly increased the probability of insufficient
25(OH)D. [Fig. 1]
[2]
[3] summarize the mean-adjusted predicted probabilities of insufficient 25(OH)D concentrations
for all categorical predictors, age and BMI z-scores. Differences in probability of
insufficient 25(OH)D were found for indoor (58.5%) versus outdoor sports (42.5%),
the lack of vitamin D supplementation (52.4%) versus supplementation (42.0%) and during
the sun-deprived seasons of fall (49.5%), winter (70.3%) and spring (57.3%) as compared
with summer (17.0%). Higher predicted probabilities of insufficient 25(OH)D were also
found for younger as compared with older age and for lower compared with higher BMI
z-scores (see [Fig. 2], [3]). Similar results were obtained from multiple linear regressions (adjusted for all
other variables). A one-unit increase in age (year) and BMI z-score was associated
with an increase of 0.85 nmol/L and 3.04 mmol/L 25(OH)D, respectively. Likewise, 25(OH)D
concentrations were significantly lower in the group without than with vitamin D supplementation
(–5.1 nmol/L), in indoor than outdoor sports (–5.4 nmol/L) and during fall (–16.9 nmol/L),
winter (–28.6 nmol/L), spring (19.7 nmol/L) compared to summer. Minor differences
in results based on the multiple imputation as compared to the complete case analysis
occurred but did not change the conclusion.
Fig. 1 Mean-adjusted predicted probabilities of 25(OH)D concentrations<75 nmol/L (95% confidence
interval) for categorical variables derived from the logistic regression model (n=603).
Predictions are mean-adjusted for all other variables listed in [Table 2]. Significantly higher probabilities of 25(OH)D insufficiency were present for indoor
vs. outdoor sports, not supplemented vs. supplemented athletes, and in fall, winter
and spring compared to summer.
Fig. 2 Mean-adjusted predicted probabilities of 25(OH)D concentrations<75 nmol/L (95% confidence
interval) for different age groups derived from the logistic regression model (n=603).
Predictions are mean-adjusted for all other variables listed in [Table 2]. Higher age was significantly related to lower probability of 25(OH)D insufficiency.
Fig. 3 Mean-adjusted predicted probabilities of 25(OH)D concentrations<75 nmol/L (95% confidence
interval) for different BMI z-scores derived from the logistic regression model (n=603).
Predictions are mean-adjusted for all other variables listed in [Table 2]. Higher BMI z-scores were significantly related to lower probability of 25(OH)D
insufficiency.
Table 2 Predictors of 25(OH)D concentrations (< 75 nmol/l) by logistic regression (insufficient<75 nmol/l
25(OH)D vs. desirable ≥75 nmol/l 25(OH)D) and linear regression (n=603).
|
Logistic regression (insufficient vs. desirable)
|
Linear regression (prediction of continuous levels of 25(OH)D)
|
|
OR
|
(95% CI)
|
p-value
|
Beta coef.
|
(95% CI)
|
p-value
|
|
Sex
|
|
Male
|
Reference
|
|
|
Reference
|
|
|
|
Female
|
1.29
|
(0.88 to 1.90)
|
0.20
|
0.41
|
(–3.09 to 3.92)
|
0.82
|
|
Age (years)
|
0.93
|
(0.89 to 0.97)
|
<0.001
|
0.85
|
(0.52 to 1.18)
|
<0.001
|
|
BMI z-scores WHO
|
0.77
|
(0.60 to 1.00)
|
0.046
|
3.04
|
(0.83 to 5.24)
|
0.007
|
|
Vitamin D supplementation
|
|
No
|
Reference
|
|
|
Reference
|
|
|
|
Yes
|
0.66
|
(0.43 to 0.99)
|
0.045
|
5.12
|
(1.39 to 8.85)
|
0.007
|
|
Skin color
|
|
Light, very light
|
Reference
|
|
|
Reference
|
|
|
|
Brown, black
|
0.85
|
(0.55 to 1.32)
|
0.48
|
–0.80
|
(–4.63 to 3.04)
|
0.68
|
|
Sunscreen use
|
|
0% to 25%
|
Reference
|
|
|
Reference
|
|
|
|
50% to 100%
|
0.85
|
(0.58 to 1.25)
|
0.41
|
1.04
|
(–2.42 to 4.50)
|
0.55
|
|
Training hours (week)
|
1.01
|
(0.97 to 1.04)
|
0.68
|
0.15
|
(–0.15 to 0.44)
|
0.33
|
|
Location of sport
|
|
Indoor sports
|
Reference
|
|
|
Reference
|
|
|
|
Outdoor sports
|
0.53
|
(0.34 to 0.82)
|
0.004
|
5.38
|
(1.55 to 9.20)
|
0.006
|
|
Season
|
|
Summer
|
Reference
|
|
|
Reference
|
|
|
|
Fall
|
4.78
|
(2.49 to 9.19)
|
<0.001
|
–16.91
|
(–22.20 to –11.61)
|
<0.001
|
|
Winter
|
11.49
|
(5.68 to 23.23)
|
<0.001
|
–28.58
|
(–34.28 to –22.89)
|
<0.001
|
|
Spring
|
6.59
|
(3.45 to 12.57)
|
<0.001
|
–19.71
|
(–24.91 to –14.52)
|
<0.001
|
Discussion
This cross-sectional study in a large cohort of Swiss athletes demonstrated that one
in two Swiss athletes showed insufficient 25(OH)D below 75 nmol/L, potentially compromising
health and athletic performance. Lower age, lower BMI and the seasons fall, winter
and spring showed to be risk factors for insufficient 25(OH)D concentrations, whereas
vitamin D supplementation and outdoor sports were positively related to 25(OH)D concentrations.
Sex, skin colour, sun cream use and training hours did not significantly predict 25(OH)D
levels.
Prevalence insufficient 25(OH)D concentrations
The prevalence of insufficient 25(OH)D of approximately 51% shown in this study was
comparable to previous research in athletes (56%) and somewhat lower than in the general
population (64–70%) [6]
[14]
[37]. This is not surprising because 25(OH)D levels can be influenced by many factors.
These include age, BMI, ethnicity, different skin types, sun protection approaches
(e. g. sunscreen use, clothing), latitude of residence, and seasonal variation determining
the extent of sun exposure, as well as dietary intake and supplementation [14]
[26]
[31]. Irrespective of personal and environmental factors, 25(OH)D measurement approaches
are subject to high variability which may result in different prevalence estimates
of insufficient 25(OH)D concentrations ranging from 8 to 42% [50].
Season
In this study, season was the strongest predictor of 25(OH)D concentrations with the
sun-deprived seasons of fall, winter and spring as compared to summer as the strongest
risk factors for insufficient 25(OH)D concentrations. This finding is consistent among
studies [14]
[35] as during these seasons, the zenith angle to the earth is too shallow (<45°) to
induce any vitamin D production in the skin [32]. Moreover, colder temperatures during these sun-deprived seasons requires proper
clothing that covers the skin completely and prevents any natural production of vitamin
D.
Age and sex
Higher age was associated with lower odds of insufficiency and therefore higher 25(OH)D
concentrations. This was not expected based on epidemiological data [30] because 25(OH)D production in the skin becomes less efficient with increasing age
due to a lower 7-dehydrocholesterol content in the epidermal layer of the skin [33]. We doubt that this mechanism played a relevant role in our rather young population,
because the decrease in vitamin D production efficiency seems to be especially prominent
at an older age [13]
[33]. Yet, the rising awareness of the carcinogenic effect of UV radiation over the last
several decades may have led to preventive strategies with the avoidance of sun exposure
and the unconditional use of sun cream [40]. The younger athletes might have been more aware of this, potentially due to the
influence of their health-conscious parents.
The influence of sex on 25(OH)D concentrations is controversial. Some authors found
lower 25(OH)D concentrations in females, whereas others found the opposite pattern
[30]
[37]
[39]
[61]. In this study, a higher prevalence of insufficient 25(OH)D concentrations was found
in females (compared to males), which is likely explained by other factors such as
different body mass, fat percentage or time spent in the sun. It is not surprising,
however, that the gender difference disappeared after adjusting for all other variables
in the models.
BMI, skin colour & sunscreen use
Several studies suggest an inverse relation between BMI, fat mass and vitamin D concentrations
[24]
[49] because body fat serves as 25(OH)D storage and reduces its release [46]. We found weak evidence for the opposite scenario with a small but consistent positive
association between BMI (z-scores) and 25(OH)D concentrations. In athletes, a higher
BMI is generally not a marker of higher body fat, but rather of increased muscle mass.
It is known that 25(OH)D plays an important role in muscle function such as induction
of myogenic transcription, cell proliferation and differentiation, and suppression
of myostatin. Therefore, higher muscle mass, expressed in our study as a higher BMI,
possibly goes along with higher 25(OH)D [1]
[29]. Another explanation for this positive relation in athletes could be the lower intake
of dietary vitamin D in athletes with a lower BMI. A low dietary and therefore 25(OH)D
intake and even eating disorders are common among sports athletes where low body weight
might be an advantage such as in aesthetic or endurance sports [53]. But, whether and how much deficient dietary intakes play a role is still controversial.
For instance, an investigation of a large cohort identified that less than 2% of individuals
studied met dietary intake requirements (RDA) for vitamin D, which questions the relevance
of nutrition in the prevention of vitamin D deficiency [25].
Darker skin colour (more melanin) and frequent sunscreen use are relevant barriers
of 25(OH)D production and therefore associated with a lower production of pre-vitamin
D in the skin and consequently lower circulating 25(OH)D concentrations [8]
[9]
[27]
[36]. Surprisingly, both factors were not found to be significant predictors of insufficient
25(OH)D concentrations in our statistical models, which may be partly explained by
the lack of measurement precision (questionnaire data).
Vitamin D supplementation
Levy, McKinnon, Barker, et al. [31] found that vitamin D supplementation in a general population was the strongest positive
predictor of circulating 25(OH)D concentrations. Although vitamin D supplementation
was associated with a 5 nmol/L higher 25(OH)D concentration compared to the not supplemented
group, this difference is surprisingly small. This can be explained partly by the
variation in supplemental dose of vitamin D. The majority of athletes in our study
reported taking supplemental vitamin D, mostly in the form of a multivitamin supplements.
Due to the imprecise recall of the exact name of the supplements by the athletes,
the supplementation dosage could not be specified exactly, although most multi-vitamin
supplements contain 400 IU of vitamin D [26] and may not be sufficient to reach the recommended daily allowance (RDA) levels
of 600–800 IU/day [12]
[27]
[47]. Heaney [21] found that, depending on the baseline 25(OH)D, an increase between 6 nmol/L (2.4 ng/ml)
and 10 nmol/L (4 ng/ml) is expected with supplementation of 400 IU/day, which is close
to our estimate. In addition, poor compliance in taking supplements or even medications
(approximately 50% in other populations) may have contributed to the apparently low
vitamin D concentrations despite supplementation [5]
[66].
Indoor sports and training hours
Several studies have shown that athletes performing indoor sports rather than outdoor
sports are more susceptible to 25(OH)D insufficiency, suggesting a difference in sun
exposure [14]
[35]
[44]. In support of this belief, seasonal variations in 25(OH)D have been well described
in the literature with consistently lower 25(OH)D concentrations in fall and winter
than in summer [14]
[27]
[35]
[42]. We included training hours per week as a possible correlate of 25(OH)D concentrations
as a possible proxy variable for hours of sun exposure. We found higher training hours
in the optimal 25(OH)D group in the descriptive analysis, but this effect disappeared
after adjusting for other predictive variables. Therefore, training hours do not seem
to be a good proxy for sun exposure, because it highly depends on time and location
of training as well as skin protection provided by sunscreen and clothing.
Recommendation and supplementation
Based on the literature, target concentrations of 75 nmol/L 25(OH)D may be recommended
for athletes to improve performance and regeneration [43] or to offer immunological benefits to prevent acute infection [20]. This target concentration is further supported by benefits to bone health which
is an important value especially for younger athletes who may still be growing [4]
[11]
[23]
[26]
[27]. Because the prevalence of insufficient 25(OH)D concentrations in this study was
high, supplementation in athletes may be indicated, except perhaps in the summer months
[20]. The intake of at least 600 IU/day vitamin D3 for children and adults is recommended
by different authorities (e. g. Endocrine Society, Institute of Medicine) [12]
[27]
[47]. However, to reach 25(OH)D levels of ≥75 nmol/L, higher dosages may be needed [12]
[27]
[47]
[58]. Daily vitamin D3 supplementation at a dosage between 600 and 1000 IU is generally
recommended and considered safe by different authorities [12]
[22]
[27]
[47]. Under strict sunlight safety recommendations in summer (e. g. short regular exposure
under strict avoidance of sunburn, application of sun cream after about 15 min of
exposure) [59]
[60], supplementation may be replaced by about 15 min of sun exposure (covered with a
T-shirt and shorts) on most days. This allows obtaining desirable vitamin D concentrations
of ≥75 nmol/L in a majority of supplemented populations [45]
[60]. For those at high risk of sunburn, those who train mostly indoors or wear skin
covering/clothing [18], and/or those who fear an increased risk of skin cancer, supplementation can safely
be taken throughout the year [22].
Study strength and limitations
The major strength of this study is the inclusion of a large and variable sample of
competitive athletes in Switzerland. 25(OH)D was uniformly assessed by one central
and certified quality laboratory that used the gold standard assay of liquid chromatography–mass
spectrometry to determine serum concentrations of 25(OH)D [50]. Multiple imputation was used to account for item non-response in the statistical
analysis to increase precision and lower the probability of selection bias [52]. Limitations are related to the cross-sectional design precluding causality and
the possibility of a selection bias that may have been induced by unit non-response.
Moreover, we used questionnaire data to assess demographics and some risk factors
prone to different types of bias. Unfortunately, the inclusion of objective measures
such as body composition including fat, muscle and bone mass (e. g. by dual X-ray
absorptiometry), aerobic endurance or muscle function, or immunological markers was
not possible.
Conclusion
Insufficient 25(OH)D concentrations that potentially hinder health and sport performance
are prevalent among athletes, especially during the sun-deprived seasons. Furthermore,
those of younger age and with lower BMI, those who participate primarily in indoor
sports and do not take vitamin D supplements were at a higher risk for 25(OH)D insufficiency.
Vitamin D intake and sun exposure recommendations for athletes should be individually
determined taking the aforementioned risk factors into account. Considering the uncertainty
of compliance regarding vitamin D supplementation, further studies should evaluate
whether commercial multi-vitamin supplements that normally contain 400 IU of vitamin
D are sufficient to maintain desirable vitamin D levels. Further research is required
to establish the range of 25(OH)D concentrations associated with optimal health and
performance in athletes, whether the optimal range differs according to age, type
and location of sport performed, and which supplementation doses are needed to reach
these optimal 25(OH)D concentrations.
