1. Introduction
Numerous reports have shown that the number of overweight and obese people has increased in recent years. The problem affects children, adolescents, and adults [
1,
2,
3,
4,
5,
6]. Obesity leads to many systemic disorders, including metabolic syndrome (MetS), type-2 diabetes, atherosclerosis, cardiovascular complications, cancer diseases, etc. [
7,
8,
9]. There are reports suggesting that obesity leads to chronic inflammation, which disturbs the proper functioning of the immune and metabolic systems [
10,
11,
12]. Increased inflammatory activation is characterized by elevated serum levels of C-reactive protein (CRP) and proinflammatory cytokines, such as interleukin-6 (IL-6), and tumor necrosis factor alpha (TNF-α) [
11,
12,
13,
14].
Over recent years, "metabolic syndrome" has become one of the most commonly used terms in the field of health sciences. The definition of MetS indicates that the development of atherosclerotic cardiovascular disease and type-2 diabetes is underlaid by interrelated risk factors [
15,
16]. The most important element of the etiology of MetS is insulin resistance accompanied by compensatory hyperinsulinemia, while the most-often diagnosed components are impaired glucose tolerance or diabetes, android obesity, atherogenic dyslipidemia, low levels of high-density lipoprotein (HDL) cholesterol, and increased blood pressure [
16,
17]. Of key importance for the development of MetS is an excess of white adipose tissue and its distribution in the visceral area. Android obesity, diagnosed on the basis of waist circumference, is thus a vital diagnostic criterion for MetS [
18,
19]. White adipose tissue thus plays a double role, bothfunctional and mechanical (it serves as stroma and thermal insulation protection for internal organs). It is also an active buffer for lipids, and an important endocrine organ [
20,
21]. Many authors have demonstrated a significant association between android obesity and the major components of MetS, namely insulin resistance, hypertension, atherogenic dyslipidemia, and hyperglycemia [
22,
23]. The mechanism of these relationships is very complex and not fully elucidated. Nevertheless, the epidemic of android obesity is the leading cause of the increase in the worldwide incidence of MetS [
22,
23].
The lack of an unambiguous view of the etiology of MetS translates into diagnostic difficulties in clinical practice. Hence, a long-lasting discussion in academic circles on MetS, its definition, and criteria is of highest diagnostic and prognostic value. Several different definitions of MetS were developed at the turn of the 21st century. In 2005, the International Diabetes Federation (IDF) established diagnostic criteria for MetS, which in fact were a modified version of the guidelines previously proposed by the experts of the National Cholesterol Education Program Adult Treatment Panel III (NCEP-ATP III). A precondition for the diagnosis of MetS was central obesity, accompanied by two out of four factors mentioned in the definition suggested by the NCEP-ATP III. However, it was not until 2009 that the IDF, with the approval of the American Heart Association/National Heart, Lung, and Blood Institute (AHA/NHLBI), offered one single definition and uniform guidelines on MetS [
18,
24].
MetS is thus an important field of interest and investigation for public health. Atherosclerotic cardiovascular disease remains the main cause of complications and deaths.
Vitamin D
3 is obtained from the diet or through synthesis in the skin with the participation of ultraviolet B radiation (UVB). Next, it is metabolized to its active form, 1.25-dihydroxyvitamin D, with the aid of enzymes. There are two forms of vitamin D: vitamin D
2 (ergocalciferol), which is found in plants and fungi, and vitamin D
3 (cholecalciferol), which is produced by animals. In humans, solar radiation converts provitamin D
3 into previtamin D
3, which is then spontaneously heat-isomerized to vitamin D
3 [
25,
26]. The main circulating metabolite of vitamin D is vitamin 25(OH)D, which accurately reflects the amount of vitamin D in the body, whether it originated from food or was synthesized in the skin. According to many authors, vitamin D deficiency is a worldwide phenomenon that may affect as many as 30–50% of the adult population [
27,
28,
29]. Those especially prone to vitamin D deficiency are elderly people, due to their decreased ability to synthesize this vitamin in the skin [
29].
Until recently, vitamin 25(OH)D was regarded as a factor regulating calcium phosphate and bone tissue metabolism. Reports from recent years have confirmed that it is involved in maintaining homeostasis in many tissues [
30,
31], and its deficiency is associated with musculoskeletal and cardiovascular disorders, as well as autoimmune, dermatological, and cancer diseases [
32,
33,
34,
35]. Furthermore, serum vitamin D levels appear to be related to obesity in both healthy and ill individuals [
36,
37,
38,
39,
40,
41]. The reduced bioavailability of vitamin D is observed in overweight and obese individuals, which probably results from the increased sequestration of this vitamin in adipose tissue [
14,
42]. Vitamin D deficiency is closely related to visceral obesity [
43], which is confirmed by elevated serum levels of proinflammatory cytokines and TNF-α in overweight and obese people [
12]. Taking into account the global increase in obesity, the analysis of the relationships between vitamin D levels, adipose tissue metabolism, and the development of MetS is a necessity. Our attempts to identify the determinants of MetS will undoubtedly contribute to the state of the art in the field, and enable successful therapeutic interventions.
3. Material and Methods
The study involved 119 women from West Pomeranian province, Poland. The criteria for inclusion in the study were female sex, age, a diagnosis of MetS, voluntary written consent to take part in the study, and place of residence in West Pomeranian province. The exclusion criteria were oncological and psychiatric disorders and D3 vitamin supplementation. The patients received written information about the purpose and course of the study, and were assured that they were free to withdraw at any stage without giving a reason. The research procedure was divided into three stages, including structured medical history, anthropometric and blood pressure measurements, and serum biochemical analysis.
The patients were diagnosed with MetS if they had at least 3 out of 5 of its components, in accordance with the modified criteria proposed by the IDF in 2009. These components were waist circumference ≥80 cm, fasting glycemia ≥100 mg/dL or pharmacotherapy for hyperglycemia, triglyceride level ≥150 mg/dL or related pharmacotherapy, HDL cholesterol level <50 mg/dL or related pharmacotherapy, and elevated blood pressure (sBP ≥130 and/or dBP ≥85 mmHg) or pharmacotherapy for hypertension [
27].
Anthropometric measurements were performed using a digital scale with a height rod. The patients were measured on an empty stomach, after urination, wearing light clothes and no shoes. Waist and hip measurements were taken in a standing position. Waist circumference was measured between the lower rib margin and the upper margin of the iliac crest at the end of a gentle exhalation. Hip circumference was measured at the level of the maximum protrusion of the gluteal muscles. Waist circumference ≤80 cm was regarded as normal. Based on the data obtained, we calculated the body mass index (BMI) and waist-to-hip ratio (WHR). A BMI in the range of 18.5–24.9 kg/m2 was regarded as normal, a BMI between 25.0 kg/m2 and 29.9 kg/m2 denoted overweight, and a BMI ≥ 30 kg/m2 indicated obesity. WHR was calculated by dividing waist circumference by hip circumference. Values <0.8 indicated the gynoid type of adipose tissue distribution, and values ≥0.8 indicated android type. Blood pressure, both systolic (sBP) and diastolic (dBP), was gauged in a sitting position using a manual manometer. The manometer’s cuff was wrapped snugly around the patient’s right upper arm at the heart level. The patient’s arm was supported so as to allow her to rest in that position for at least 5 min before the measurement. The cuff was adjusted for the arm circumference.
At the next stage, venous blood samples were taken on an empty stomach (minimum 8 h from the last meal) from each patient using the Vacutainer system, in compliance with the relevant regulations. The levels of the following biochemical parameters were determined in blood serum: total cholesterol (TCh, normal level: 115–190 mg/dL), HDL (normal level >50 mg/dL), low-density lipoprotein (LDL, normal level <115 mg/dL), triglycerides (TG, normal level <150 mg/dL), and vitamin D3 (normal level: 30–80 ng/mL or 75–200 nmol/L).
All subjects were informed in detail of the range and purpose of the study, and gave their written consent for their participation. The protocol was approved by the Bioethical Commission of the Pomeranian Medical University in Szczecin (approval number KB-0012/181/13).
Statistical Analysis
Statistical analysis was performed in the R software environment (version 3.5.0). Descriptive statistics—such as the number of valid cases, arithmetic mean, standard deviation, and median, as well as minimum and maximum values—were applied. We also used the structure ratio and mathematical statistics, such as distribution fitting tests, nonparametric correlations, and significance-of-difference tests. Statistical significance was assumed at p ≤ 0.05, and high statistical significance at p ≤ 0.01.
4. Results
The mean age of the participants was 52.73 ± 7.92 years. The majority of them had completed tertiary (39.50%) and secondary (36.13%) education, with 57.98% of the women living in large conurbations. The vast majority of the women were married (75.63%) and employed (73.95%).
Excessive body weight was a major problem: 33.61% were overweight, 26.05% were obese, and 18.48% had first- or second-degree obesity. A high BMI was observed in 78.15% (93) of cases. The mean BMI of the overweight women fell within the range of 32.39 ± 29.81, and was close to the mean BMI of their obese counterparts, 32.29 ± 24.75. The values for the women with first and second-degree obesity were slightly higher (39.01 ± 30.31). Only 26.89% (32) of the participants had normal vitamin D
3 levels, 52.94% (63) had vitamin D
3 deficiency, and 20.16% (24) had elevated levels of the vitamin. There were no statistically significant relationships between the women’s BMIs and their vitamin D
3 levels (
p = 0.092;
p = 0.291), see
Table 1.
The measurement of adipose tissue distribution (WHR) showed that the vast majority of the women (75.63%) had android obesity, and almost half (48.89%) of these had low vitamin D
3 levels. In the group without android obesity, vitamin deficiency was observed in 65.52% of the women. The analysis did not demonstrate a statistically significant relationship between the women’s waist circumference and their vitamin D
3 levels (
p = 0.067;
p = 0.291), see
Table 2.
No statistically significant relationships (
p > 0.05) were found between the selected metabolic parameters (total cholesterol, LDL and the HDL fractions, and triglycerides), systolic (sBP) and diastolic blood pressure (dBP), and vitamin D
3 levels (
Table 3).
The study demonstrated a statistically significant positive correlation between the women’s age and their vitamin D
3 levels (
p < 0.001), see
Table 4.
Age statistically contributed significantly both to the risk of vitamin D
3 deficiency (
p < 0.006)—vitamin D
3 levels decreased by 6.7% (odds ratio = 0.933) with each subsequent year—and to the risk of elevated vitamin D
3 levels (
p < 0.002)—vitamin D
3 levels rose by 13.1% (odds ratio = 1.131) with each subsequent year (
Table 5).
Menstruating women made up 36.13% of the study sample (56.30% not menstruating). The research revealed a statistically significant relationship (
p = 0.015;
p = 0.01) between vitamin D
3 levels and the menstrual cycle. The menstruating women more often had vitamin D
3 deficiencies, and less often showed elevated vitamin D
3 levels (
Table 6).
5. Discussion
Advanced clinical and epidemiological studies have provided data on the factors that contribute to inadequate vitamin D
3 levels and the diseases this can cause in humans. Research results suggest that vitamin D
3 deficiency entails a higher incidence of autoimmune, cardiovascular, and cancer diseases [
30,
31,
32,
33,
35]. Vitamin D
3 synthesis in human skin is one factor that determines the amount of cholecalciferol available to healthy individuals. Many elements, including air pollution, lifestyle, the use of sun filters, and the dose of ultraviolet (UV) radiation received affect this synthesis [
30]. At latitudes corresponding to Poland, optimal vitamin D supply is achieved from March/April to September, provided that 18% of the naked body is exposed to the sun for 15 min a day. During fall and winter, oral supplementation is recommended [
30,
44]. According to estimates, about 30–80% of children and adults worldwide suffer from severe vitamin D deficiency [
45], which has serious consequences on health, and thus contributes to a global public health crisis [
33].
Many researchers point to vitamin D
3 deficiency as a factor in the pathogenesis of hypertension (vitamin D
3 inhibits renin and endothelin synthesis and the proliferation of smooth muscle cells), MetS, and diabetes (development of insulin resistance). It has hence been suggested that vitamin D
3 deficiency raises the risk of cardiovascular disease [
26,
27,
46,
47,
48,
49,
50]. According to expert guidelines proposed in 2009, the pleiotropic effects of vitamin D
3 can be achieved by maintaining vitamin levels in the range of 30–80 ng/mL (75–200 nm/L) in adults [
44]. Vitamin D
3 deficiency, defined as serum levels of calcifediol (or 25(OH)D) below 20 ng/mL, is observed in over half of the Polish population, with this percentage increasing to over 70% in the winter months [
25,
51,
52,
53]. Our study has demonstrated low serum vitamin 25(OH)D levels (below 30 ng/mL) in 52.94% of its participants, while the optimal (recommended) levels were only found in 26.89%.
The relationship between obesity and vitamin D
3 has not yet been fully explicated. However, the available findings show that overweight and obese people have low serum levels of this vitamin [
53,
54,
55,
56,
57]. In obese individuals, vitamin D
3 bioavailability is limited due to its sequestration in adipose tissue [
42,
57,
58]. Many researchers indicate that serum vitamin 25(OH)D levels are associated with obesity in both healthy and unhealthy populations [
36,
37,
38,
39,
59,
60,
61]. Nonetheless, this relationship has not been confirmed by all authors [
37,
62], which corresponds with our outcomes showing no association between BMI and vitamin D
3 levels.
Described by Reaven in 1988, MetS is characterized by the coexistence of carbohydrate metabolism disorders, lipid metabolism disorders, and hypertension underlain by insulin resistance and obesity [
17]. The study of Chacko et al. (2011) does not support the hypothesis of the connection between 25(OH)D levels and LDL, HDL, and glucose levels [
63]. In a study of Korean postmenopausal women, on the other hand, low serum vitamin D
3 levels were accompanied by MetS or some of its parameters (especially hypertriglicerides and hypertension) [
64]. In another study, based on the data of the 2008–2010 Korean National Health and Nutrition Examination Surveys (KNHANES), the authors did not note a significant relationship between serum 25(OH)D levels and the incidence of MetS in postmenopausal women [
65]. Our study also did not provide evidence for statistically significant correlations between selected metabolic parameters, blood pressure, and vitamin D
3 levels.
One of the diagnostic criteria for MetS is android obesity, since this is the main factor responsible for the development of insulin resistance. As a result of the disturbed balance between proinflammatory and anti-inflammatory cytokines produced in adipose tissue (and elsewhere), a large amount of visceral adipose tissue contributes to chronic inflammation (so-called metabolic inflammation) [
17]. According to Roth et al. (2011), vitamin D levels are associated with the metabolism of adipose tissue. Researchers emphasize that the development of insulin resistance and other MetS components in obese people correlates with vitamin D deficiency [
66]. Cheng et al. (2010) also assert that a larger amount of adipose tissue is associated with greater vitamin D deficiency. Furthermore, the negative correlation between adipose tissue levels and the level of 25(OH)D is stronger in people with android obesity [
43]. In our study, the vast majority of the women (75.63%) had android obesity and nearly half of them had vitamin 25(OH)D deficiency. Nevertheless, the analysis did not demonstrate a correlation between these two.
A European multicenter study, the Survey in Europe on Nutrition and the Elderly, a Concerted Action (SENECA), involving elderly people from 11 European countries, showed that the lowest vitamin D levels were found in Italy and Spain, and the highest in Norway [
25]. High vitamin D
3 levels in Scandinavian countries are ascribed to a diet based largely on fish and fish fat. Low vitamin D levels in sunny countries (such as Italy and Spain), on the other hand, are explained by avoidance of exposure to sunlight by the studied women. Low vitamin levels in Middle Eastern countries (Turkey, Jordan, Iran, etc.) are attributed to dress codes for women that require them to cover the whole body. Vitamin 25(OH)D deficiency is also related to age. The synthesis of the biologically active form of vitamin D decreases with age, which is often accompanied by chronic renal disease. Additionally, people of advanced age tend to avoid exposure to sunlight [
25]. Our study confirmed the correlation between age and vitamin D
3 but, surprisingly, higher levels of vitamin D
3 were observed in older women.
Menopause is a physiological phenomenon that typically occurs between 45 and 55 years of age. In Poland, the mean age of menopause is 50 years. This stage of life is characterized by the reduced production of hormones in the ovaries. Lower estrogen levels contribute to lower vitamin D-binding protein (DBP), and consequently lower 25(OH)D levels in blood. This deficiency of 25(OH)D can negatively affect bodily functions, resulting in various disorders (especially in women of postmenopausal age). As stated by Kołodziejczyk et al. (2017), women at this age more often undergo laboratory analysis to determine 25(OH)D levels. Those authors found that postmenopausal women diagnosed with MetS had lower levels of this vitamin than their premenopausal counterparts [
67]. In our investigation, the study sample consisted of women with a diagnosis of MetS, over half of whom were postmenopausal. However, our results were different, andvitamin D
3 deficiency was observed in the premenopausal women.
Vitamin D
3 exerts an influence on various physiological functions, such as reproduction, sex hormone synthesis, normalization of the menstrual cycle, immune system response, and metabolic pathways [
68]. Hence, the need to continue research in this field to expand our knowledge of the pleiotropic effects of vitamin D
3 seems indisputable.