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.     

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.     

Hyperhomocysteinemia,vascular function and atherosclerosis: effects of vitamins

Homocysteine is a metabolic product of methyl group donation by the amino acid methionine. Moderate elevation of plasma homocysteine (>15 M) is most commonly caused by B-vitamin deficiencies, especially folic acid, B₆ and B₁₂. Genetic factors, certain drugs and renal impairment may also contribute. Homocysteine has several potentially deleterious vascular actions. These include increased oxidant stress, impaired endothelial function, stimulation of mitogenesis, and induction of thrombosis. Homocysteine also appears to increase arterial pressure. In humans, experimental induction of hyperhomocysteinemia by methionine loading rapidly causes profound impairment of endothelium-dependent dilatation in both resistance and conduit arteries. This endothelial dysfunction can be reversed by administration of antioxidants. Epidemiological evidence suggests that homocysteine acts as an independent risk factor for atherosclerosis, thrombosis and hypertension. Prospective studies have shown that elevated plasma homocysteine concentrations in the top quintile of the population (>12 M) increase risk of cardiovascular disease by about 2-fold. There are currently no data available from randomized, controlled trials of the effects of lowering plasma homocysteine on atherothrombotic events. Nonetheless, it would seem appropriate to screen for and treat hyperhomocysteinemia in individuals with progressive or unexplained atherosclerosis. Folic acid and vitamins B₆ and B₁₂ are the mainstay of therapy. Treatment of moderately elevated plasma homocysteine in patients without atherosclerosis should be deferred until the completion of randomized outcome trials.     

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.     

Homocysteine hypothesis for atherothrombotic cardiovascular disease: not validated.

Homocysteine has been implicated in promoting atherosclerotic and thrombotic vascular disease. During the last decade, the utility of homocysteine in predicting risk for atherothrombotic vascular disease has been evaluated in several observational studies in a large number of patients. These studies show that the overall risk for vascular disease is small, with prospective, longitudinal studies reporting a weaker association between homocysteine and atherothrombotic vascular disease compared to retrospective case-control and cross-sectional studies. Furthermore, randomized controlled trials of homocysteine-lowering therapy have failed to prove a causal relationship. On the basis of these results, there is currently insufficient evidence to recommend routine screening and treatment of elevated homocysteine concentrations with folic acid and other vitamins to prevent atherothrombotic vascular disease. This review outlines the metabolism and pathophysiology of homocysteine, highlights the results of homocysteine observational and interventional trials, and presents areas of uncertainty and potential future work.     

Homocysteine hypothesis for atherothrombotic cardiovascular disease: not validated

Homocysteine has been implicated in promoting atherosclerotic and thrombotic vascular disease. During the last decade, the utility of homocysteine in predicting risk for atherothrombotic vascular disease has been evaluated in several observational studies in a large number of patients. These studies show that the overall risk for vascular disease is small, with prospective, longitudinal studies reporting a weaker association between homocysteine and atherothrombotic vascular disease compared to retrospective case-control and cross-sectional studies. Furthermore, randomized controlled trials of homocysteine-lowering therapy have failed to prove a causal relationship. On the basis of these results, there is currently insufficient evidence to recommend routine screening and treatment of elevated homocysteine concentrations with folic acid and other vitamins to prevent atherothrombotic vascular disease. This review outlines the metabolism and pathophysiology of homocysteine, highlights the results of homocysteine observational and interventional trials, and presents areas of uncertainty and potential future work.     

Mildly elevated homocysteine concentrations impair endothelium dependent vasodilation in hypercholesterolemic patients

BACKGROUND: Elevated low density lipoproteins (LDL)-cholesterol and homocysteine levels have both been found to be associated with an increased risk for atherosclerotic vascular disease. To assess the effects of elevated homocysteine levels in hypercholesterolemic subjects on endothelial function, we examined basal and stimulated nitric oxide (NO) mediated vasodilation in the forearm vascular bed in hypercholesterolemic subjects with normal or elevated homocysteine levels. METHODS: Twenty-seven white subjects (age: 48 +/- 12 years) with elevated LDL-cholesterol (> or = 160 mg/dl) were divided into two groups with normal (n = 11) or mildly elevated (n = 16) homocysteine plasma concentration. We used strain gauge plethysmography to measure changes in forearm blood flow in response to intraarterial administration of increasing doses of acetylcholine (3, 12, 24, 48 microg/min), sodium nitroprusside (200, 800, 3200 ng/min), and N-monomethyl L-arginine (L-NMMA) (1, 2, 4 micromol/min). Total homocysteine plasma concentrations were determined by high performance liquid chromatography fluorimetry. RESULTS: Endothelium independent vascular relaxation tested by i.a. sodium nitroprusside and changes in forearm blood flow after i.a. L-NMMA indicating basal production and release of nitric oxide were similar between the two groups with normal or elevated homocysteine levels. In contrast, endothelium dependent vasodilation as assessed by the administration of i.a. acetylcholine differed between the groups with normal or elevated homocysteine levels for all doses tested (MANOVA P < 0.01: ACH 48 microg/min: 480 +/- 237% with normal vs 234 +/- 130% with elevated homocysteine; P < 0.002). This was significant even after taking possible covariates such as age, blood pressure, body mass index, LDL-, high density lipoproteins (HDL)-cholesterol, and trigylcerides into account (MANOVA P < 0.02). CONCLUSIONS: From our study we conclude that homocysteine impairs endothelium dependent vasodilation in subjects with elevated LDL-cholesterol levels. The most intriguing finding is that even mildly elevated homocysteine levels seem to be of crucial importance for deterioration of endothelial function, especially if other cardiovascular risk factors such as hypercholesterolemia preexist.     

Homocysteine, folic acid and coronary artery disease: possible impact on prognosis and therapy

Within the past four decades, the efforts of investigators worldwide have established the amino acid homocysteine (Hcy) as an important factor in arteriosclerosis and ageing. The amino acid homocysteine is a unique candidate for the study of different age-related pathological conditions, namely vascular diseases, dementia disorders and late-life depression, due to its multiple roles in different pathways leading to atherosclerosis and neurotoxicity. Especially, the role of homocysteine in predicting risk for atherothrombotic vascular disease has been evaluated in several observational studies in a large number of patients. These studies show that the overall risk for vascular disease is small, with prospective, longitudinal studies reporting a weaker association between homocysteine and atherothrombotic vascular disease compared to retrospective case-control and cross-sectional studies. Furthermore, randomised controlled trials of homocysteine-lowering therapy have failed to prove a causal relationship. On the basis of these results, there is currently insufficient evidence to recommend routine screening and treatment of elevated homocysteine concentrations with folic acid and other vitamins to prevent atherothrombotic vascular disease.     

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.     

Homocysteine enhances neutrophil-endothelial interactions in both cultured human cells and rats In vivo

Despite intense investigation, mechanisms linking the development of occlusive vascular disease with elevated levels of homocysteine (HCY) are still unclear. The vascular endothelium plays a key role in regulating thrombogenesis and thrombolysis. We hypothesized that vascular lesions in individuals with elevated plasma HCY may be related to a dysfunction of the endothelium triggered by HCY. We investigated the effect of HCY on human neutrophil adhesion to and migration through endothelial monolayers. We also examined the effect of HCY on leukocyte adhesion and migration in mesenteric venules of anesthetized rats. We found that pathophysiological concentrations of HCY in vitro induce increased adhesion between neutrophils and endothelial cells. This contact results in neutrophil migration across the endothelial layer, with concurrent damage and detachment of endothelial cells. In vivo, HCY infused in anesthetized rats caused parallel effects, increasing leukocyte adhesion to and extravasation from mesenteric venules. Our results suggest that extracellular H2O2, generated by adherent neutrophils and/or endothelial cells, is involved in the in vitro endothelial cell damage. The possibility exists that leukocyte-mediated changes in endothelial integrity and function may lead to the vascular disease seen in individuals with elevated plasma HCY.     

Diabetes mellitus and hyperhomocysteinemia

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 diabetics than in subjects without diabetes. 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 negative vascular effect, patients with diabetes are good candidates for screening and treatment with folic acid until the results of ongoing clinical trials are available.     

Mechanisms of Venous and Arterial Thrombosis in Heparin-Induced Thrombocytopenia

This pictorial introduction to homocysteine illustrates at a glance the nature of homocysteine and its role in cardiovascular disease by means of eight simple figures and an essential bibliography. Homocysteine is a sulfur-containing metabolite of methionine. Conversion back to methionine or transsulfuration to cysteine are the two major metabolic pathways that reduce total homocysteine (tHcy) concentrations in cells and blood. B vitamins are essential cofactors in homocysteine metabolism. Median fasting total homocysteine levels in adult males are 10 µmol/L. Increased plasma tHcy concentrations are found with methionine-rich diets, low vitamin B intake, male gender, age, impaired renal function, and genetically determined defects of the enzymes involved in homocysteine metabolism. An inverse relation exists between plasma tHcy and circulating folate or vitamin B₆ concentrations, and folic acid supplements of 0.5 mg/d can reduce tHcy levels by 25%. Homocystinuric patients, who have severe hyperhomocysteinemia, die prematurely of atherothrombotic disease. Many (but not all) cross-sectional and prospective studies indicate, on average, that plasma tHcy levels <.10 µmol/L are associated with, or predict the development of, coronary, cerebral, and peripheral vascular disease. The risk conferred by hyperhomocysteinemia is graded and is independent of traditional risk factors, with an estimated odds ratio for ischemic heart disease of 1.4 for every 5 µmol/L increase in plasma tHcy. In vitro and in vivo, tHcy has been found to impair endothelial function. It is now well established that tHcy represents a marker of current or subsequent ischemic vascular disease. However, irrefutable proof that hyperhomocysteinemia actually causes atherothrombosis will come only if interventions to lower plasma tHcy will produce concomitant reductions in cardiovascular events.     

Methods in assessing homocysteine metabolism

Homocysteine, a sulfur-containing amino acid, is a metabolite of the essential amino acid methionine. High blood levels of homocysteine result in far-reaching biochemical and life-threatening consequences. Homocysteine exists at a critical biochemical intersection in the methionine cycle between S-adenosylmethionine, the ubiquitous methyl donor, and vitamins B(12) and folic acid. Indirect and direct vascular damage can be caused by homocysteine, a putative atherothrombotic risk factor. Homocysteine has been associated with vascular disease, particularly in subjects with significant carotid stenosis. Increasing evidence for a connection between homocysteine metabolism and cognitive function is surfacing, and this includes from mild cognitive decline (age-related memory loss) to vascular dementia and Alzheimer's disease. In the elderly population increase in homocysteine is commonly seen due to significant deficiencies in cobalamin (B(12)), folate and vitamin B(6.) All of these disease associations are thought to be interrelated via increased homocysteine and S-adenosylhomocysteine and subsequent hypomethylation of numerous substances, including DNA and proteins, rendering vascular structures more susceptible to damage. Decreasing plasma homocysteine, by providing nutritional cofactors for its metabolism has been shown to reduce the risk of cardiovascular events. The current methods of evaluation of homocysteine metabolism include assessment of cobalamin (B(12)) and folate and vitamin B(6) status and screening for mutations in the genes encoding the enzymes of metabolism. An accurate method for the estimation of plasma and tissue levels of homocysteine would contribute greatly to a proper understanding of the metabolism. In the current review emphasis will be on the estimation of homocysteine, and evaluation of one of the common mutations encountered in the metabolism of this amino acid.     

Plasma concentration of asymmetric dimethylarginine, an endogenous inhibitor of nitric oxide synthase, is elevated in monkeys with hyperhomocyst(e)inemia or hypercholesterolemia

Hyperhomocyst(e)inemia is associated with endothelial dysfunction. Mechanisms responsible for endothelial dysfunction in hyperhomocyst(e)inemia may involve impaired bioavailability of endothelium-dependent nitric oxide. We tested the hypothesis that hyperhomocyst(e)inemia is associated with an elevated plasma concentration of asymmetric dimethylarginine (ADMA), an endogenous inhibitor of nitric oxide synthase. One group of adult cynomolgus monkeys was fed either a control or hyperhomocyst(e)inemic diet for 4 weeks in a randomized crossover design. The second group was fed an atherogenic diet that produces both hyperhomocyst(e)inemia and hypercholesterolemia for 17 months, followed by an atherogenic diet supplemented with B vitamins for 6 months to decrease plasma homocyst(e)ine concentration. Human endothelial cells were used to study the effects of methionine and homocysteine in the presence or absence of B vitamins or the methylation inhibitor S-adenosylhomocysteine on the formation of ADMA and its inactive stereoisomer, symmetric dimethylarginine. The hyperhomocyst(e)inemic diet produced 2- to 3-fold increases in plasma levels of homocyst(e)ine and ADMA (both P<0.05). The atherogenic diet also produced elevated plasma levels of homocyst(e)ine and ADMA (both P<0. 05). Supplementation of the atherogenic diet with B vitamins decreased the plasma levels of homocyst(e)ine but did not affect the plasma levels of ADMA or endothelial function. There was a strong correlation between plasma ADMA and homocyst(e)ine and a strong inverse correlation between ADMA and carotid artery relaxation to acetylcholine. ADMA release by cultured endothelial cells was significantly increased in the presence of methionine or homocysteine. This effect was blocked by S-adenosylhomocysteine but not by B vitamins. We conclude that plasma levels of ADMA are elevated in hyperhomocyst(e)inemia. Because ADMA acts as a competitive inhibitor of endothelial nitric oxide synthase, these findings suggest a novel mechanism for impaired endothelial function in hyperhomocyst(e)inemia.     

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.     

Effect of folic acid and antioxidant vitamins on endothelial dysfunction in patients with coronary artery disease

OBJECTIVES: The purpose of this study was to determine whether lowering homocysteine levels with folic acid, with or without antioxidants, will improve endothelial dysfunction in patients with coronary artery disease (CAD). BACKGROUND: Elevated plasma homocysteine levels are a risk factor for atherosclerosis. Homocysteine may promote atherogenesis through endothelial dysfunction and oxidative stress. METHODS: In a double-blind, placebo-controlled, randomized trial, we used vascular ultrasound to assess the effect of folic acid alone or with antioxidants on brachial artery endothelium-dependent flow-mediated dilation (FMD). Seventy-five patients with CAD (screening homocysteine level > or =9 micromol/liter) were randomized equally to one of three groups: placebo, folic acid alone or folic acid plus antioxidant vitamins C and E. Patients were treated for four months. Plasma folate, homocysteine, FMD and nitroglycerin-mediated dilation were measured before and after four months of treatment. RESULTS: Plasma folate, homocysteine and FMD were unchanged in the placebo group. Compared with placebo, folic acid alone increased plasma folate by 475% (p < 0.001), reduced plasma homocysteine by 11% (p = 0.23) and significantly improved FMD from 3.2 +/- 3.6% to 5.2 +/- 3.9% (p = 0.04). The improvement in FMD correlated with the reduction in homocysteine (r = 0.5, p = 0.01). Folic acid plus antioxidants increased plasma folate by 438% (p < 0.001), reduced plasma homocysteine by 9% (p = 0.56) and insignificantly improved FMD from 2.6 +/- 2.4% to 4.0 +/- 3.7% (p = 0.45), as compared with placebo. Nitroglycerin-mediated dilation did not change significantly in any group. CONCLUSIONS: Folic acid supplementation significantly improved endothelial dysfunction in patients with coronary atherosclerosis. Further clinical trials are required to determine whether folic acid supplementation may reduce cardiovascular events.     

Homocysteine and renal disease

Hyperhomocysteinemia refers to an elevated circulating level of the sulfur-containing amino acid homocysteine and has been shown to be a risk factor for vascular disease in the general population. In patients with renal failure, hyperhomocysteinemia is a common feature. The underlying pathophysiological mechanism for this phenomenon is unknown. Proposed mechanisms include reduced renal elimination of homocysteine and impaired nonrenal disposal, possibly because of inhibition of crucial enzymes in the methionine-homocysteine metabolism by the uremic milieu. Absolute or relative deficiencies of folate, vitamin B6, or vitamin B12 may also play a role. Several case-control and prospective studies have now indicated that hyperhomocystenemia is an independent risk factor for atherothrombotic disease in patients with predialysis and end-stage renal disease. In renal patients, plasma homocysteine concentration can be reduced by administration of folic acid in doses ranging from 1 to 15 mg per day. In more than 50% of the cases, however, the homocysteine concentration remains above 15 micromol/L. The effects of vitamin B12 or vitamin B6 are unclear. Large intervention trials are now needed to establish whether homocysteine-lowering therapy will reduce atherothrombotic events in patients with renal failure. These studies are now planned or are ongoing.     

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.     

Endothelium-dependent effects of statins

The vascular endothelium is a dynamic endocrine organ that regulates contractile, secretory, and mitogenic activities in the vessel wall and hemostatic processes within the vascular lumen. Risk factors for cardiovascular disease, such as cigarette smoking, hypertension, and elevated serum lipid levels, impair endothelial function and lead to the development of atherosclerotic vessels. Recent studies suggest that statins reduce cardiovascular events in part by improving endothelial function. Statins reduce plasma cholesterol levels, thereby decreasing the uptake of modified lipoproteins by vascular wall cells. There is increasing evidence, however, that statins may also exert effects beyond cholesterol lowering. Indeed, many of these cholesterol-independent or "pleiotropic" vascular effects of statins appear to involve restoring or improving endothelial function through increasing the bioavailability of nitric oxide, promoting re-endothelialization, reducing oxidative stress, and inhibiting inflammatory responses. Thus, the endothelium-dependent effects of statins are thought to contribute to many of the beneficial effects of statin therapy in cardiovascular disease.     

Should hyperhomocysteinemia be treated in patients with atherosclerotic disease?

Numerous retrospective and prospective observational studies support an association between elevated homocysteine and increased risk for myocardial infarction, stroke, and peripheral vascular disease. Although folic acid therapy substantially reduces homocysteine levels, recent large, randomized controlled trials failed to translate folic acid-induced homocysteine reduction into clinical benefit for the secondary prevention of cardiovascular events. These studies are compelling and have generated some newfound skepticism regarding a clinical role for folic acid therapy. Because these intervention trials have been limited to patients with mild hyperhomocysteinemia, the results of the trials imply that folic acid therapy may be best suited for individuals with more robustly elevated homocysteine levels. Furthermore, the potential benefit of folic acid therapy for primary prevention in individuals at low-or intermediate-risk for atherothrombotic disease has not been studied to date. Thus, at this time, folic acid therapy for borderline or mild hyperhomocysteinemia is not recommended. However, the role of folic acid therapy in patients with intermediate or severe hyperhomocysteinemia, or for primary prevention of cardiovascular diseases, remains unresolved.