ABSTRACT
Aim:
Accumulating knowledge suggests that low 25-hydroxyvitamin D3 concentrations may be inversely related to diabetes mellitus and insulin resistance. We planned to investigate the association of 25-hydroxyvitamin D3 levels with some antropometric and metabolic data in type 2 diabetic patients.
Methods:
In our study including 101 patients with type 2 diabetes mellitus and 60 healthy controls, after making comparisons of 25-hydroxyvitamin D3 levels and other parameters of two groups, we made correlation analysis in our diabetic patients. Later, we grouped our patients according to their 25-hydroxyvitamin D3 levels and made comparisons.
Results:
We found significantly lower 25-hydroxyvitamin D3 levels in type 2 diabetic patients than in controls. In correlation analysis, 25-hydroxyvitamin D3 levels were found to be negatively correlated with insulin homeostasis model assessment index. When we grouped our diabetic patients according to 25-hydroxyvitamin D3 levels, no difference was demonstrated in any parameters.
Conclusion:
This study suggests that 25-hydroxyvitamin D3 levels are significantly low in type 2 diabetes mellitus. In patients with type 2 diabetes, once vitamin D deficiency exists, metabolic parameters do not worsen according to decreasing vitamin D levels. Since hypovitaminosis D also exists in non-diabetics, we recommend vitamin D supplementation in our population.
Introduction
Vitamin D affects various tissues besides bones, sun exposure and vitamin D intake determines its concentration (1). It has been demonstrated that vitamin D deficiency is associated with hypertension (2-4), type 1 (T1DM) and type 2 diabetes mellitus (T2DM) (5-11), metabolic syndrome (12-14), cardiovascular disease (15-17) and malignancy (18-20).
Serum concentration of 25-hydroxy vitamin D3(25(OH)D) is the best indicator of vitamin D status (21). Hypovitaminosis D is defined as serum 25(OH)D concentration <20ng/ml (22,23). The 25(OH)D concentration was lower in patients with T2DM, than in nondiabetic control subjects (17,24). It has been reported that insulin secretion is dependent upon vitamin D (25-27). It has also been reported that there is a positive correlation of vitamin D concentration with insulin sensitivity (28-30).
Keeping in mind the complex relationship of vitamin D with glucose metabolism, cardiovascular disease, metabolic syndrome and insulin resistance, we planned to seek the relationship of vitamin D with various parameters in diabetic patients.
Materyal and Methods
Patients
A total of 101 T2DM patients, aged between 30 and 80 years, were recruited from the outpatient clinic at Ankara Education and Research Hospital from January 2011 to February 2011. Sixty healthy age-matched individuals constituted the control group.
Subjects with a history of chronic renal disease and liver disease, skin disorders, malabsorption, inflammatory bowel disease or celiac disease, and those taking medications that may interfere with serum levels of 25(OH)D were excluded.
After detailed physical examination, body weight and height were measured in all subjects. Body mass index (BMI) was calculated as the weight in kilograms divided by the square of the height in meters (kg/m2).
Blood samples were withdrawn after a 12-hour overnight fast, at 08.30 a.m. for measuring fasting plasma glucose (FPG), HbA1c, fasting insulin (FI), serum total and HDL cholesterol (HDL-C), triglyceride (TG), creatinine, Ca, P, PTH, TSH, albumin and 25(OH)D levels.
An indirect measure of insulin resistance was calculated from the fasting plasma insulin (μunite/ml) x fasting plasma glucose (mmol/l) /22.5 formula as homeostasis model assessment (HOMA-IR).
This study was performed according to the principles of the Declaration of Helsinki 2008. The local ethics committee approved this study and all the subjects gave written informed consent.
Laboratory Methods
Plasma glucose, total cholesterol, TG, creatinine, Ca, P, albumin and HDL-C concentrations were determined by enzymocalorimetric spectrophotometric method using a Roche/Hitachi molecular PP autoanalyzer. Low-density lipoprotein cholesterol (LDL-C) was calculated by the Friedewald Formula (LDL=Total cholesterol - HDL - TG ÷ 5). Insulin was measured by means of DRG Diagnostics (DRG Instruments GmbH, Germany) ELISA kits and FI was measured by TOSOH G7 HPLC system. PTH and TSH were determined by chemiluminescence method using the Advia Centaur XP system.
For the measurements of 25(OH)D, Waters LC-MS/MS device liquid chromatography mass spectrometry was used. We classified 25(OH)D serum levels as follows: 1) <12 ng/mL, 2) 12-20 ng/mL and 3) ≥20 ng/mL.
Statistical Analysis
Calculations were performed using SPSS version 10.1. Student’s t-test was used to compare the groups in a parametric way (for data showing homogeneous dispersion) and the Mann-Whitney U test was used in a non-parametric way (for data showing non-homogeneous dispersion). Correlation between variables was calculated using Pearson’s correlation coefficient. Data are presented as mean±SD. A p value of less than 0.05 was considered statistically significant.
Results
This study included 101 patients with T2DM [61 females (61%) and 40 males (29%)’ yerine 61 females (61%) and 40 males (39%). All the demographic and laboratory findings in the groups were compared and are illustrated in Table 1. In T2DM patients BMI, FBG, HbA1c, FI, HOMA-IR, TG levels were significantly higher (p=<0.01) and 25(OH)D levels were significantly lower than in controls (p=<0.01).
When we made correlation analysis in diabetic patients, we found that 25OHD positively correlated with creatinine (p=<0.05, r=0.18) and negatively correlated with BMI (p=<0.001, r=-0.23), HbA1c (p=<0.05, r=-0.21), FI (p=<0.05, r=-0.01), HOMA-IR (p=<0.05, r=-0.20), and PTH levels (p=<0.05, r=-0.18).
Then we classified our diabetic patients according to their 25 (OH) D levels as follows: 1) <12, 2) 12-20 and 3) >20ng/ml (Table 2). We did not find any difference in serum 25 (OH) D levels between the patient subgroups.
Discussion
Vitamin D is produced in the body after sun exposure and is found in foods. In the body, two hydroxylased forms of vitamin D are present (21). There are three reasons why 25(OH)D is thought to be a good indicator of vitamin D state. First; 1,25 (OH) 2D has a shorter half life than 25 (OH) D, second; its plasma levels are closely related to PTH, Ca and P, and lastly, levels of 1,25 (OH) 2D do not decrease until vitamin D deficiency is serious (23).
Vitamin D affects cell growth, immune functions, neuromuscular functions and inflammation (21,23,32-33).There is also mounting interest in the role of vitamin D in the aetiology of T1DM (5-8) and T2DM (9-11) as well as metabolic syndrome (12-14).
In most (24,25,34-37), but not all (38-40), case-control studies, patients with T2DM are found to have lower serum 25(OH)D concentration compared with controls without diabetes. We also found lower levels of 25(OH)D in our diabetic patients, compared to that in controls, in concordance with most of the previous studies. Persons with diabetes are at risk for vitamin D insufficiency and deficiency. Reasons for this include diet, lack of sun exposure, obesity, lack of outdoor physical activity, renal impairment and genetic predisposition.
25(OH)D levels in the range of 30 to 60 ng/mL are considered normal (26). Vitamin D insufficiency has been defined as a 25(OH)D of 16-30 ng/mL (41). Vitamin D deficiency is generally defined as a 25(OH)D below 20 ng/mL(22,23). The National Health and Nutrition Examination Survey (NHANES) III used a slightly lower value which was <15 ng/mL(42). Whatever cutoff value was accepted, our patients’ vitamin D levels were significantly low.
The vitamin D levels of our patients were found to be deficient, however, it must be noted that the 25(OH)D levels of our controls were also very low, as it was also determined in another study made in Ankara (43). In the literature, only in a few studies so low 25(OH)D levels were encountered both in patient and control groups (44,45). It was interesting that Al-Daghri et al. (46) found that severe hypovitaminosis D was prevalent in both non-diabetic and diabetics in Saudi adults, but was more common in young and middle aged non-diabetics. Several explanations are possible to describe the reason for very low vitamin D levels both in patient and control subjects. First, the season we have performed our study may affect the vitamin D levels; we made the study during the winter. Second, in our small group of Turkish population, genetic variations must be considered. Third, our clothing style may have affected sun exposure. Fourth, as vitamin D is stored in fatty tissues and less is biologically active in serum, obesity may be linked to the low vitamin D levels in our subjects. The BMI of both diabetics and controls were above the normal range. Fifth, insufficient dietary intake of vitamin D may be another cause of the low levels. Last, lack of outdoor physical activity due to possible obesity or mobility issues and to the season must also be considered.
Vitamin D has various effects on glucose homeostasis. Besides its role in insulin secretion (47), it also has an influence on insulin resistance directly or via Ca indirectly (48). Ca is essential for insulin mediated-intracellular processes in insulin responsive tissues such as skeletal muscle and adipose tissue. Changes in Ca in primary insulin target tissues may contribute to peripheral insulin resistance (49) via impaired insulin signal transduction, leading to decreased glucose transporter-4 activity (49). The association between low vitamin D level and insulin sensitivity have been reported in cross-sectional and observational studies (22). The results from the trials on the effect of vitamin D and/or Ca supplementation on insulin resistance have showed improvement on insulin action (50). Supporting the role of vitamin D in both insulin secretion and action, our diabetic patients whose 25(OH)D levels were lower than controls, had higher blood sugar, insulin and HbA1c levels. 25(OH)D levels in diabetic patients were also found to be negatively correlated with HbA1c and FI levels. Diabetic patients were more obese than controls and we showed a negative correlation between BMI and vitamin D. As expected, our diabetics had higher TG levels.
In our diabetic patients, besides significantly low 25(OH)D levels, HOMA-IR levels were significantly high. When we made correlation analysis in diabetic patients, we also found a negative correlation between 25OHD and HOMA-IR. Our results may indicate that vitamin D levels may be related to insulin resistance.
As mentioned before, vitamin D levels in the diabetic group was statistically lower than in the control group, but when we categorized diabetics according to their 25(OH)D levels (<12,12-20 and >20ng/mL), we did not find any difference in the parameters such as blood glucose, insulin, lipids, body mass or insulin resistance index. This result makes us speculate that if vitamin D levels are above normal limits, decline in 25(OH)D levels may not make any change in glucose, lipid metabolism, or obesity or insulin resistance.
In conclusion, we found that vitamin D levels were significantly low in type 2 diabetics compared to non-diabetics.
There was an inverse relationship between vitamin D levels and insulin resistance. We also concluded that as vitamin D levels were so low, when vitamin D levels declined in diabetic patients, metabolic parameters did not worsen. Our findings warrant further examination in prospective studies including clinical trials. Our non-diabetic population also had low 25(OH)D levels, thus, we think that in Turkish population, fortified foods in increasing dietary intake of vitamin D should be encouraged as a component in the treatment plan in combination with supplements of vitamin D and safe sun exposure.
Address for Correspondence/Yazışma Adresi: Gül Gürsoy Kafkas University Faculty of Medicine, Department of Endocrinology, Kars, Turkey
E-mail: [email protected] Received/Geliş Tarihi: 05 October 2012 Accepted/Kabul Tarihi: 21 January 2013