Epidemiology of homocysteine as a risk factor in diabetes

Patients with diabetes mellitus are prone to cardiovascular disease, and risk factors presumably unrelated to diabetes, such as hyperhomocysteinemia, may be involved in the atherothrombotic process in these subjects. Plasma homocysteine levels are usually normal in diabetes, although both lower and higher levels have been reported. This has been ascribed to hyperfiltration and renal dysfunction or low folate status, respectively. Insulin resistance does not appear to be a major determinant of plasma homocysteine level. Hyperhomocysteinemia has been associated with microalbuminuria and retinopathy in type 1 and type 2 diabetes. In patients with type 2 diabetes, plasma homocysteine concentration has also been shown to be related to macrovascular disease and death. This relation seems to be stronger in subjects with diabetes than without. The underlying pathophysiological mechanism of this increased vascular risk remains unexplained, but may relate to worsening of endothelial dysfunction or structural vessel properties. Because homocysteine and diabetes have an apparent synergistic detrimental vascular effect, patients with diabetes are good candidates for screening and treatment with folic acid until the results of ongoing clinical trials are available.     

Plasma homocysteine concentrations in type II diabetic patients in India: relationship to body weight

Hyperhomocysteinemia has been established as a risk factor for cardiovascular disease and occurs with a high prevalence in patients with type II diabetes and microvascular disease. In order to determine whether plasma homocysteine concentrations vary with body-mass index in patients with type II diabetes, we measured plasma homocysteine in lean, normal weight, and overweight subjects living in India. Plasma homocysteine concentrations were significantly lower in the lean persons with diabetes when compared to those who were obese and compared to control subjects (p < 0.02). We conclude that plasma homocysteine concentrations are lower in lean persons with type II diabetes and that this efficiency in homocysteine metabolism may contribute towards protection from cardiovascular disease in this population.     

Homocysteine and atherothrombosis: Diagnosis and treatment

Hyperhomocysteinemia has long been recognized as a risk factor for cardiovascular disease. Many cross-sectional and retrospective case-control studies have shown an association between elevated total homocysteine levels and coronary, peripheral, and cerebral vascular disease; prospective studies, however, have been inconsistent. Overall, there is evidence to suggest a modest association between elevated homocysteine levels and cardiovascular disease risk. Folate supplementation has been shown to reduce plasma homocysteine even when levels are in the normal range. Clinical studies suggest that lowering plasma homocysteine may improve endothelial dysfunction, a marker of atherothrombotic risk. The long-term effects of folate supplementation on homocysteine levels and cardiovascular disease risk await the results of ongoing clinical trials. However, several recent studies suggest a benefit for reduction of plasma homocysteine levels, as individuals with lower homocysteine have reduced cardiovascular event rates.     

Vitamins,homocysteine and cardiovascular risk

A raised plasma level of the amino acid homocysteine is associated with increased risk of cardiovascular disease. This association may be causal—it is biologically plausible, fairly strong, graded, and an increase in plasma homocysteine preceeds the onset of vascular disease.Plasma homocysteine levels are controlled by genetic and nutritional factors, notably folate, vitamin B12 and vitamin B6 intakes. Folic acid in particular lowers plasma homocysteine levels by about 25%. It is not known if this cheap and safe treatment reduces vascular disease risk. Current randomized control trials are addressing this issue, and proof or otherwise of causality must await their results.Homocysteine may also interact with conventional risk factors such as smoking to substantially increase their effect on risk. Thus meticulous risk factor control may be particulary important in subjects at high total cardiovascular risk who also have a raised plasma homocysteine level, and folic acid supplementation may be considered in such individuals.     

Plasma homocysteine, oxidative stress and endothelial function in patients with Type 1 diabetes mellitus and microalbuminuria.

AIMS: The purpose of this study was to examine the associations between endothelial function, plasma homocysteine and oxidative stress in patients with Type 1 diabetes mellitus (DM) and microalbuminuria compared with DM patients with normoalbuminuria and non-diabetic control subjects. We wished to test the hypothesis that increased cardiovascular risk in patients with Type 1 diabetes and microalbuminuria may be in part as a result of hyperhomocysteinaemia-mediated oxidative stress leading to impaired endothelial function. METHODS: We measured forearm blood flow, total plasma homocysteine, total antioxidant status (TAOS) and whole blood glutathione in 31 DM patients, 16 with microalbuminuria and 15 with normoalbuminuria, and 15 non-diabetic control subjects. RESULTS: Plasma homocysteine levels were significantly higher in the microalbuminuric diabetic patients compared with the normoalbuminuric patients and the control subjects. TAOS was significantly lower in the micoalbuminuric and normoalbuminuric diabetic patients compared with the control subjects, although TAOS levels were similar in both groups of diabetic patients. There was no difference in forearm blood flow between the groups and no association between measured endothelial function and antioxidant defence/oxidative stress and homocysteine in each group. There was no association between plasma total homocysteine and TAOS or whole blood glutathione within the groups. CONCLUSIONS: We have found mild hyperhomocysteinaemia in microalbuminuric DM patients compared with normoalbuminuric DM patients and non-diabetic subjects and some evidence for reduced antioxidant defence in DM patients. These findings add to our understanding of the increased risk of vascular disease in patients with Type 1 diabetes.     

Reduced plasma total homocysteine concentrations in Type 1 diabetes mellitus is determined by increased renal clearance.

INTRODUCTION: Elevated plasma levels of total homocysteine are related to the development of vascular complications. Patients with diabetes mellitus are particularly at risk for the development of these complications. Several factors determine plasma total homocysteine including renal function. AIMS: As early Type 1 diabetes is characterized by a relative glomerular hyperfiltration, increased renal clearance could contribute to decreased levels of homocysteine as observed in Type 1 diabetes mellitus. Therefore we investigated the relationship between plasma total homocysteine and the glomerular filtration rate (GFR). METHODS: In 92 Type 1 diabetes patients and 44 control subjects, we measured GFR and effective renal plasma flow (ERPF) by means of continuous infusion of inulin and p-aminohippurate. Fasting plasma total homocysteine was measured using high performance liquid chromatography. RESULTS: GFR (121 +/- 21 resp. 104 +/- 14 ml/min; P < 0.001) and ERPF (563 +/- 127 resp. 516 +/- 121 ml/min; P = 0.05) were significantly higher in Type 1 diabetes patients as compared with control subjects. Plasma total homocysteine was reduced in Type 1 diabetes patients as compared with control subjects (11.0 +/- 4.5 resp. 13.4 +/- 7 micromol/l; P = 0.01). Plasma total homocysteine was strongly correlated with GFR (Type 1 diabetes patients: r = -0.43, P < 0.001; control subjects: r = -0.39, P = 0.01). CONCLUSION: GFR is a major determinant of plasma total homocysteine levels in Type 1 diabetes patients as well as control subjects. The reduced plasma total homocysteine levels in diabetes patients can be explained by an increased GFR.     

Plasma homocysteine levels in patients with isolated coronary artery ectasia

OBJECTIVE: Hyperhomocysteinemia is recognized as an independent risk factor for arterial disease including coronary artery disease, cerebrovascular disease and peripheral vascular disease. Previously, an association between increased plasma homocysteine level and peripheral arterial aneurysms has been reported. However, the relationship between coronary artery ectasia (CAE) and plasma homocysteine level has not been investigated. Accordingly, this study was designed to investigate plasma homocysteine level in patients with isolated CAE. METHODS: Thirty-two patients with isolated CAE without significant stenosis and 30 control subjects with angiographically normal coronary arteries were included in this study. Fasting plasma homocysteine concentrations were measured by Fluorescence Polarization Immunoassay method using homocysteine kids. Hyperhomocysteinemia is defined as plasma homocysteine levels above the 95th percentile of the control subjects (13.6 mumol/l). RESULTS: According to the definition of hyperhomocysteinemia, 19 (59%) of patients with isolated CAE had elevated levels of plasma homocysteine compared to 2 (7%) in the control subjects with angiographically normal coronary arteries (p<0.001). In addition, patients with isolated CAE had significantly higher levels of plasma homocysteine compared to control subjects (14.9+/-4.5 micromol/l vs. 8.6+/-1.9 micromol/l respectively, p<0.001). Besides, we detected a significant positive correlation between the number of ectasic segment and plasma homocysteine level (r=0.537, p=0.002). CONCLUSION: We have shown for the first time an association between elevated plasma homocysteine level and isolated CAE. Larger prospective studies are needed to confirm the role of hyperhomocysteinemia in CAE and to evaluate the usefulness of homocysteine-lowering therapies.     

Homocysteine, a risk factor for cardiovascular disease

Fasting hyperhomocysteinemia is an independent risk factor for coronary artery disease, stroke, peripheral vascular atherosclerosis, and for arterial and venous thromboembolism. The risk for cardiovascular disease with homocysteine is similar to conventional risk factors. The interaction of hyperhomocysteinemia with hypertension and smoking is strong and the combined effect is more than multiplicative. The combined effect of homocysteine and cholesterol is additive. Homocysteine produces atherosclerosis, thromboembolism, and vascular endothelial cell injury. Vascular dysfunction produced by homocysteine may be due to endothelial cell damage. Homocysteinemia-induced atherosclerosis is probably due to various factors including endothelial cell injury, inability to sustain S-nitroso-homocysteine formation because of imbalance between production of nitric oxide by dysfunctional endothelium and homocysteine, smooth muscle cell proliferation, and thromboembolism. There is strong evidence that endothelial cell injury is associated with oxidative stress produced by homocysteine. Hyperhomocysteinemia is associated with numerous conditions, including coronary disease, stroke, peripheral vascular disease (carotid artery and cerebrovascular atherosclerosis), venous thrombosis, renal disease, diabetes mellitus, and organ transplant. Folic acid, vitamin B₁₂ and B₆ have been shown to be beneficial in reducing plasma homocysteine levels. Folic acid is specifically very effective, safe and inexpensive.     

Changes in plasma levels of homocysteine in patients with acute pancreatitis

The role of homocysteine role in inflammation and malignancy has been studied experimentally. Some researchers suggest that a relationship exists between pancreatitis and homocystinuria, possibly being secondary to occlusive vascular disease of the pancreas. To date, plasma homocysteine levels in pancreatic disease have not been studied. We aimed to analyze the homocysteine status in patients with acute pancreatitis, and the changes of the plasma homocysteine level at the acute phase of the disease and six months after hospital discharge. Fourteen acute pancreatitis patients and 14 healthy subjects were studied. Plasma homocysteine, vitamin B12, folate, amylase, lipase, C-reactive protein, total, HDL and LDL cholesterol, triglycerides, blood urea nitrogen, white blood cells, and creatinine were measured in the two groups of subjects. Plasma levels of homocysteine were significantly higher in patients with acute pancreatitis as were serum creatinine, blood urea nitrogen, WBC counts, amylase, lipase, and C-reactive protein. An impaired creatinine clearance was also found in these patients but this did not reach statistical significance. Serum total, HDL, and LDL cholesterol concentrations were not significantly different between the two groups of subjects. Our data suggest that homocysteine may play a role in inflammatory diseases of the pancreas. Increased plasma homocysteine levels in acute pancreatitis may be a reason, or a marker, for the diagnosis of acute pancreatitis. In conclusion, this is the first report showing that patients with acute pancreatitis have higher plasma homocysteine levels than healthy subjects.     

Hyperhomocysteinemia, vascular pathology, and endothelial dysfunction

Hyperhomocysteinemia has been associated with premature atherothrombotic vascular disease. It is not known whether hyperhomocysteinemia induces a distinct type of vascular disease. Its interaction, if any, with traditional risk factors also remains unclear. The pathophysiological mechanisms linking hyperhomocysteinemia to vascular disease have been extensively studied in vitro and in animals. From these studies, it has been suggested that homocysteine limits the bioavailability of nitric oxide (NO), increases oxidative stress, stimulates smooth cell proliferation, and alters elastic wall properties. The relevance of these proposed mechanisms in vivo is unclear, because clinical studies have yielded controversial results with regard to the relation between plasma homocysteine levels and indices of endothelial function, such as brachial artery flow-mediated vasodilatation and plasma levels of endothelium-derived marker proteins. Up till now, there have been no controlled data on the effects of homocysteine-lowering treatment on vascular function or clinical end points. The precise mechanisms (if any) by which homocysteine mediates its adverse vascular effects are in fact unknown but may relate to impaired endothelial and smooth muscle cell function.     

Endothelial dysfunction and atherothrombosis in mild hyperhomocysteinemia

Mildly elevated plasma homocysteine levels are an independent risk factor for atherothrombotic vascular disease in the coronary, cerebrovascular, and peripheral arterial circulation. Endothelial dysfunction as manifested by impaired endothelium-dependent regulation of vascular tone and blood flow, by increased recruitment and adhesion of circulating inflammatory cells to the endothelium, and by a loss of endothelial cell antithrombotic function contributes to the vascular disorders linked to hyperhomocysteinemia. Increased vascular oxidant stress through imbalanced thiol redox status and inhibition of important antioxidant enzymes by homocysteine results in decreased bioavailability of the endothelium-derived signaling molecule nitric oxide via oxidative inactivation. This plays a central role in the molecular mechanisms underlying the effects of homocysteine on endothelial function. Supplementation of folic acid and vitamin B12 has been demonstrated to be efficient in lowering mildly elevated plasma homocysteine levels and in reversing homocysteine-induced impairment of endothelium-dependent vasoreactivity. Results from ongoing intervention trials will determine whether homocysteine-lowering therapies contribute to the prevention and reduction of atherothrombotic vascular disease and may thereby provide support for the causal relationship between hyperhomocysteinemia and atherothrombosis.     

Folic acid improves endothelial dysfunction in type 2 diabetes--an effect independent of homocysteine-lowering

Diabetes is associated with endothelial dysfunction, which in part may be related to uncoupling of the endothelial nitric oxide (NO) synthase enzyme, thus reducing the availability of NO. As folates may potentially reverse the uncoupling of NO synthase, we wanted to determine whether folic acid supplementation could modulate endothelial function and markers of inflammation in patients with type 2 diabetes without vascular disease. Nineteen patients with type 2 diabetes were treated with folic acid (10mg/day for 2 weeks) versus placebo in a randomized, placebo-controlled, cross-over study with an 8-week washout period between treatments. Fasting endothelium-dependent flow-mediated dilatation (FMD) of the brachial artery, endothelium-independent nitroglycerin-mediated dilatation (NMD), plasma homocysteine, serum lipids, folate, and inflammatory markers (high-sensitivity C-reactive protein, soluble intercellular adhesion molecule-1 and vascular cell adhesion molecule-1, interleukin-18, tumor necrosis factor-alpha) were assessed after each 2-week treatment period. Folic acid supplementation significantly increased folate levels and lowered plasma homocysteine levels. Folic acid significantly improved FMD compared to placebo (5.8 +/- 4.8% vs 3.2 +/- 2.7%, p = 0.02). There were no significant effects of folic acid supplementation on lipids, NMD, or the inflammatory markers. There was no relationship between the change in homocysteine and the improvement in FMD. Thus, 2 weeks of folic acid supplementation can improve endothelial dysfunction in type 2 diabetics independent of homocysteine-lowering, but does not modulate markers of inflammation.     

Mild hyperhomocysteinemia: risk factor or just risk predictor for cardiovascular diseases?

Elevated plasma levels of homocysteine (hyperhomocysteinemia) are increasingly recognized as a potential risk for atherothrombotic vascular diseases by numerous epidemiological and clinical studies. There are increasing experimental data that indicate mechanisms by which homocysteine may alter the vasculature in a way that predisposes to atherosclerotic vascular disease. A key event in the vascular pathobiology of hyperhomocysteinemia seems to involve the induction of endothelial dysfunction due to a reduction of the endogenous antiatherothrombotic molecular nitric oxide. Elevated homocysteine levels can be efficiently and safely reduced in most of hyperhomocysteinemic patients by supplementation of folic acid and cobalamin. This reduction is associated with an improvement in endothelial function and other surrogate markers of atherothrombosis, like carotid plaque area and the rate of abnormal stress electrocardiograms. Whether or not this translates into clinical benefits, is still under investigation. The first clinical study on homocysteine-lowering vitamin supplementation in patients that had undergone coronary intervention showed a benefitial effect on the rate on restenosis and the need for revascularization which translated into a reduction of major coronary events. In contrast, in three larger scaled secondary intervention trials in patients with stable coronary disease or post non-disabling stroke, vitamin supplementation had no effect on future vascular events although baseline homocysteine levels were significantly associated with a worse prognosis. Until the results of more clinical trials are available, the clinical relevant question whether or not homocysteine is just a risk predictor or a modifiable risk factor can not definitely be answered.     

Coronary artery disease - free radical damage, antioxidant protection and the role of homocysteine

Traditional risk factors for coronary artery disease (CAD) can only explain approximately two thirds of observed clinical events. This has maintained interest in other nutritional and biochemical factors that might contribute to the underlying pathophysiology of vascular disease. Two such factors are dietary antioxidants and plasma homocysteine. Established risk factors such as hypertension, smoking and diabetes mellitus are all associated with increased oxidative stresses due to excess free radical activity in the vascular wall. This may facilitate the development of vascular disease because of (i) increased oxidation of low-density lipoprotein (LDL) particles which increases their propensity to deposition in the vascular wall, (ii) inactivation of endotheliumderived nitric oxide, and (iii) direct cytotoxicity to endothelial cells. Protective antioxidant molecules include vitamin C and vitamin E of which the latter is lipid soluble and is the primary antioxidant defence in circulating LDL particles. Epidemiological studies have suggested strongly that individuals who have high circulating concentrations or dietary intake of natural antioxidant vitamins are protected against vascular disease events (18). Furthermore, many studies have demonstrated a beneficial effect of natural and synthetic antioxidants on surrogate markers of vascular disease such as endothelial function and lipoprotein oxidation. However, large prospective randomized controlled intervention trials, mostly involving vitamin E (e.g. CHAOS, HOPE (22)), have failed to demonstrate any beneficial effect upon vascular mortality in high risk individuals. Possible reasons for these disappointing results include the pro-oxidant effects of high dose antioxidant supplements, particularly in patients with established vascular disease. Homocysteine is a sulphydryl-containing amino acid derived from the demethylation of dietary methionine. Epidemiological studies over 30 years have shown that increased concentrations of homocysteine are associated with vascular disease. This link is independent of other risk factors, is consistent across many studies and is strongly dose-related. Recently, evidence has accumulated to suggest that this link is also biologically plausible because homocysteine promotes oxidant injury to the vascular endothelium, impairs endothelium-dependent vasomotor regulation and may also alter the coagulant properties of the blood. Plasma homocysteine levels can be reduced by dietary supplements of folic acid and B vitamins. Studies are currently being undertaken to examine the impact of these vitamins in high risk patients and, thereby, establish a causative role for homocysteine in promoting vascular events.     

Plasma homocysteine level and development of coronary artery disease

BACKGROUND: The plasma level of homocysteine is an independent risk factor for atherosclerotic vascular disease. The relationship between plasma homocysteine level and the onset of coronary artery disease (CAD) has not been established. OBJECTIVE: To investigate the relationship between plasma homocysteine level and the age at which CAD was diagnosed. METHODS: Fifty-seven male patients aged < or = 65 years (mean age 53 years) with angiographically proven symptomatic CAD seen consecutively and 138 age-matched male control subjects (mean age 52 years) free from atherosclerotic vascular disease were studied. They were divided into two subgroups, a group of younger subjects (aged < or = 55 years) and a group of older subjects (aged 56-65 years). RESULTS: Plasma homocysteine levels in CAD patients significantly exceeded those of control subjects (means 13.4 versus 10.6 nmol/ml, P = 0.0002). Plasma homocysteine level of subjects in younger CAD group was significantly higher than that of subjects in older CAD group (15.0 versus 11.3 nmol/ml, P = 0.03), and age and logarithmically transformed plasma homocysteine level exhibited a significant negative correlation (r = -0.28, P = 0.03) for subjects in CAD group. Among control subjects, members of our two age subgroups had similar plasma homocysteine levels. Younger CAD patients had significantly higher plasma homocysteine levels than did younger controls (15.0 versus 10.4 nmol/ml, P < 0.0001). However, for older groups there was no significant difference between plasma homocysteine levels in CAD patients and controls (11.3 versus 10.9 nmol/ml). Multiple regression analysis showed that only logarithmically transformed plasma homocysteine level was a significant predictor for age of onset of CAD. CONCLUSION: An elevated level of plasma homocysteine is more important in the development of premature CAD than it is in that of late-onset CAD among men.     

Increased plasma levels of N-terminal brain natriuretic peptide (NT-proBNP) in type 2 diabetic patients with vascular complications

AIMS: The plasma levels of either brain natriuretic peptide (BNP) or the N-terminal fragment of the prohormone (NT-proBNP) have recently gained extreme importance as markers of myocardial dysfunction. Patients with type 2 diabetes are at high risk of developing cardiovascular complications. This study was aimed to assess whether plasma NT-proBNP levels are at similar levels in type 2 diabetics with or without overt cardiovascular diseases. METHODS: We assayed plasma NT-proBNP in 54 type 2 diabetics, 27 of whom had no overt macro- and/or microvascular complications, while the remaining ones had either or both. The same assay was carried out in 38 healthy control subjects age and sex matched as a group with the diabetics. RESULTS: Plasma NT-proBNP was higher in diabetics (median 121 pg/ml, interquartile range 50-240 pg/ml, ) than in those without complications (37 pg/ml, 21-54 pg/ml, P<0.01). Compared with the controls (55 pg/ml, 40-79 pg/ml), only diabetics with vascular complications had significantly increased plasma NT-proBNP levels (P<0.001). In the diabetics, coronary heart disease and nephropathy (defined according to urinary excretion of albumin) were each independently associated with elevated values of plasma NT-proBNP. CONCLUSIONS: In type 2 diabetes mellitus, patients with macro- and/or micro-vascular complications exhibit an elevation of plasma NT-proBNP levels compared to corresponding patients with no evidence of vascular disease. The excessive secretion of this peptide is independently associated with coronary artery disease and overt nephropathy. The measurement of circulating NT-proBNP concentration may therefore be useful to screen for the presence of macro- and/or microvascular disease.     

Homocysteine and cardiovascular disease

Research over the past decade has shown that elevated levels of homocysteine have a strong association with all forms of atherothrombotic disease and venous thromboembolism. This association is particularly strong for coronary disease and newer data indicate that screening for homocysteine levels may be warranted in those with unexplained thrombotic tendencies and in young patients who develop coronary events or disease without the usual predisposing factors such as hypertension, smoking, hypercholesterolemia, or diabetes. Although the link between hyperhomocysteinemia and cardiac disease has not been conclusively shown to be causal as yet, data are emerging that lowering homocysteine levels may be beneficial in patients at high risk. Such lowering can be done safely and inexpensively with increased intake of fruits and vegetables and in those patients who are particularly at high risk using supplementation with folic acid and the B vitamins. Preliminary studies have shown that lowering homocysteine levels in this manner may slow the progression of atherosclerosis in coronary and carotid vessels. No mortality data exist yet showing that reducing homocysteine reduces cardiac or total mortality, although it is likely that ongoing and planned trials that are underway will shed light on these important questions soon.     

Role of hyperhomocystinemia in retinal vascular occlusive disease.

Elevated plasma homocysteine (Hcy) level is considered a risk factor for vascular diseases. In recent years, many scientific reports have suggested that hyperhomocystinemia may be associated with an increased risk of retinal vascular occlusive disease (RVOD). The prevalence of elevation of homocysteine in patients with a recent retinal vascular occlusion was compared to a health control group in this study. Forty-nine consecutive patients (22 M; 27 F) (age 26-85 years, mean 69) with diagnosis of retinal vascular occlusion were compared with 71 healthy controls. These patients underwent laboratory evaluation for plasma fasting total homocysteine, activated protein C resistance, protein C, protein S, antithrombin III, and antiphospholipid and anticardiolipin antibodies. The G20210 prothrombin gene mutation (FII G20210A) and Factor V Leiden mutation (FVL) were evaluated. None of these enrolled subjects had other prothrombic risk factors. The health control group consisted of healthy subjects from the general population, with no history or clinical evidence of retinal vascular disease, recruited during the same 2-year period. High fasting homocystinemia (higher than 15 mumol/L) was detected in 24/49 subjects (48.9%) (P < .0005). There was a high prevalence of hyperhomocystinemia: these data suggest an association between RVOD and high fasting homocystinemia. Elevated homocysteine may be an independent risk factor, and its assessment may be important in the investigation, management, and follow-up of patients with RVOD. Further controlled studies are necessary to clarify the exact role of hyperhomocystinemia in RVOD and to evaluate the appropriate therapeutic approach.     

Redox status of plasma homocysteine and other plasma thiols in stroke patients

Despite the growing evidence that plasma homocysteine is a cardiovascular risk factor, the mechanism behind the vascular injuries is still unknown. Studies are difficult as a result of the fact that little is known about the formation of different homocysteine species in vivo. Since extracellular glutathione and cysteine may influence the formation of different homocysteine species, we have in the present study investigated the different fractions of homocysteine and their relation to the different fractions of glutathione and cysteine in stroke patients and control subjects. We found a ratio of about 32-33% between reduced and total plasma glutathione concentrations and 2.6 3.0% between reduced and total plasma cysteine concentrations both in patients and in healthy control subjects. We noted an elevated concentration of total plasma homocysteine in stroke patients, but no difference in the ratio between reduced and total plasma homocysteine concentrations in patients and control subjects (mean value 1.20 and 1.10%, respectively). However, in a subgroup of patients with higher concentrations of total plasma homocysteine, we observed a significantly lower ratio of reduced to total plasma homocysteine compared to a subgroup of patients with lower concentration of total plasma homocysteine. A low reduced/total ratio of plasma homocysteine in combination with elevated plasma homocysteine concentrations might reflect an increased pro-oxidant activity in plasma from these patients. Thus, increased pro-oxidant activity in plasma might be one factor, besides genetic and nutritional factors, that could explain hyperhomocysteinemia. Since substantial evidence indicates that progression of atherosclerosis is related to enhanced pro-oxidant activity, the premature vascular disease associated with increased plasma homocysteine concentration might be as a result of increased pro-oxidant activity and the elevated plasma homocysteine concentration may only reflect the increased oxidative stress.     

Plasma homocysteine is related to albumin excretion rate in patients with diabetes mellitus: a new link between diabetic nephropathy and cardiovascular disease?

Summary The high risk of cardiovascular disease in patients with diabetes mellitus, particularly in those with nephropathy, is not completely explained by classical risk factors. A high plasma homocysteine concentration is an independent risk factor for cardiovascular disease but information on its association with diabetes is limited. Fasting homocysteine concentrations were measured in the plasma of 165 diabetic patients (75 with insulin-dependent [IDDM]; 90 with non-insulin-dependent diabetes [NIDDM]) and 56 non-diabetic control subjects. Other measurements included the prevalence of diabetic complications, glycaemic control, lipid and lipoprotein levels, vitamin status and renal function tests. Patients with NIDDM had higher homocysteine levels than control subjects, whereas IDDM patients did not (9.2 ± 4.5 vs 7.7 ± 2 μmol/l, p < 0.01; and 7.0 ± 3 vs 7.4 ± 2 μmol/l, NS). Univariate correlations and multiple regression analysis showed albumin excretion rate to be the parameter with the strongest independent association with homocysteine. Patients with both types of diabetes and nephropathy had higher plasma homocysteine concentrations than those without nephropathy. Increases of homocysteine in plasma were related to increases in the severity of the nephropathy. Fasting hyperhomocysteinaemia was considered as the mean of the plasma homocysteine for all control subjects (7.5 ± 2.1 μmol/l) + 2 SD (cut-off =11.7 μmol/l). Nephropathy was present in 80 % of diabetic patients with fasting hyperhomocysteinaemia. In conclusion, increases in fasting homocysteine in diabetic patients are associated with increased albumin excretion rate, especially in those with NIDDM, thus providing a potential new link between microalbuminuria, diabetic nephropathy and cardiovascular disease. [Diabetologia (1998) 41: 684–693] Received: 4 August 1997 and in final revised form: 4 February 1998