89urn:lsid:arphahub.com:pub:CCBBD2E1-BDAF-5702-AE4B-0E4910A4C7D6PharmaciaPHAR0428-02962603-557XBulgarian Pharmaceutical Scientific Society10.3897/pharmacia.69.e9090890908Research ArticleClinical pharmacologyBeneficial effects of vitamin D in the management of untreated hyperlipidemia in diabetic patients in Erbil, IraqKhoshnawMohammed1DizayeKawadoctorkawa@gmail.comhttps://orcid.org/0000-0003-1739-82731Hawler Medical University, Erbil, IraqHawler Medical UniversityErbilIraq
2022140920226938478530EC69A9C-92FC-5753-ABB8-450318764FF32607202225082022Mohammed Khoshnaw, Kawa DizayeThis is an open access article distributed under the terms of the Creative Commons Attribution License (CC BY 4.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Hyperlipidemia is highly prevalent among type 2 diabetes mellitus (T2DM) patients. As hyperlipidemia plays a major part in atherosclerosis development and progression, this occurrence is linked to a significantly raised risk of cardiovascular disease. This study aims to assess the effects of vitamin D supplementation on lipid parameters in T2DM patients with untreated hyperlipidemia. Thirty-five T2DM patients with hyperlipidemia and vitamin D deficiency were supplemented with vitamin D for three months. Serum 25-hydroxyvitamin D (25[OH]D), calcium, lipid parameters, atherogenic indices, glucose, and HbA1c were recorded before and after the intervention. After supplementation, there was a statistically significant reduction in VLDL-C and triglycerides. Triglycerides showed a significant negative correlation with 25(OH)D. Atherogenic indices and HDL-C also improved significantly. Vitamin D supplementation had beneficial effects on the lipid profile of T2DM patients with untreated hyperlipidemia and vitamin D deficiency. Thus, vitamin D could be a valuable adjuvant therapy for these patients.
type 2 diabetes mellitushyperlipidemialipid profilevitamin DIntroduction
Diabetes is a significant driver of dyslipidemia, which is a metabolic disorder characterised by an increase in serum triglyceride (TG) levels or total cholesterol concentrations and/or serum high-density lipoprotein cholesterol (HDL-C) reduction (Ama Moor et al. 2017). The process of cholesterol, TG, and their derivatives is tightly regulated, which is interrupted due to continuous hyperglycemia in diabetes leading to hypertriglyceridemia and hypercholesterolemia (Závorková et al. 2018).
Dyslipidemia, hypertension, arteriosclerosis, and all these consequences associated with myocardial infarction and stroke are more common in type 2 diabetic patients (Ginsberg 2000). Despite the increase in the use of lipid-lowering agents, dyslipidemia is poorly controlled (Alshamiri et al. 2018). Statins and fibrates are the most commonly prescribed lipid-lowering medicines (Blais et al. 2021). Although they are effective in achieving optimal concentrations of lipids, fibrates have been attributed to side effects, including myopathy and hepatotoxicity (Okopień et al. 2018). Furthermore, long-term statin use might lead to myopathy, new-onset T2DM, and perhaps a hemorrhagic stroke, which can affect treatment adherence and increase cardiovascular risk (Collins et al. 2016; Ward et al. 2019).
Vitamin D is a hormone that has an important role in maintaining mineral homeostasis and integrity of the bone but also has numerous extraskeletal pleiotropic effects involving the endocrine system (Verstuyf et al. 2010). Many studies have reported that vitamin D deficiency is prevalent in patients with type 2 diabetes (Al-Zaharani 2013; Bashir et al. 2016; Nasr et al. 2022).
Studies also revealed that higher concentrations of serum 25-hydroxyvitamin D (25[OH]D) correlate with higher HDL-C, lower low-density lipoprotein cholesterol (LDL-C), total cholesterol, and TG levels (Wang et al. 2012; Tepper et al. 2014). In addition, a recent study in China reported that the incidence of dyslipidemia is higher in individuals with vitamin D deficiencies (Yang et al. 2020).
According to a meta-analysis of clinical trials, vitamin D supplementation has been shown to reduce TG, LDL-C, and total cholesterol serum levels (Dibaba 2019). A decade-long study discovered that serum 25(OH)D and serum TG have an inverse relationship (Jorde et al. 2010). Vitamin D might indirectly affect blood lipid levels by improving insulin sensitivity and secretion (Kamycheva et al. 2007).
Vitamin D may also help in maintaining glucose homeostasis via pancreatic beta-cell stimulation to increase insulin release (Pitocco et al. 2006). Improvement in insulin resistance as a result of reduced systemic inflammation, direct stimulation of insulin secretion via vitamin D receptors on pancreatic beta-cells, and reduction in peripheral insulin resistance in the liver and muscles have all been proposed as mechanisms to elucidate the possible role of vitamin D in the metabolism of glucose (Gysemans et al. 2005; Zhou et al. 2008; Park et al. 2016). Correcting vitamin D deficiency may improve glucose levels and have beneficial effects on preventing complications related to type 2 diabetes (Mirhosseini et al. 2018a; Hu et al. 2019).
Although vitamin D supplementation has been investigated for its effects on the lipid profile in type 2 diabetic individuals, experimental studies have provided inconsistent findings (Jorde and Grimnes 2011). Identifying effective ways of reducing microvascular and macrovascular complications and the risk of developing cardiovascular disease in type 2 diabetic patients is an important global health concern. There is a need for studies on the beneficial effects of vitamin D on blood lipids and glycemic control in diabetic patients. This study aims to evaluate the effects of correcting vitamin D deficiency with vitamin D supplementation in type 2 diabetic patients with untreated hyperlipidemia on lipid parameters and glycemic control.
Materials and methodsStudy design and patients
This prospective clinical trial study was conducted among type 2 diabetes mellitus (T2DM) patients with untreated hyperlipidemia and vitamin D deficiency at Layla Qasim Diabetic Center, Erbil, Iraq, over a period of six months from 1 October 2021 to 1 April 2022. Out of two hundred patients, thirty-five patients were eligible for the study. Patients were supplemented with a weekly oral 50,000 IU of vitamin D3 softgel capsule (Madamar Company, Warsaw, Poland) for three months to correct serum vitamin D deficiency. In addition, they were advised to continue their existing lifestyle and medications. Twenty-six patients completed the study, and the rest were excluded for various reasons (three patients started taking lipid-lowering agents, two patients were travelling, and four patients changed their antidiabetic medications). The study participants’ mean age ± standard deviation (SD) was 55.4 ± 9 years and ranged from 38 to 72 years.
Inclusion criteria
Both male and female type 2 diabetic patients aged ≥ 18 years attending Layla Qasim Diabetic Center with hyperlipidemia (triglyceride and/or total cholesterol > 200 mg/dL) and serum 25(OH)D < 20 ng/ml were included in this study.
Exclusion criteria
The study excluded patients who were taking vitamin D supplements, lipid-lowering drugs, receiving insulin therapy, who had type 1 diabetes, and those who were known to have other lipid-altering diseases, such as hepato-biliary disease, hypothyroidism, chronic kidney disease, and nephrotic syndrome. Patients who consumed alcohol and women who were pregnant or breastfeeding were also excluded.
Data collection
Patients’ information including demographic characteristics, disease profiles including duration of diabetes, current medications used by the patients, presence of dyslipidemia and cardiovascular diseases (duration of the diseases and their treatments), height and weight to calculate body mass index (BMI).
Blood samples were taken from patients after fasting (for 12 hours) and divided into two parts. The first part was placed in an EDTA-test tube for glycated haemoglobin (HbA1c) measurement, and the second part was placed in a non-coagulant test tube at room temperature to allow clotting (for 15 minutes) then the sera were separated by centrifugation (3,000 rpm for 10 minutes). Finally, HbA1c, serum 25(OH)D, calcium, glucose, and lipid profile, including total cholesterol, TG, LDL-C, and HDL-C were measured by enzymatic methods using Cobas 6000 (Roche Diagnostics, Hitachi, Tokyo, Japan), which is a fully automated analyser for clinical chemistry analysis. The same procedures were carried out again after three months of supplementation with vitamin D.
Ethical considerations
Informed consent was obtained from the patients who participated in this study and the study was approved by the Scientific and Research Committee of College of Pharmacy, Erbil, Iraq. Reference number: HMU.PE.05.09.2021-332.
Statistical analysis
The data were evaluated statistically using SPSS software (version 26.0). The data were presented as mean ± SD or frequencies and percentages. A Student’s t-test and the Mann-Whitney U test were used for data analysis. The Shapiro-Wilk test was used to identify the normal distribution of the data. A Pearson’s correlation was used to examine the associations between serum 25(OH)D levels and blood lipid and glucose levels. A P-value of 0.05 or less was considered statistically significant.
Results
Twenty-six patients completed the follow-up (13 females and 13 males) who had dyslipidemia and vitamin D deficiency with a diabetes duration of 8.7 ± 6 years. Most participants (20) were non-smokers (76.9%) (Table 1).
Baseline characteristics of the study participants.
Characteristics
Values
Age (years)
55.4 ± 9
Duration of diabetes (years)
8.7 ± 6
BMI (kg/m2)
30.31 ± 4.72
Height (cm)
163.94 ± 9.19
Weight (kg)
81.69 ± 15.53
Gender
Male
13 (50)
Female
13 (50)
Smoking status
Non-smoker
20 (76.9)
Smoker
6 (23.1)
Data presented as mean ± SD or n (%); BMI: Body mass index.
There were no statistically significant differences in the mean serum 25(OH)D and calcium levels between male and female patients before and after the supplementation. Vitamin D supplementation over a period of three months led to a significant rise in serum 25(OH)D (from 13.60 ± 4.30 to 37.90 ± 8.04 ng/mL, P = 0.001). None of the patients developed hypercalcaemia (8.95 ± 0.57 mg/dL) after supplementation (Table 2).
Assessment of serum 25(OH)D and calcium before and after vitamin D supplementation in T2DM patients with hyperlipidemia and vitamin D deficiency.
Parameters
Before vitamin D supplementation
After vitamin D supplementation
P-value
25(OH)D (ng/mL)
13.60 ± 4.30
37.90 ± 8.04
0.001
Calcium (mg/dL)
8.92 ± 0.50
8.95 ± 0.57
0.747
Data presented as mean ± SD; 25(OH)D: 25-Hydroxyvitamin D.
After three months of follow-up, on the one hand, there was a statistically significant reduction in very-low-density lipoprotein cholesterol (VLDL-C) (from 55.00 ± 11.75 to 49.87 ± 12.01 mg/dL, P = 0.001) and TG (from 274.98 ± 58.74 to 249.34 ± 60.06 mg/dL, P = 0.001) with a mean serum level change of -9.31% and -9.32%, respectively. On the other hand, there was a statistically significant increase in HDL-C (from 33.51 ± 6.16 to 37.17 ± 6.43 mg/dL, P = 0.001) with a mean serum level change of 10.92% and atherogenic indices improved significantly. However, total cholesterol and LDL-C were decreased nonsignificantly (Table 3).
The effect of vitamin D supplementation on lipid parameters and percentage change in serum lipid profile and atherogenic index following vitamin D supplementation.
Parameters
Before vitamin D supplementation
After vitamin D supplementation
% change
P-value
Total cholesterol (mg/dL)
200.62 ± 23.34
197.52 ± 24.46
-1.55%
0.184
LDL-C (mg/dL)
122.72 ± 19.68
120.72 ± 20.93
-1.63%
0.214
VLDL-C (mg/dL)
55.00 ± 11.75
49.88 ± 12.01
-9.31%
0.001
TG (mg/dL)
274.98 ± 58.74
249.34 ± 60.06
-9.32%
0.001
HDL-C (mg/dL)
33.51 ± 6.16
37.17 ± 6.43
10.92%
0.001
Cholesterol/HDL-C
6.14 ± 1.17
5.45 ± 1.08
-11.24%
0.001
TG/HDL-C
8.56 ± 2.73
6.99 ± 2.42
-18.34%
0.012
AIP (Log TG/HDL-C)
0.55 ± 0.15
0.46 ± 0.15
-16.36%
0.001
Data presented as mean ± SD.
LDL-C: low-density lipoprotein cholesterol; VLDL-C: very-low-density lipoprotein cholesterol; TG: triglycerides; HDL-C: high-density lipoprotein cholesterol; AIP: atherogenic index of plasma.
Pearson’s correlation analysis between serum levels of 25(OH)D and other parameters was performed in which serum levels of 25(OH)D had a nonsignificant negative correlation with fasting blood glucose (FBG) (r = -0.14, P = 0.49) and HbA1c (r = -0.03, P = 0.88). Regarding lipid parameters, TG showed a significant negative correlation with serum 25(OH)D (r = -0.46, P = 0.02) (Fig. 1) while other lipid parameters showed nonsignificant correlations with 25(OH)D levels.
Correlation between serum 25(OH)D and triglyceride levels after three months of supplementation with vitamin D.
https://binary.pensoft.net/fig/743132
Additionally, HbA1c was significantly improved (from 8.44 ± 0.93% to 7.95 ± 0.86%, P = 0.001) while FBG was decreased nonsignificantly (Table 4).
Assessment of glycemic status before and after vitamin D supplementation in T2DM patients with hyperlipidemia and vitamin D deficiency.
Parameters
Before vitamin D supplementation
After vitamin D supplementation
P-value
FBG (mg/dL)
174.67 ± 37.58
160.13 ± 28.40
0.113
HbA1c (%)
8.44 ± 0.93
7.95 ± 0.86
0.001
Data presented as mean ± SD; FBG: fasting blood glucose; HbA1c: glycated haemoglobin.
Discussion
The deficiency of vitamin D has been linked to a higher risk of developing several chronic diseases, including T2DM (Wang et al. 2017). Type 2 diabetics, especially those with poorly controlled diabetes, are highly prone to hyperlipidemia (Shahwan et al. 2019). Compared to those who do not have diabetes, hyperlipidemia is significantly associated with an increased risk of cardiovascular disease due to the role it plays in atherosclerosis development and progression (Miao et al. 2020; Merkhan et al. 2021).
In this study, 25(OH)D levels were measured to determine vitamin D deficiency, since it is the most accurate indicator of vitamin D status (Sempos et al. 2018).
The present study involved T2DM patients with vitamin D deficiency and dyslipidemia. They were on oral hypoglycaemic agents and not taking lipid-lowering agents. To our knowledge, no research has been conducted on the effects of vitamin D supplementation on the lipid profile in T2DM patients with untreated hyperlipidemia and vitamin D deficiency. Supplementing vitamin D for three months led to a substantial rise in levels of 25(OH)D and a significant decrease in VLDL-C, TG levels, and atherogenic indices (cholesterol/HDL-C, TG/HDL-C, and AIP), and a significant rise in HDL-C levels.
The available studies’ findings regarding the impact of vitamin D administration on lipid profile are uncertain. A study conducted on hyperlipidemic patients on statin therapy found a significant improvement in total cholesterol, TG, LDL-C, and HDL-C levels after taking daily 2,000 IU of vitamin D for six months (Qin et al. 2015).
The present study’s result of reduced levels of TG after vitamin D supplementation is consistent with the findings of Barzegari et al. (2019). In their study, an eight-week administration of weekly 50,000 IU of vitamin D as a supplement in diabetic nephropathy patients showed a significant reduction in TG, LDL-C, and total cholesterol levels in participants with a marginal vitamin D deficiency. In another study on T2DM patients who had been advised not to change the dose of their antidiabetic and antihyperlipidemic drugs throughout the study period, Mohammed et al. (2016) showed no significant improvement in lipid profile after receiving daily 4,500 IU of vitamin D for two months, except for female patients whose TG levels were significantly reduced.
In the present study, the participants showed a significant rise in HDL-C levels after the supplementation with vitamin D. A similar increase in HDL-C levels was observed in several other studies (Rad et al. 2014; Razzaghi et al. 2017; Wenclewska et al. 2019). Similarly, Mirhosseini et al. (2018b) confirmed the favourable impact of vitamin D on HDL-C in their meta-analysis. This positive influence of 25(OH)D on HDL-C might result from the increased concentration of apolipoprotein AI in the blood, which plays an important role in the reverse cholesterol transport process (Kazlauskaite et al. 2010). Pearson’s correlation revealed a significant negative correlation between serum TG and 25(OH)D, which is similar to the findings of some other studies (Elmi et al. 2021; Elshebiny et al. 2021; Gong et al. 2022). In contrast to this finding, Ramiro-Lozano and Calvo-Romero (2015) concluded that supplementing T2DM patients with 16,000 IU of vitamin D once a week for eight weeks did not significantly alter their blood TG, cholesterol, and HDL levels.
The variations in these results may be attributed to study participants’ vitamin D levels and blood lipid levels at baseline, variations in dosage of vitamin D supplementation, and discrepancies in the design and duration of the studies.
Numerous mechanisms have been proposed for vitamin D’s effect on lipid levels. Vitamin D may affect lipid metabolism by inhibiting 3-hydroxy-3-methylglutaryl coenzyme A reductase expression, which in turn lowers the synthesis of cholesterol (Li et al. 2016). Vitamin D increases the absorption of calcium in the intestine and the intestinal calcium influences the absorption of fats resulting from the binding of calcium to intestinal bile acids and fatty acids to make soaps of calcium-fatty acid, which are eventually eliminated from the body in the faeces (Wang et al. 2016). Zittermann et al. (2009) have proposed that the increased calcium absorption could affect hepatocellular calcium to lower serum TG by lowering hepatic TG formation or secretion. Theoretically, vitamin D could have an immediate effect on serum lipid levels, but it could also have an indirect effect on calcium balance and/or serum parathyroid hormone (PTH) (Jorde and Grimnes 2011). Additionally, serum levels of 25(OH)D and PTH are inversely related, and serum PTH levels are suppressed by vitamin D supplementation (Suplotova et al. 2019). This suppressive effect of vitamin D on serum concentrations of PTH might cause a reduction in serum levels of TG as a result of enhanced peripheral removal (Wang et al. 2016). Furthermore, vitamin D may also influence insulin secretion and sensitivity, thus indirectly affecting lipid metabolism (Lemieux et al. 2019).
Regarding glycemic status, following three months of vitamin D supplementation, participants had a significant reduction in HbA1c levels. The reduction in FBG was not significant. The effect of vitamin D supplementation on glucose levels in our study was similar to results in several other studies (Krul-Poel et al. 2015; Ghadiri-Anari et al. 2019; Safarpour et al. 2020).
In parallel with this study, various studies reported a significant reduction in HbA1c levels in diabetic patients after receiving vitamin D supplementations (Razzaghi et al. 2017; Upreti et al. 2018; Almaghrbi et al. 2021). Vitamin D may enhance the function of beta-cells (Mitri et al. 2011) and reduce insulin resistance (Guclu et al. 2016). Conversely, some other studies on diabetic patients were not documented with similar effects of vitamin D supplementation on glycemic control (Witham et al. 2010; Heshmat et al. 2012; Al-Sofiani et al. 2015). The likely explanations for these inconsistent findings might be the different study designs, differences in diet and lifestyle, type and/or dose and the schedule of hypoglycaemic agents, and genetic variation of populations. Overall, vitamin D supplementation has improved lipid profile and glycemic control, thus, it might reduce the risk of diabetic complications, especially in those with hyperlipidemia and vitamin D deficiency.
It is still unclear exactly how vitamin D influences blood glucose levels. It is possible that the improvement in glycemic status might be due to the presence of vitamin D receptors and 1-alpha-hydroxylase in the pancreas (Bland et al. 2004). In a recent experiment, Kjalarsdottir et al. (2019) discovered that preincubating human and mouse islets with calcitriol increases glucose-stimulated insulin secretion and glucose-stimulated calcium influx via upregulation of the voltage-gated calcium channel gene, consequently modulating the beta-cell capacity to secrete insulin. Additionally, Chen et al. (2016) found that in mice lacking functional vitamin D receptors in their skeletal muscles, forkhead box O1 (FOXO1), a transcription factor that negatively regulates insulin signalling, is expressed and activated at higher levels. They also showed that the overexpression of FOXO1 results in skeletal muscle vitamin D signalling deficiency that contributes significantly to insulin resistance and glucose intolerance development.
The present study has some limitations due to time constraints, including a relatively small sample size and a short intervention period. Additionally, this study did not analyse subgroups.
Conclusions
Oral vitamin D supplementation of 50,000 IU once weekly for three months significantly decreased VLDL-C, TG, atherogenic indices, and HbA1c and led to a significant rise in HDL-C levels in T2DM patients with untreated hyperlipidemia and vitamin D deficiency. Therefore, vitamin D supplementation to restore normal levels of vitamin D in such patients could be a valuable adjuvant therapy. However, further studies with larger patient samples and longer durations are needed to substantiate our findings.
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