Association of serum asymmetric dimethyl-arginine and troponin I levels as a risk of myocardial infarction in thalassemia.

BACKGROUND: The current study evaluated level of serum asymmetric dimethylarginine (ADMA) and its association to cardiac biomarkers in thalassemia patients for early diagnosis of abnormality in myocardial infarction. SUBJECTS AND METHODS: This study was conducted on 80 subjects divided into four groups each with 20 subjects. Group I: Control: healthy subjects. Group II: Myocardial infarction: Patients with elevated serum troponin T. Group III: thalassemia patients. Group IV: thalassemia with myocardial infarction patients: Included 20 thalassemia patients with Myocardial infarction. Serum samples were subjected for assay of creatine kinase (CK:MB), Lactate dehydrogenase, troponin I, ADMA, Serum MDA level was determined.
RESULTS: Data obtained showed that serum CKMB, LDH1, AST, Troponin T and ADMA levels were significant elevated in MI with or without Thalassemia compared with control groups. Serum MDA was statistically significantly elevated in MI with or without Thalassemia compared with control groups. The serum level of troponin T showed an area under curve (AUC) of 0.92, (sensitivity 91.0 % and specificity, 88%). Also, the ADMA supported the diagnostic profile, showing an AUC of 0.85 with (sensitivity, 92.0%; specificity, 91,9%).
CONCLUSION: Serum ADMA is sensitive marker for incidence of MI in thalassemia patients.

Introduction

Thalassemias are known genetically inherited blood disorders, that can result in abnormal hemoglobin formation. Quite often, the individuals suffer from mild to severe anemia, yellowish skin, enlarged spleen, dark urine, bone problems and slow growth (among children)1. Mainly, there are two types of thalassemias, the alpha thalassemia and the beta thalassemia; their severity is dependent upon the number of missing genes out of four for alpha globin and two for beta globin1. In alpha thalassemia, genes HBA1 and HBA2 (on chromosome 16) are involved, of which, two gene loci are present, and therefore, four alleles exist. As a result of alpha thalassemia, there is a decrease in the alpha-globin production, hence alpha-globin chains production is lowered, which in turn results in an excess of beta chains among the adults and gamma chains in newborns. This excess of beta chains produce tetramers which are unstable (known as hemoglobin H or HbH of 4 beta chains), and show defective oxygen release. In beta thalassemia there are mutations in the HBB gene (on chromosome 11), and the severity depends on the nature and on the presence of mutations in one or both alleles. The clinical picture is described by the situation of both the alleles: β thalassemia major: caused by a β0/β0 genotype, i.e., no functional β chains are formed, most severe form of β-thalassemia. B thalassemia minor: caused by β/β0 or β/β+ genotypes. Here, mutation is present in one of the two β globin alleles, therefore, the production of β chain is not compromised.

Anemia and chronic ineffective erythropoiesis are the characteristics of thalassemia major as its primary problems, so, certain physiological adaptations are produced in the cardiovascular system. People with chronic anemia have an increased cardiac output, so that the oxygen delivery is maintained. This results in increased heart rate and cardiac dimensions. Patients with chronic anemia have higher resting oxygen consumption and lower reserves. With increased resting metabolism, there is also an increase in oxidative stress. Hypersplenism is also found to be common among the people suffering from thalassemia. This condition may require and necessitate the removal of spleen. In the removal of hematologic debris from cardiovascular system, spleen nevertheless has a critical function. Platelet fragments, RBC fragments, phosphatidylserine positive platelets are known strong pro-coagulants. Moreover, they inhibit nitric oxide (a powerful vasodilator) and stimulate substances that promote vasoconstriction, like: endothelin and prostaglandins, and produce endothelial proliferation2. This implies that splenectomy (removal of spleen), may carry a strong risk of intra vascular thrombosis. Individuals suffering from thalassemia acquire excess of iron because of an increase in absorption of iron and transfusion therapy. Iron is known to be toxic to endocrine glands supporting the heart. Iron may poison thyroid and parathyroid glands, thereby affecting metabolism and calcium regulation.

Asymmetric dimethylarginine (ADMA) is a modified amino acid that occurs naturally in human blood, and is known to inhibit nitric oxide production. Nitric oxide plays a key role in vascular tone regulation, thereby has an important contribution in atherosclerosis3,4,5. Studies suggested that higher the values of circulating ADMA level more are incidences of cardiovascular disease (CVD). Studies carried out in mice with elevated ADMA levels (genetically and chemically) exhibited an increase in blood pressure and systemic vascular resistance6,7, on the other hand they showed a decrease in these parameters with low ADMA level8. In addition to this, high ADMA and low NO may result in vascular inflammation9, LDL oxidation10 endothelial cell apoptosis11 aggregation and adhesion of platelets12. Thus, it could be said that ADMA and NO play a crucial role in endothelial dysfunction, which is the first step in atherogenesis, and hence ADMA may also be a risk factor for cardiovascular disease in thalassemia, in a way by inhibition of nitric oxide. Troponin is a complex protein (consisting of three proteins: troponin C, troponin I, and troponin T). Troponin is important in muscle contraction, both in skeletal and cardiac muscles. Troponin I holds actin-tropomyosin complex in place by binding to actin in thin myofilaments, due to which, in a relaxed muscle, myosin cannot bind with actin (letter I stands for inhibitory character). Troponin I is useful in laboratory diagnosis of heart attack.

Due to iron overload, the first cause of death among thalassemia major patients is iron induced cardiac dysfunction (abnormality of pumping and conduction)13,14,15. It was reported that high ferritin (iron containing protein in blood) concentration is related to high troponin levels in patients who are receiving high iron sucrose16. Iron absorption is enhanced by mutations in the hypophis-hypothalamus axis in JAK STAT pathway17. Iron is reportedly deposited in the patients in parenchyma tissues, including the heart. This increase in iron levels results in free radical formation and lipid oxidation of cardio-myocyte membranes, eventually leading to damage18. During cell damage, there is a loss of myocyte contraction force resulting in the release of troponin. Increase in troponin levels can be considered a specific and a sensible biomarker for myocardial injury in the early stages and could be well referred as the beginning of a microinfarct19.

Additional experiments were performed by Yu Han et al20 in which using human umbilical vein endothelial cells (HUVECs) it was shown that the detrimental effect of troponin I (cardiac troponin I)was related to increase in VCAM 1expression (functions as a cell adhesion molecule) induced by troponin I, and adhesion of human monocytes THP-1(a human monocytic cell line derived from an acute monocytic leukemia patient) mediated by VCAM 1 to HUVECs, which could be neutralized by VCAM1 antibody. It was reported that NF-kB and toll-like receptor 4 (TLR4), both had a role involved this signaling pathway. This was inferred due to the fact that troponin I's effect on VCAM 1 expression and adhesion of monocytes to the endothelial cells was inhibited if there was any blockade of either of the two - TLR4 or NF-kB. Furthermore, troponin I augmented cardiac injury in rats with myocardial ischemia- reperfusion injury was reduced after the inhibition of TLR420. They concluded that troponin I aggravates myocardial ischemia- reperfusion injury by induction adhesion of monocytes to vascular endothelial cells by activating TLR4/NF-kB pathway. Thus, inhibiting of TLR4 may prove to be an alternative strategy to reduce troponin I induced myocardial injury20. The rationale of this study was to evaluate serum dimethylarginine and its association to cardiac biomarkers in thalassemia patients for early diagnosis of myocardial infarction to avoid its complications.

Subjects and methods

Informed consent was taken from all individuals included in this study. The study was done according to ethical committee of King Abdulaziz University. This study was conducted on 80 subjects admitted to the Hematology Department, King Abdulaziz University. All individual were subjected to full clinical examination (diabetes, hypertension, cardiovascular disorder). They were classified according to clinical examination to the following groups: Group I: Control group: Included 20 healthy subjects with no evidence for any symptoms of clinical disorder. Group II: Myocardial infarction patients: Included 20 patients all patients of this group were confirmed to have myocardial infarction by clinical examination and elevated serum troponine T. Group III: Thalassemia patients: Included 20 patients who were graded according to blood picture, all patients of this group were confirmed to have thalassemia by clinical examination and hematological parameters. Group IV: Thalassemia with myocardial infarction: Included 20 thalassemia patients with myocardial infarction, all patients of this group were confirmed by clinical examination and hematological parameters. Exclusion criteria included, liver disease, renal dysfunction, hyperplasia and diabetes.

Sample collection

A five ml blood sample was collected from each subject. Serum was separated by centrifugation at 4000 r.p.m for 10 minutes. Serum was stored at −80°C until used. Serum samples were subjected to the following examination. Creatine kinase (CK2:MB), Lactate dehydrogenase (LDH1), Serum Aspartate transaminase, Serum troponin I, by kits from BioLab, Jeddah.

Assay of asymmetric dimethylarginine (ADMA).

Serum ADMA was measured by HPLC15. N-monomethyl L-arginine (NMMA) was used as the internal standard. Serum ADMA was extracted by (NH3 /1M NaOH/waterCH3OH) (10/0.5/40/50; v/v/v/v). The it was derivatized with ortho-phthaldialdehyde (OPA) reagent (1:1; v:v) and injected into the HPLC system, with a fluorescent detector. Chromatographic separation was performed isocratically at 100% mobile phase A, with 25 mmol/L phosphate buffer (pH 6.8) containing 6.5% CH3CN, at a flow rate of 1.1 mL/min. Mobile phase was water:CH3CN (50:50, v:v), and the flow rate was increased to 2.0 mL/min.

Statistical analysis

Statistical analysis will be done by SPSS using student's t-test. Value of P < 0.05 was considered as statistically significant. ANOVA test was performed to correlate between different groups.

Results

Table (1) showed that serum CKMB, LDH1, AST, Troponin T and ADMA levels were significantly elevated in MI with or without Thalassemia compared with control groups (p<0.001) for each. Serum malondialdhyde was statistically significantly elevated in MI with or without Thalassemia compared with control groups (p<0.001). ANOVA analysis showed non-significant changes observed between MI and MI with Thalassemia. Non-significant changes in the levels of hemoglobin in MI compared with control but it was significantly reduced in thalassemia with or without MI. Serum MDA was significantly increased in MI with or without Thalassemia (P < 0.001, p<0.001). The level of serum ADMA level was positively correlated with increase in troponin T (P < 0.01). The cut-off value in 90% patients at the MI with or without Thalassemia 70%. Positive correlations were observed between troponin (r=0.66), and ADMA (r=0.73) while there was no correlation with other laboratory markers such as plasma AST and LDH.

Table (1)

The levels of hemoglobin, activities of serum CK;MB, LDH1 and AST in All studied groups (mean ±SD)

Patients Groups	Control n=20	MI n=20	Thalass. n=20	MI +Thalass. n=20
Parameters
Hemoglobin (g/dl) Mean±SD P1 value P2 value	15.3± 2.1 --- ---	14.3±2.4 <0.001 ---	9.5± 1.2 <0.001 <0.001	10.1± 1.1 <0.001 <0.05
CK:MB (U/L) Mean±SD P1 value P2 value	33.8 ±4.02 --- ---	67.5±5.06 <0.001 ---	31.1± 3.2 <0.001 <0.01	50.3± 5.18 <0.001 <0.01
LDH1 (U/L) Mean±SD P1 value P2 value	62±4.5 --- ---	84±8.7 <0.05 ---	55± 5.8 N.S ---	90.± 9.9 <0.001 <0.001
AST (U/L) Mean±SD P1 value P2 value	22± 2.02 --- ---	81±9.12 <0.001 <0.001	32+ 3 N.S ---	65± 4 <0.001 <0.001

n = number of cases p1 value, thalassemia, Myocardial infarction and thalassemia with Myocardial infarction versus control. p2 value, thalassemia with Myocardial infarction versus Myocardial infarction

Discussion

Contributing to the correct orientation in the therapeutic protocol in management of early myocardial infarction in thalassemia subjects to avoid complications of chronic cardiac dysfunctions, we designed a prospective study to assess the association between plasma ADMA level and incidence of MI in patients with thalessemia.

Data obtained showed that, serum troponin T was significantly elevated in pateints with MI and thalassemia cases, but In MI it was higher statistically (p<0.001). This is indicated that, troponin T was released from muscle heart as a result of heart injury. This is was more sensitive test than myoglobin12.

It was found that in this study, serum ADMA was significantly elevated in MI and thalassemia and MI with thalassemia patents compared with control group (p<0.01, 0.001 and 0.01) respectively. Serum ADMA is a well-characterized circulating endogenous inhibitor of NO synthase6,7, and may compete with L-arginine as the substrate for NO synthase which can lead to decreases in both the production and availability of endothelium-derived NO8. Elevated plasma ADMA level has been associated with MI7,9 and was observed in patients with various risk factors for atherosclerosis10,11. Several studies have shown that plasma ADMA level may predict the progression of renal injury in patients with early-stage MI15,16.

Since NO normally inhibits platelet aggregation and adhesion14,16, any decrease in NO levels may trigger thrombus formation and development on a ruptured plaque. It is documented that NO generated from activated platelets inhibits further platelet recruitment to the developing thrombus17. This is recommended by elevation of cardiac markers CKMB and LDH1 and troponin T25.

High ADMA levels are also associated with elevated cardiac output30, mechanisms that may well be incriminated in the morning occurrence of myocardial infarction6–11.

However, previous studies that investigated the troponin in MI found that it was correlated with ADMA level33.

It was stated that, ADMA was elevated in MI with or without thalassemia but the elevation in thalassemia was higher than without.

AUC; area under curve Receiver operating curve (ROC) analysis was performed to define the diagnostic profile markers among subjects with MI. The serum level of troponin T showed an area under curve (AUC) of 0.92 with (sensitivity 91.0 % and specificity, 88%). Also, the ADMA supported the diagnostic profile, showing an AUC of 0.85 with (sensitivity, 92.0%; specificity, 91,9%).

Conclusion

Assessment of serum ADMA in combination with other routine tests (LDH1, CKMB) and cardiac troponin T may give good prediction for early diagnosis of MI in patients with thalassemia.

Table (2)

The levels of serum troponin T, ADMA and MDA in all studied groups (mean ±SD)

Patients Groups	control n=20	MI n=20	Thalass. n=20	MI ±Thalass. n=20
Parameters
Troponin T (ug/l) Mean±SD P1 value P2 value	71± 10.2 --- ---	140 ±15.3 <0.001 ---	61± 6.8 <0.001 <0.001	110± 13.2 <0.001 <0.001
ADMA (ug/l) Mean±SD P1 value P2 value	3.5± 0.8 --- ---	23.2±1.1 N.S ---	9.7± 2.8 <0.001 <0.001	18.3± 3.2 <0.01 <0.001
MDA (umole/l) Mean±SD P1 value P2 value	16± 2.5 --- ---	33.9± 4.07 <0.001 <0.001	31± 4.07 <0.001 <0.001	43± 5.2 <0.001 <0.01

n = number of cases p1value, thalassemia, Myocardial infarction and thalassemia with Myocardial infarction versus control. p2 value, thalassemia with Myocardial infarction versus Myocardial infarction

Table 3

Receiver operating curve (ROC) analysis of investigated urine parameters as a test for diagnosis of diabetic nephropathy

Variable	ADMA	TropT	CK:MB
AUC	0.91	0.78	0.95
Sensitivity (%)	89 %	92.3%	95.5%
Specificity (%)	90.4%	89.9%	97%

AUC; area under curve Receiver operating curve (ROC) analysis were performed to define the diagnostic profile markers among subjects with MI. The serum level of troponin T showed an area under curve (AUC) of 0.92 with (sensitivity 91.0 % and specificity, 88%). Also, the ADMA supported the diagnostic profile, showing an AUC of 0.85 with (sensitivity, 92.0%; specificity, 91,9%).