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Vitamin D deficiency is a problem for adult out-patients? A university hospital sample in Istanbul, Turkey

Published online by Cambridge University Press:  09 August 2012

Ozlem Cigerli*
Affiliation:
Faculty of Medicine, Department of Family Medicine, Baskent University, Ankara, Turkey
Hulya Parildar
Affiliation:
Faculty of Medicine, Department of Family Medicine, Baskent University, Ankara, Turkey
Aslı D Unal
Affiliation:
Faculty of Medicine, Department of Endocrinology, Baskent University, Ankara, Turkey
Ozlem Tarcin
Affiliation:
Faculty of Medicine, Department of Endocrinology, Baskent University, Ankara, Turkey
Rengin Erdal
Affiliation:
Faculty of Medicine, Department of Family Medicine, Baskent University, Ankara, Turkey
Nilgun Guvener Demirag
Affiliation:
Faculty of Medicine, Department of Endocrinology, Baskent University, Ankara, Turkey
*
*Corresponding author: Email ozlemcigerli@gmail.com
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Abstract

Objective

To investigate the frequency of vitamin D deficiency in relation to demographics, clinical diagnosis, season of measurement and laboratory parameters in adult out-patients.

Design

Descriptive, retrospective study concerning evaluation of the initial 25-hydroxyvitamin D (25(OH)D) levels determined at admission in relation to demographics, clinical diagnosis, season of measurement and laboratory parameters. 25(OH)D levels <20 ng/ml were classified as deficiency, 20–30 ng/ml as insufficiency and >30 ng/ml as sufficiency.

Setting

Out-patient clinics at a tertiary care centre.

Subjects

A total of 2488 adult patients (mean age: 53·3 (sd 15·2) years; 85·2 % were females) admitted to out-patient clinics at Baskent University Istanbul Hospital were included.

Results

Mean level of 25(OH)D in the overall population was 17·4 (sd 11·5) ng/ml while insufficiency and deficiency were evident in 24 % and 66 % of patients, respectively. Mean 25(OH)D levels in males >45 years old were higher than in their female counterparts (19·4 (sd 11·3) ng/ml v. 17·8 (sd 12·2) ng/ml; P < 0·05). Mean 25(OH)D levels obtained in summer (18·6 (sd 11·1) ng/ml) and autumn (23·3 (sd 13·6) ng/ml) were significantly higher than levels in spring (16·1 (sd 10·3) ng/ml) and winter (14·6 (sd 10·2) ng/ml; P < 0·01). Mean 25(OH)D levels were determined to be significantly lower in obese patients compared with non-obese patients (15·6 (sd 10·4) ng/ml v. 17·6 (sd 11·6) ng/ml; P < 0·05). Levels of 25(OH)D were significantly negatively correlated with serum parathyroid hormone levels (r = −0·194; P < 0·001) while significantly positively correlated with phosphorus (r = 0·059; P < 0·01) and HDL cholesterol (r = 0·070; P < 0·01) levels.

Conclusions

Our findings indicate that vitamin D deficiency is very common among out-patients in Turkey, regardless of gender and age, especially among obese people and during winter and spring.

Type
Nutrition and health
Copyright
Copyright © The Authors 2012 

Owing to renewed scientific interest in vitamin D in relation to newly described benefits extending beyond healthy bones, several studies concerning the effects of vitamin D in many varying clinical conditions have been published in the previous decade(Reference Thacher and Clarke1).

Either synthesized in the form of vitamin D3 (cholecalciferol) under the influence of solar UV-B radiation in the epidermis or absorbed from the diet or from supplements and food additives, which in some countries may contain vitamin D2 (ergocalciferol), vitamin D is transferred to the liver, where it is metabolized to 25-hydroxyvitamin D (25(OH)D)(Reference Peterlik, Boonen and Cross2). Since it denotes the sum of 25(OH)D3 and 25(OH)D2, the plasma level of this metabolite has been considered as the most stable, plentiful and reliable indicator of an individual's vitamin D status(Reference Peterlik, Boonen and Cross2), reflecting the sum of vitamin D from endogenous synthesis and from dietary intake(Reference Thacher and Clarke1).

Hypovitaminosis D is a global problem, prevalent across both genders and all age groups, even in sunny countries(Reference Mithal, Wahl and Bonjour3). Using 25(OH)D cut-off values of 20 ng/ml to define deficiency and 30 ng/ml to define insufficiency in adults, it is estimated that one billion individuals have vitamin D insufficiency or deficiency worldwide(Reference Holick4, Reference Arabi, Baddoura and El-Rassi5). There is growing evidence that vitamin D sufficiency is required for optimal health in general, and musculoskeletal health in particular(Reference Arabi, Baddoura and El-Rassi5, Reference Bordelon, Ghetu and Langan6).

In this respect, once thought to be primarily a determinant of bone health, it is now recognized that vitamin D is a requisite hormone involved in a myriad of physiological processes including immune modulation, genetic regulation, hormone production and cellular functioning throughout the life cycle(Reference Peterlik, Boonen and Cross2, Reference Genuis, Schwalfenberg and Hiltz7).

Indeed, the requirement for vitamin D in a wide variety of essential biological functions such as bone and mineral metabolism, muscle function and immunity(Reference Orwoll, Nielson and Marshall8) explains why many chronic diseases including osteoporosis and fractures, falls, cancer, psoriasis, diabetes mellitus, obesity, hypertension, multiple sclerosis, rheumatoid arthritis, inflammatory bowel disease and sixteen different cancer types(Reference Holick4, Reference Holick9, Reference Cantorna10) show significant negative associations with serum 25(OH)D as has been noted in a variety of populations(Reference Orwoll, Nielson and Marshall8).

Vitamin D deficiency is of particular interest because it is easily, safely and inexpensively corrected with adequate supplementation. Although findings have been somewhat inconsistent, trials of the effects of vitamin D supplementation suggest beneficial effects on important clinical outcomes(Reference Orwoll, Nielson and Marshall8). As a result, increased attention has been directed at improving vitamin D nutrition, including recent recommendations to increase the routine intake of vitamin D(Reference Bischoff-Ferrari11).

The present retrospective study was designed to investigate the prevalence of vitamin D deficiency in relation to patient demographics, clinical diagnosis, season of measurement and laboratory parameters, including levels of fasting blood glucose, glycated Hb (HbA1c), insulin, creatinine, Ca, phosphorus, LDL cholesterol (LDL-C), HDL cholesterol (HDL-C), TAG, high-sensitivity C-reactive protein (hsCRP) and parathyroid hormone (PTH), in Turkish adult out-patients.

Methods

A total of 2488 adult patients (mean age: 53·3 (sd 15·2) years; 85·2 % were females) who were admitted to out-patient clinics at Baskent University Istanbul Hospital (total number of new patient admissions was 313 779) from March 2009 to March 2011 were included in the present descriptive, retrospective study. Patients receiving therapeutic or prophylactic vitamin D supplement therapy were included in the study, while patients having a diagnosis of chronic renal failure or chronic liver failure and older than 75 years of age were excluded.

The initial 25(OH)D levels determined at admission were evaluated in relation to patient demographics, clinical diagnosis (according to the International Classification of Diseases, 10th revision), season of measurement and laboratory parameters including levels of fasting blood glucose (mg/dl), HbA1c ( %), insulin (μI/ml), creatinine (mg/dl), Ca (mg/dl), phosphorus (mg/dl), LDL-C (mg/dl), HDL-C (mg/dl), TAG (mg/dl), hsCRP (mg/l) and PTH (pg/ml). Obesity was diagnosed by the clinician based on WHO criteria, which noted according to the International Classification of Diseases, 10th revision, with consideration of obese and overweight patients under the ‘obese’ class as indicated by BMI values(12). Serum 25(OH)D levels <20 ng/ml were classified as deficiency, 20–30 ng/ml as insufficiency and >30 ng/ml as sufficiency(Reference Holick4).

Assay of vitamin D and other laboratory parameters

All instruments and kits were from Abbott Laboratories, Abbott Park, IL, USA. Serum 25(OH)D levels were measured with a chemiluminescent immunoassay method (Architect i1000 system); normal ranges were 15·7–60·3 ng/ml (summer) and 8·8–46·3 ng/ml (winter); and the intra-assay CV ranged from 2·6 to 4·0 %. Insulin levels were analysed by chemiluminescent immunoassay (Architect i1000 system); normal range 2·6–24·9 μU/ml; intra-assay CV 2·3–4·2 %. Serum PTH levels were measured with an electrochemiluminescent immunoassay method (Architect i2000 system); normal range 15–68 pg/ml; intra-assay CV 3·0–6·5 %. Levels of hsCRP were measured with an immunoturbidimetric assay (C8000 system); normal level <0·5 mg/dl; intra- and inter-assay CV 0·65–4·00 % and 0·26–2·38 %, respectively. Serum Ca and phosphorus levels were measured with an enzymatic colorimetric assay (C8000 system); intra- and inter-assay CV were respectively 0·5–0·6 % and 0·3–0·5 % for Ca, 0·5–0·5 % and 0·3–0·6 % for phosphorus. Serum glucose levels were measured by enzymatic colorimetric assay (C8000 system); intra- and inter-assay CV were 0·65–1·98 % and 0·84–0·93 %, respectively. HbA1c was detected with a turbidimetric assay method (C4000, Architect cSystem); intra- and inter-assay CV were 0·77–0·88 % and 1·45–1·88 %, respectively. Serum total cholesterol, TAG, HDL-C, LDL-C, creatinine, aspartate aminotransferase and alanine aminotransferase were measured by enzymatic colorimetric assay (C8000 system); the within-run and between-run CV were, respectively, 1·1–1·4 % and 1·92–2·2 % for TAG, 0·4–1·1 % and 0·2–0·8 % for aspartate aminotransferase, 0·5–1·5 % and 0·7–1·3 % for alanine aminotransferase; intra-assay and inter-assay CV were 1·0–1·7 % and 0·5–1·1 %, respectively, for HDL-C.

Ethical approval

The study was approved by Baskent University Institutional Review Board (project no. KA11/167). The study protocol was approved by the institutional ethics committee of the Baskent University Faculty of Medicine.

Statistical analysis

Statistical analysis was conducted using the SPSS statistical software package version 16·0 (SPSS Inc.). Student's t test and one-way ANOVA were used for the comparison of parametric variables. Pearson correlation analysis was performed to reveal the relationship of 25(OH)D levels with laboratory parameters. Data are expressed as mean and standard deviation or as number and percentage where appropriate. P < 0·05 was considered statistically significant.

Results

Mean age of the patients was 53·3 (sd 15·2) years. The percentage of female and male patients was 85·2 % (n 2131) and 14·9 % (n 373), respectively. Female (53·3 (sd 15·2) years) and male (53·4 (sd 15·7) years) patients were homogeneous in terms of mean age. Clinical diagnoses at initial admission are listed in Table 1.

Table 1 Clinical diagnoses at initial admission among adult out-patients (n 2488), Istanbul, Turkey, March 2009–March 2011

Mean level of 25(OH)D in the overall study population was 17·4 (sd 11·5) ng/ml. There was no gender influence on 25(OH)D levels in the overall population and in patients <45 years of age; but, when patients ≥45 years of age were considered, mean 25(OH)D levels were determined to be significantly higher in male patients than females (P < 0·05; Table 2).

Table 2 Mean serum 25-hyroxyvitamin D (25(OH)D; ng/ml) in the study population according to gender, age and season of measurement: adult out-patients (n 2488), Istanbul, Turkey, March 2009–March 2011

Mean values were significantly different from those of male patients aged ≥45 years: *P < 0·05.

Mean values were significantly different from those obtained during summer and autumn months: **P < 0·01.

Season of 25(OH)D measurement is presented in Table 2. When mean 25(OH)D levels were compared with respect to the season of measurement, it was determined that levels obtained in summer and autumn were significantly higher than those in spring and winter (P < 0·01; Table 2 and Fig. 1).

Fig. 1 Serum 25-hyroxyvitamin D (25(OH)D) level according to month/season ( $$$$ , winter months; $$$$ , spring months; $$$$ , summer months; $$$$ , autumn months) among adult out-patients (n 2488), Istanbul, Turkey, March 2009–March 2011. Values are means with standard deviations represented by vertical bars

The distribution of the patients according to vitamin D status that is sufficient, insufficient and deficient in the overall study population and in age groups of <45 and ≥45 years is shown in Table 3. Sufficient vitamin D levels were determined only in 9·8 % (n 243) of patients. When evaluated according to age group, the prevalence of vitamin D deficiency was found to be significantly lower in patients aged <45 years than in those aged ≥45 years (P < 0·05; Table 3).

Table 3 Mean serum 25-hyroxyvitamin D (25(OH)D) levels and classification of vitamin D status (sufficiency, insufficiency, deficiency) in the study population according to age: adult out-patients (n 2488), Istanbul, Turkey, March 2009–March 2011

Mean values were significantly different from those of patients aged ≥45 years: *P < 0·05, **P < 0·001.

When patients who have obesity were considered, their mean 25(OH)D levels were determined to be significantly lower than in non-obese patients (15·6 (sd 10·4) ng/ml v. 17·6 (sd 11·6) ng/ml; P < 0·05).

The association between serum 25(OH)D and PTH concentrations in a non-linear regression model revealed that 25(OH)D concentration of 30 ng/ml is needed to keep PTH concentration low (Fig. 2).

Fig. 2 The association between serum 25-hyroxyvitamin D (25(OH)D) and parathyroid hormone (PTH) concentrations in adult out-patients (n 2488), Istanbul, Turkey, March 2009–March 2011. Non-linear regression model with vitamin D as dependent variable and PTH as independent variable ( $$$$ , observed; ——, logarithmic fit; – · – · –, 25(OH)D concentration needed to keep PTH concentration low). Model summary: R 2 = 0·047, F = 77·185, df1 = 1, df2 = 1579, P = 0·000; parameter estimates: constant = 36·490, b 1 = –4·680

Levels of 25(OH)D (ng/ml) were significantly negatively correlated to serum PTH levels (r = −0·194; P < 0·001) while significantly positively correlated to phosphorus (r = 0·059; P < 0·01) and HDL-C (r = 0·070; P < 0·01) levels (Table 4).

Table 4 Correlation between serum 25(OH)D and biochemical parameters among adult out-patients (n 2488), Istanbul, Turkey, March 2009–March 2011

25(OH)D, 25-hdroxyvitamin D; PTH, parathyroid hormone; LDL-C, LDL cholesterol; HDL-C, HDL cholesterol; hsCRP, high-sensitivity C-reactive protein; HbA1c, glycated Hb; FBG, fasting blood glucose.

Discussion

Since the major stimulus for PTH secretion is a low level of serum ionized Ca, the 25(OH)D level that maximally suppresses PTH secretion is considered the functional definition of sufficient vitamin D status. Therefore the rationale behind the selection of 30 ng/ml as the cut-off value for defining vitamin D sufficiency is the data from multiple cross-sectional examinations concerning the plateau in suppression of PTH when 25(OH)D level reaches approximately 30 ng/ml(Reference Thacher and Clarke1).

In this respect, similar to what is reported in other studies and confirming that vitamin D deficiency is widespread(Reference Orwoll, Nielson and Marshall8), hypovitaminosis D was identified to be very common in our study population. Identification of vitamin D deficiency at concentrations associated with severe consequences(Reference Holick4) in 66 % of our study population is notable, especially when the corresponding rates of deficiency reported in the adult population in Europe (7–27 %), South-East Asia, Australia (8–17 %) and the USA (5 %) are considered(Reference Peterlik, Boonen and Cross2). Likewise, mean serum 25(OH)D levels in our male (18·1 ng/ml; 45·18 nmol/l) and female (17·3 ng/ml; 43·43 nmol/l) patients were lower than overall mean data from the latest US National Health and Nutrition Examination Survey (62·9 nmol/l in men; 61·5 nmol/l in women) and most European studies (53·8 nmol/l in men; 51·5 nmol/l in women)(Reference Looker, Pfeiffer and Lacher13Reference Brock, Huang and Fraser15).

Besides, while our observation that 25(OH)D serum levels were higher in summer and autumn than in winter and spring is consistent with previous studies(Reference Brock, Huang and Fraser15Reference Hagenau, Vest and Gissel17), vitamin D status identified even in summer and autumn months was still below the optimum in our population. Likewise, similarly, in another study conducted in Turkey, evaluation of 472 patients including osteopenia and osteoporosis patients (84·7 %) and controls (15·3 %) revealed hypovitaminosis D (<20 ng/ml) in 52·8 % of osteoporosis patients and in 51·6 % of the control group; and indicated that while lowest values of serum vitamin D were obtained in March and highest values in September, overall values were still below the levels reported in other countries(Reference Yanik, Geler and Gok18).

Although some studies have shown higher vitamin D and lower PTH levels in men compared with women throughout the year, this finding was not reported consistently in all studies(Reference Arabi, Baddoura and El-Rassi5). Accordingly, while there was no gender influence on 25(OH)D levels in the overall population in our study, unlike reported lower values in females than males in the general population(16), identification of lower 25(OH)D levels in female patients older than 45 years of age seems to support the reported tendency of women to have lower values in elderly populations(Reference Brock, Huang and Fraser15).

Moreover, persons with low vitamin D levels were reported to be older(Reference Ramel, Jonsson and Bjornsson19), more likely to be women, to have higher BMI and less sun exposure, while BMI and female sex were reported to be independently associated with vitamin D insufficiency in the literature(Reference Ding, Cicuttini and Parameswaran20).

Although 25(OH)D levels were reported to be lower in elderly people based on diminished cutaneous production of vitamin D with ageing, lower sun exposure due to spending little time outdoors and lower Ca intake in the elderly(Reference Arabi, Baddoura and El-Rassi5), the frequency of vitamin D deficiency was identified to be much higher in younger patients than in patients aged ≥45 years in our study population, which might be related to more common use of vitamin D supplements in the elderly. Interestingly, supporting the significantly lower 25(OH)D levels in our elderly but not younger female patients when compared with males, the age-related fall in vitamin D level was previously reported not to be the same in both genders and suggested to occur at a younger age in women than men(Reference Arabi, Baddoura and El-Rassi5, Reference Maggio, Cherubini and Lauretani21).

While strong seasonal variation in serum 25(OH)D with a marked downward shift during the winter months has been reported consistently(Reference Pedersen22), identification of vitamin D deficiency even in the summer months in our country – which has, in most of its geographic regions, sufficient sunshine to maintain adequate vitamin D status by dermal synthesis(Reference Ergür, Berberoğlu and Atasay23Reference Atli, Gullu and Uysal25) – seems worth noting. In this vein, similar to studies indicating lower levels of vitamin D in females that mainly reflect lifestyle and dress style(Reference Arabi, Baddoura and El-Rassi5, Reference Salamoun, Kizirian and Tannous26, Reference Arabi, Baddoura and Awada27), most Turkish women of reproductive age were documented to lack benefit from this source because of their clothing habits(Reference Andiran, Yordam and Özon28).

The association of obesity with low 25(OH)D levels in our population is in line with the consistently reported negative correlation between vitamin D and fat mass in the literature. The inverse 25(OH)D and obesity relationship is explained by ‘trapping’ of the vitamin D parent compound, cholecalciferol, in adipose tissue(Reference Arabi, Baddoura and El-Rassi5, Reference Brock, Huang and Fraser15) as well as due to a difference in sunbathing habits between obese and lean persons while not confirmed in the elderly(Reference Harris and Dawson-Hughes29, Reference Kull, Kallikorm and Lember30).

The significant correlation of 25(OH)D with HDL-C (positively) and PTH (negatively) levels in our population is important with respect to the consistently reported relationship of vitamin D and its insufficiencies with greater mortality from chronic CVD(Reference Peterlik, Boonen and Cross2), higher incidence of cardiovascular risk factors such as hypertension, obesity, metabolic syndrome and diabetes mellitus type 2(Reference Peterlik, Boonen and Cross2) and higher risk for incident cardiovascular symptoms including angina, coronary insufficiency, myocardial infarction, transient ischaemic attack and stroke(Reference Peterlik, Boonen and Cross2).

Over the last few years, discussions have focused on determining desirable serum 25(OH)D levels to optimize bone health, using various surrogate markers of vitamin D status, including the relationship between serum 25(OH)D and PTH levels(Reference Arabi, Baddoura and El-Rassi5). In this regard, the negative correlation of PTH levels to vitamin D levels in our study is consistent with data on the inverse relationship between serum 25(OH)D and PTH levels in other countries(Reference Arabi, Baddoura and El-Rassi5) as well as a previous study conducted in Turkey with osteopenia and osteoporosis patients(Reference Yanik, Geler and Gok18), while this well-described association was reported to vary across studies and populations(Reference Arabi, Baddoura and El-Rassi5).

High prevalence of hypovitaminosis D in our population despite inclusion of patients receiving vitamin D supplements supports the statement that the prevalence of vitamin D deficiency remains high even in supplement users, leading 39·6 % of supplement users to be vitamin D deficient (<20 ng/ml)(Reference Orwoll, Nielson and Marshall8). In fact, in correlation to the previously reported(Reference Holick, Biancuzzo and Chen31) increase in circulating 25(OH)D level of only 1 ng/ml for every 2·5 μg (100 IU) of vitamin D2 or vitamin D3 ingested, our results strengthen the impression(Reference Vieth, Bischoff-Ferrari and Boucher32) that commonly used supplement doses are inadequate to ensure vitamin D nutrition(Reference Orwoll, Nielson and Marshall8).

As a matter of fact, while factors including race, vitamin D intake, sun exposure, adiposity, age and physical activity are known to influence 25(OH)D levels, most of the individual variation of 25(OH)D values has been considered difficult to explain, even when all the factors known to influence 25(OH)D concentrations are taken into account(Reference Thacher and Clarke1). Consequently, the duration of vitamin D insufficiency, the responsiveness of the vitamin D receptor, dietary Ca intake, and individual Ca requirements and absorption capacity of the intestines were reported to likely modify the clinical consequences of vitamin D deficiency or insufficiency, which seems difficult to assess on the basis of concentrations of 25(OH)D alone(Reference Thacher and Clarke1).

Nevertheless, while direct comparison of studies on vitamin D intake in different parts of the world has been considered difficult due to differences in lifestyle and clothing habits, consumption of traditional foods or supplement intake, combined evidence from all studies clearly indicates that vitamin D insufficiency and Ca malnutrition are common in both genders worldwide, not only in elderly people as previously believed but also in younger adults(Reference Peterlik, Boonen and Cross2, Reference Bolek-Berquist, Elliott and Gangnon33).

Besides, based on an increasing incidence of CVD, diabetes, metabolic syndrome and cancer rates in the general population, it seems reasonable to speculate on the relationship among these conditions and the seemingly prevalent finding of vitamin D deficiency in most of countries(Reference Scragg34, Reference Johal and Levin35). In this respect, consideration of simple and low-cost measures that have the potential to address the problem of vitamin D inadequacy, including food sources such as fatty fish and fortified foods, skin exposure to UV-B from the sun or artificial light sources and vitamin D supplementation, seems crucial(Reference Genuis, Schwalfenberg and Hiltz7).

The main limitation of the present study is the inclusion of out-patients suffering from certain diseases likely to indicate vitamin D status differing from the general population. Second, our findings must be cautiously interpreted based on the lack of supporting variables related to outcome of vitamin D deficiency, such as bone markers or bone parameters, in our study population.

Conclusions

Our findings indicate vitamin D deficiency to be very common in women and men out-patients living in Istanbul, regardless of age, especially among the obese and during the winter and spring. Identification of vitamin D sufficiency in only 10 % of our population as well as determination of insufficiency even in younger persons and in the summer months seem to emphasize the great risk posed by a myriad of health problems based on the consideration of vitamin D deficiency as a long-standing condition, rather than a recent occurrence(Reference Orwoll, Nielson and Marshall8). In this regard, the enormous opportunity to improve individual and public health by identification and appropriate correction of vitamin D status in individuals and populations, beginning from pregnancy and/or early childhood, must be taken into consideration by the medical community. Future studies concerning vitamin D insufficiency in relation to the potential multitude of health sequelae in the general population are required to establish population means and definitions of deficiencies, as well as to translate the need for change evident from emerging research into day-to-day clinical implementation.

Acknowledgements

Source of funding: This research received no specific grant from any funding agency in the public, commercial or not-for-profit sectors. Conflicts of interest: The authors declare that they have no conflict of interest. Authors’ contributions: O.C. designed the study, worked in all stages of data collection and analysis. H.P. and A.D.U. made substantial contributions to conception and design. R.E. and N.G.D. made substantial contributions to performing the statistical analysis. All authors read and approved the final manuscript. Acknowledgements: The authors would like to thank Dr Feyza Dinc and Dr Hacer Eroglu, Lab Specialists of the Department of Biochemistry, for helpful evaluations and discussions of the biochemical results.

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Figure 0

Table 1 Clinical diagnoses at initial admission among adult out-patients (n 2488), Istanbul, Turkey, March 2009–March 2011

Figure 1

Table 2 Mean serum 25-hyroxyvitamin D (25(OH)D; ng/ml) in the study population according to gender, age and season of measurement: adult out-patients (n 2488), Istanbul, Turkey, March 2009–March 2011

Figure 2

Fig. 1 Serum 25-hyroxyvitamin D (25(OH)D) level according to month/season ($$$$, winter months; $$$$, spring months; $$$$, summer months; $$$$, autumn months) among adult out-patients (n 2488), Istanbul, Turkey, March 2009–March 2011. Values are means with standard deviations represented by vertical bars

Figure 3

Table 3 Mean serum 25-hyroxyvitamin D (25(OH)D) levels and classification of vitamin D status (sufficiency, insufficiency, deficiency) in the study population according to age: adult out-patients (n 2488), Istanbul, Turkey, March 2009–March 2011

Figure 4

Fig. 2 The association between serum 25-hyroxyvitamin D (25(OH)D) and parathyroid hormone (PTH) concentrations in adult out-patients (n 2488), Istanbul, Turkey, March 2009–March 2011. Non-linear regression model with vitamin D as dependent variable and PTH as independent variable ($$$$, observed; ——, logarithmic fit; – · – · –, 25(OH)D concentration needed to keep PTH concentration low). Model summary: R2 = 0·047, F = 77·185, df1 = 1, df2 = 1579, P = 0·000; parameter estimates: constant = 36·490, b1 = –4·680

Figure 5

Table 4 Correlation between serum 25(OH)D and biochemical parameters among adult out-patients (n 2488), Istanbul, Turkey, March 2009–March 2011