ABSTRACT
Conclusion:
MS is a cluster of diseases in which pro-atherosclerotic processes such as DM, hypertension, obesity, and hypercholesterolemia coexist. In our study, when increased CIMT values were considered as evidence for the presence of atherosclerosis in patients, the low serum ADMA levels may be related to metformin therapy, poor glycemic control, and/or problems in the immune-assay.
Results:
Lower serum ADMA levels and higher CIMT measurements were observed in the patient group than in the control group (p<0.001 and p<0.001, respectively). C-reactive protein (CRP) was significantly higher in patients than in controls (p<0.001). Correlation analysis revealed a significant and inverse correlation between plasma ADMA concentrations and fasting blood glucose (p<0.001, r=-0.421), HbA1c (p=0.001, r=-0.361), CRP (p=0.003, r=-0.335), and CIMT measurements (p=0.024, r=-0.261). Among the patients with MS, 32 were diagnosed with type 2 DM; among whom 29 were receiving metformin treatment. ADMA levels in MS patients with and without metformin therapy were 4.5±1.7 nmol/mL and 7.3±1.2 nmol/mL, respectively; and the ADMA levels were significantly lower in the former than in the latter (p=0.007).
Methods:
Thirty-eight patients (24 women and 14 men) who were diagnosed with MS, according to the National Cholesterol Education Program Adult Treatment Panel III, were included in the study. Patients with a history of systemic diseases, except components of MS, and smokers were excluded from the study. The control group comprised 25 and 12 healthy women and men, respectively; with similar age profiles. Serum ADMA levels and carotid intima-media thickness (CIMT) were measured in patients and controls.
Objective:
This study aimed to make an early diagnosis of endothelial dysfunction, the initial pathology of atherosclerosis in metabolic syndrome (MS) patients, and to investigate the usefulness of serum asymmetric dimethylarginine (ADMA) levels as a marker of cardiovascular risk.
INTRODUCTION
Significant features of metabolic syndrome (MS) include central obesity, hypertension, dyslipidemia, glucose intolerance, vascular inflammation, and prothrombotic condition (1). Studies have highlighted the effect of insulin resistance on MS components and its critical role in the pathophysiology of MS (2). Insulin resistance may lead to hypertension, dyslipidemia, coagulation abnormality, endothelial dysfunction, and cardiovascular diseases (1).
Endothelial dysfunction is the earliest evidence of coronary artery disease and its occurrence in the early stages of the disease; before atheroma plaque formation. The main indicator of endothelial dysfunction is the disruption of endothelium-dependent vasodilatation caused by nitric oxide (NO). NO is synthesized from L-arginine by NO synthase (NOS). NO produced in the endothelium, affects vascular tone and leads to vasodilatation (3,4).
L-arginine is methylated with intracellular methyltransferases and converted to asymmetric dimethylarginine (ADMA), the metabolite of methylated L-arginine. Since, ADMA is an endogenous competitive inhibitor of NOS; it is an important risk predictor for cardiovascular disease; as a marker of endothelial dysfunction (5).
Studies have revealed that in sudden deaths secondary to coronary artery disease, the development of atherosclerosis was not limited to the coronary arteries alone. Therefore, ultrasonographically measured carotid intima-media thickness (CIMT) may be used to detect the presence of atherosclerotic plaques, degree of calcification, arterial lumen diameters, and asymptomatic atherosclerotic disease (6).
In this study, endothelial dysfunction and increased cardiovascular risk in MS were evaluated with serum ADMA levels and CIMT that are considered to be risk factors for cardiovascular disease. The aim of this study was to make an early diagnosis of endothelial dysfunction, the initial pathology of atherosclerosis in MS patients, and to investigate the usefulness of serum ADMA levels as a marker of cardiovascular risk.
METHODS
Study Population
This study was performed prospectively in patients followed in internal medicine, and/or endocrinology and metabolism disease clinics of Bursa Yüksek İhtisas Training and Research Hospital from which the ethics committee approval is obtained (23.10.2013/3). For the diagnosis of MS, according to the National Cholesterol Education Program Adult Treatment Panel III criteria, at least three of the following criteria were required:
• Fasting blood glucose (FBG) >110 mg/dL
• Triglyceride (TG) >150 mg/dL
• Waist circumference >88 cm for women, >102 cm for men
• High-density lipoprotein (HDL) cholesterol <50 mg/dL in women and <40 mg/dL in men
• Blood pressure >130/85 mmHg
Results of hematological investigations were obtained from the archived files of patients. Waist circumferences and body mass indices of patients (BMI) were calculated at the time of their inclusion in the study. ADMA and CIMT were assessed prospectively.
Laboratory Methods
Venous blood samples for serum ADMA level measurements were taken in the morning, following a 12-hour fasting period. They were transported to the laboratory in ice molds and centrifuged at 4000 rpm for 5 min and stored at -80 °C. ADMA measurements were carried out with AD double-antibody sandwich ELISA method with Human ADMA ELISA Kit (Sunred Biological Technology, Shanghai China), with a sensitivity range of 0.05-15 nmol/mL, in the Biochemical Laboratory of Bursa Yüksek İhtisas Training and Research Hospital.
Carotid Intima-media Thickness
CIMT measurements were performed for patient group and control group using Logiq 5 Pro (GE Healthcare, Milwaukee, USA) ultrasound, using a 7.5 MHz linear array transducer. For CIMT, three measurements were taken from approximately 1 cm proximal to the bifurcation of both main carotid arteries, when the anterior and posterior walls were seen bilaterally. The arithmetic mean of the three measured values of the randomly selected region was used.
Statistical Analysis
Average, standard deviation, median, lowest, highest, frequency, and ratio values were used for descriptive statistics. The distribution of variables was assessed with the Kolmogorov-Smirnov test. Mann-Whitney U test and independent sample t-test were used in the analysis of quantitative data, while χ2 test was used for qualitative data. Spearman correlation analysis was used for evaluating correlation. Statistical analysis of the data was performed with “SPSS for Windows, Version 22.” The data were represented by mean ± standard deviation, and p <0.05 was considered as statistically significant.
RESULTS
Thirty-eight patients with MS (24 women and 14 men) and 37 healthy controls (25 women and 12 men) were included in the study, with median ages of 45.1±8.3 years (range; 30-59 years) and 41.4±8.0 years (range; 31-60 years), respectively. The median FBG and HbA1c levels were 167 mg/dL (96-280 mg/dL) and 9% (5.6-13%); and 88 mg/dL (73-113 mg/dL) and 5.5% (4.8±5.8%); in MS and control groups, respectively. The median TG and HDL cholesterol levels were 269 mg/dL (115-480 mg/dL) and 39 mg/dL (22-63 mg/dL); and 112 mg/dL (57-198 mg/dL) and 45 mg/dL (21-84 mg/dL); in MS and control groups, respectively. The median waist circumferences in MS and control groups were 110 cm (104-220 cm) and 65 cm (60-78 cm), respectively; while the median systolic and diastolic blood pressure (SBP and DBP) were 130 mmHg (120-150 mmHg) and 80 mmHg (75-90 mmHg) in the MS group and 120 mmHg (100-128 mmHg) and 75 mmHg (60-80 mmHg) in control group (Table 1).
The serum ADMA levels were significantly different between MS and control groups (5.1±1.9 nmol/mL and 7.7±3.3 nmol/mL, respectively; p<0.001). The same was true for CIMT measurements (0.07±0.01 mm and 0.05±0.01 mm, respectively; p<0.001) (Table 2) (Figure 1, 2).
In MS group, statistically significant negative correlations were observed between serum ADMA levels and (BMI) (r=-0.428; p=<0.001), waist circumference (r=-0.351; p=0.002), SBP (r=-0.330; p=0.004), FBG (r=-0.421; p=<0.001), HbA1c (r=-0.361; p=0.001), TG (r=-0.316; p=0.006), CRP (r=-0.335; p=0.003), and CIMT (r=-0.261; p=0.024). There was a positive correlation between serum ADMA levels and HDL cholesterol (r=0.247; p=0.033) (Table 3).
Further, statistically significant positive correlations were observed between CIMT values and BMI (r=0.713; p=<0.001), waist circumference (r=0.661; p=<0.001), SBP (r=0.610; p=<0.001), FBG (r=0.711; p=<0.001), HbA1c (r=0.686; p=<0.001), TG (r=0.502; p=<0.001), and CRP (r=0.402; p=<0.001). There was a negative correlation between CIMT values and HDL cholesterol (r=-0.279; p=0.015) (Table 4).
Thirty-two of the patients with MS were diagnosed with type 2 DM, and 29 of these were receiving metformin treatment. ADMA levels in MS patients with and without metformin therapy were 4.5±1.7 nmol/mL and 7.3±1.2 nmol/mL, respectively. ADMA levels were significantly lower in patients with MS receiving metformin than in patients without metformin (p=0.007).
DISCUSSION
In the present study, serum ADMA levels and CIMT measurements were compared between MS patients; a risk group for atherosclerosis, and healthy controls.
Some studies have focused on the relationship between serum ADMA levels and atherosclerosis. Vallance et al. (7) were the first to demonstrate that endogenous ADMA antagonizes endothelium-induced vasodilatation. They reported elevated plasma ADMA levels in patients with endothelial dysfunction, and considered it as a risk factor for atherosclerosis. Böger et al. (8) described ADMA as a new cardiovascular risk factor and found that plasma ADMA levels were higher in patients with hypercholesterolemia than in healthy controls. Further, Cooke (9) reported that serum ADMA levels were associated with the development of cardiovascular diseases such as endothelial dysfunction, hypercholesterolemia, peripheral vascular disease, and hypertension.
Many studies have reported increased plasma ADMA concentrations in type 1 and type 2 diabetic patients. In a study of 40 uncomplicated type 1 diabetic patients, plasma ADMA levels were increased before the development of vascular complications (10). Another study, including 408 patients with type 1 diabetic nephropathy, suggested that increased ADMA levels contributed to diabetes-induced organ damage (11). However, there are other studies with contradicting results. In a population-based Framingham offspring study by Böger et al. (12), the mean ADMA levels were similar in diabetic and non-diabetic groups. Although, there was a positive correlation between ADMA levels and mortality in the non-diabetic group, no significant relationship was observed in the diabetic group. Päivä et al. (13) found decreased ADMA levels in type 2 diabetic patients and argued that this result may be due to increased glomerular filtration rate and poor glycemic control in their patients. In another study by Onat et al. (14), the relationships between serum ADMA levels and MS, type 2 DM, and coronary artery disease were investigated in 848 patients. Contrary to the expectations, serum ADMA levels were found to be low in patients with high fasting glucose, and they believed that this may be due to the leakage of some ADMA proteins, triggering an autoimmune response during the immune assays. In the study of Xiong et al. (15), it was found that adopting measures to target various metabolic abnormalities of MS and insulin-sensitizing treatments, generally decreased ADMA levels. Wang et al. (5) found a decrease in plasma ADMA levels and improved flow-mediated dilatation of the brachial artery, 8 weeks after treatment, with rosiglitazone in non-diabetic patients with MS. A recent study found that plasma ADMA levels had a dynamic balance and that they did not correlate with cellular levels (16).
In our study, when compared with healthy controls, serum ADMA levels were found to be significantly lower and CIMT was found to be significantly higher, in patients. In our study, 86% of the patients in the MS group were diabetic, the median HbA1c levels were 9% (5.6-13%), and 29 patients received metformin. Serum ADMA levels were significantly lower in the metformin group than in the non-metformin group. In light of these findings, poor glycemic control-related interference or the use of metformin to break down insulin resistance may be one of the causes of low serum ADMA levels in the MS group.
There are several limitations to our study. The first was the inadequate number of participants in the patient and control groups. Another was that most patients in the MS group had a diagnosis of DM and were receiving treatment for the same. If the newly diagnosed patients, who had no apparent DM and were not receiving any medications, were included in the study, the relationship between MS and serum ADMA could be considered to be free from medication effects and possible effects of poor glycemic control. Other limitations were the lack of insulin values and the absence of objective insulin resistance, although patients met the MS criteria.
CONCLUSION
In conclusion, in many studies, CIMT is accepted as an indicator of generalized atherosclerosis including that of the coronary arteries. MS is a cluster of diseases in which pro-atherosclerotic processes such as DM, hypertension, obesity, and hypercholesterolemia coexist. In our study, when increased CIMT values were considered as evidence for the presence of atherosclerosis in patients, the low levels of serum ADMA may be related to metformin therapy, poor glycemic control, and/or problems in the immune-assay.
References
et al. Plasma concentrations of asymmetric-dimethylarginine in type 2 diabetes associate with glycemic control and glomerular filtration rate but not with risk factors of vasculopathy. Metabolism 2003;52:303-7.