Reduced susceptibility of low density lipoprotein (LDL) to lipid peroxidation after fluvastatin therapy is associated with the hypocholesterolemic effect of the drug and its binding to the LDL

Fluvastatin suppresses atherosclerotic progression, mediated through its inhibitory effect on endothelial dysfunction, lipid peroxidation, and macrophage deposition

Fluvastatin, a potent 3-hydroxy-3-methylglutaryl coenzyme A reductase inhibitor, exerts an inhibitory effect on intimal thickening after mechanical injury in normocholesterolemic rabbit artery at a dose not enough to elicit a known action of lipid lowering. This study was designed to determine whether atherosclerotic progression triggered by hypercholesterolemia can be inhibited by fluvastatin under conditions without its hypocholesterolemic effect. Rabbits were fed a 0.5% cholesterol diet or normal diet for 17 weeks and were treated with either fluvastatin (0.3-2 mg/kg/day, p.o.) or pravastatin (2 mg/kg/day, p.o.). Atherogenic features manifested in the cholesterol-diet group, compared with the normal-diet group; they were the increase in serum lipid peroxide level, in the intraluminal lesion area of the aorta, and in macrophage content of the aortic cross-sectional lesion area; the attenuation of endothelium-dependent relaxing response to acetylcholine in the femoral artery; and the increase in serum lipid level. Treatment with fluvastatin, but not pravastatin, inhibited the manifestation of the atherogenic features without a serum lipid-lowering effect. Thus fluvastatin is likely to reduce the risk of atherosclerotic progression, to which endothelial dysfunction, lipid peroxidation, and macrophage accumulation in the vasculature may contribute, irrespective of changes in serum lipid levels.

Ibuprofen protects low density lipoproteins against oxidative modification

Oxidative modification of LDL by vascular cells has been proposed as the mechanism by which LDL become atherogenic. The effect of ibuprofen on LDL modification by copper ions, monocytes and endothelial cells was studied by measuring lipid peroxidation products. Ibuprofen inhibited LDL oxidation in a dose-dependent manner over a concentration range of 0.1 to 2.0 mM. Ibuprofen (2 mM, 100 microg/ml LDL) reduced the amount of lipid peroxides formed during 2 and 6 h incubation in the presence of copper ions by 52 and 28%, respectively. Weak free radical scavenging activity of ibuprofen was observed in the DPPH test. The protective effect of ibuprofen was more marked when oxidation was induced by monocytes or endothelial cells. Ibuprofen (1 mM, 100 microg/ml LDL) reduced the amount of lipid peroxides generated in LDL during monocyte-mediated oxidation by 40%. HUVEC-mediated oxidation of LDL in the absence and presence of Cu2+ was reduced by 32 and 39%, respectively. More lipid peroxides appeared when endothelial cells were stimulated by IL-1beta or TNFalpha and the inhibitory effect of ibuprofen in this case was more pronounced. Ibuprofen (1 mM, 100 microg/ml LDL) reduced the amount of lipid peroxides formed during incubation of LDL with IL-1beta-stimulated HUVEC by 43%. The figures in the absence and presence of Cu2+ for HUVEC stimulated with TNFalpha were 56 and 59%, respectively. To assess the possibility that ibuprofen acts by lowering the production rate of reactive oxygen species, the intracellular concentration of H2O2 was measured. Ibuprofen (1 mM) reduced intracellular production of hydrogen peroxide in PMA-stimulated mononuclear cells by 69%. When HUVEC were stimulated by IL-1beta or TNFalpha the reduction was 62% and 66%, respectively.

New insights into the pharmacodynamic and pharmacokinetic properties of statins

The beneficial effects of statins are assumed to result from their ability to reduce cholesterol biosynthesis. However, because mevalonic acid is the precursor not only of cholesterol, but also of many nonsteroidal isoprenoid compounds, inhibition of 3-hydroxy-3-methylglutaryl coenzyme A reductase may result in pleiotropic effects. It has been shown that several statins decrease smooth muscle cell migration and proliferation and that sera from fluvastatin-treated patients interfere with its proliferation. Cholesterol accumulation in macrophages can be inhibited by different statins, while both fluvastatin and simvastatin inhibit secretion of metalloproteinases by human monocyte-derived macrophages. The antiatherosclerotic effects of statins may be achieved by modifying hypercholesterolemia and the arterial wall environment as well. Although statins rarely have severe adverse effects, interactions with other drugs deserve attention. Simvastatin, lovastatin, cerivastatin, and atorvastatin are biotransformed in the liver primarily by cytochrome P450-3A4, and are susceptible to drug interactions when co-administered with potential inhibitors of this enzyme. Indeed, pharmacokinetic interactions (e.g., increased bioavailability), myositis, and rhabdomyolysis have been reported following concurrent use of simvastatin or lovastatin and cyclosporine A, mibefradil, or nefazodone. In contrast, fluvastatin (mainly metabolized by cytochrome P450-2C9) and pravastatin (eliminated by other metabolic routes) are less subject to this interaction. Nevertheless, a 5- to 23-fold increase in pravastatin bioavailability has been reported in the presence of cyclosporine A. In summary, statins may have direct effects on the arterial wall, which may contribute to their antiatherosclerotic actions. Furthermore, some statins may have lower adverse drug interaction potential than others, which is an important determinant of safety during long-term therapy.

Low-density lipoprotein-independent effects of statins

Statins have pleiotropic properties that complement their cholesterol-lowering effects. These properties may partly account for their established benefit in the prevention of coronary artery disease beyond the reduction of LDL-cholesterol levels. The most widely recognized properties are reviewed here. They include: (i) nitric oxide-mediated improvement of endothelial dysfunction and upregulation of endothelin-1 expression; (ii) antioxidant effects; (iii) anti-inflammatory properties; (iv) inhibition of cell proliferation with anticarcinogenic actions in animals; (v) stabilization of atherosclerotic plaques; (vi) anticoagulant effects; and (vii) inhibition of graft rejection after heart and kidney transplantation. As advances are made in our knowledge, new properties are steadily being uncovered. Pleiotropic effects are currently being given consideration when instituting combination therapy for patients at high cardiovascular risk. Some pleiotropic effects are negative, and may account for occasional untoward drug interactions. For many of these new properties, the clinical relevance has not been established. The challenge for the future will be to design and carry out appropriate clinical trials to establish their relative importance in the prevention of coronary artery disease.

Neuroprotective properties of statins in cerebral ischemia and stroke

BACKGROUND

The atheroma-retarding properties of beta-hydroxy-beta-methylglutaryl coenzyme A reductase (HMG-CoA) inhibitors, or "statins," in both the coronary and carotid arterial beds are well established. However, a growing body of recent data suggests that statins possess important adjunctive properties that may confer additional benefit beyond the retardation of atherosclerosis. In this article, we review the emerging evidence that statins have beneficial effects within the cerebral circulation and brain parenchyma during ischemic stroke and reperfusion.

SUMMARY OF REVIEW

Clinical studies show that statins reduce the incidence of ischemic stroke through probable effects on precerebral atherosclerotic plaque and through antithrombotic mechanisms. Additionally, statins have been shown to reduce infarct size in experimental animal models of stroke. Statins both upregulate endothelial nitric oxide synthase (eNOS) and inhibit inducible nitric oxide synthase (iNOS), effects that are potentially neuroprotective. The preservation of eNOS activity in cerebral vasculature, particularly in the ischemic penumbra, may be especially important in preserving blood flow and limiting neurological loss. Statins may also attenuate the inflammatory cytokine responses that accompany cerebral ischemia, and they possess antioxidant properties that likely ameliorate ischemic oxidative stress in the brain.

CONCLUSIONS

In addition to reducing stroke, the statin class of drugs exhibits a number of important neuroprotective properties that likely attenuate the effects of ischemia on the brain vasculature and parenchyma. Further investigation of the role of statins in human neuroprotection by use of neuroimaging and cognitive studies is warranted to explore these preliminary observations. In addition to reducing ischemic stroke, early evidence indicates that statins may also be neuroprotective.

Fluvastatin and low-density lipoprotein oxidation in hypercholesterolemic renal transplant patients

BACKGROUND

Hyperlipidemia contributes to the development and progression of vascular disease in organ transplant patients. Oxidative modification of low-density lipoproteins (LDLs) has been suggested as a key event in early atherogenesis.

METHODS

We conducted a pilot study in renal transplanted patients with persistent hypercholesterolemia above 6.5 mmol/liter. We studied the LDL oxidation before and after one year of fluvastatin treatment. Twenty patients (12 males and 8 females, 46 +/- 10 years old) who received a kidney transplant 24 +/- 18 months before the study were treated with fluvastatin (20 mg/day for 12 weeks). Patients with a total cholesterol under 6.3 mmol/liter continued to receive 20 mg/day for another 40 weeks (group I, N = 10). Nine patients with a total cholesterol above 6.3 mmol/liter received 40 mg/day for a further 40 weeks (group II).

RESULTS

Cyclosporine levels did not experience a significant variation. Total and LDL cholesterol decreased significantly in both groups (21.7 and 27.9% in group I, 18.3 and 27.2% in group II, respectively). The lag-phase time, which was significantly enlarged before fluvastatin treatment in the patients with respect to the controls (N = 18, 82 +/- 45 vs. 50 +/- 8 min) was shortened after one year of fluvastatin treatment (64 +/- 24 vs. 50 +/- 8 min, P = 0.04). Fluvastatin was stopped in only one patient because of nausea and vomiting. Transaminases and creatin-phospho-kinase were not altered. All of the patients maintained a functioning graft during the study period.

CONCLUSIONS

Fluvastatin significantly reduced total and LDL cholesterol, without interferences with cyclosporine A through levels. Fluvastatin has not demonstrated an antioxidant effect in our renal hypercholesterolemic transplant patients.

A HMG-CoA reductase inhibitor improved regression of atherosclerosis in the rabbit aorta without affecting serum lipid levels: possible relevance of up-regulation of endothelial NO synthase mRNA

We determined the role of Fluvastatin: HMG-CoA reductase inhibitor on the regression of atherosclerosis following removal of dietary cholesterol. Male rabbits fed a 0.5% cholesterol diet for 12 weeks were divided into three groups: A1, hypercholesterolemic; A2, fed a regular diet for an 12 additional weeks; and A3, fed a regular diet with fluvastatin (2 mg/kg/day). Fluvastatin treatment (A3) did not affect serum lipid levels compared with A2. However, it decreased the atherosclerotic area in the aortic arch and decreased total and esterified cholesterol concentrations in the descending aorta. Tone-related basal NO release in the thoracic aorta was larger in A3 than in A2. eNOS mRNA in vessel was determined by competitive RT-PCR assay. It increased in A1, compared with normal aorta and decreased in A2; however, it did not decrease in A3. This is the first report of a decrease in eNOS mRNA in atherosclerosis after removal of dietary cholesterol and a reversal of it by a HMG-CoA reductase inhibitor, which may contribute to the regression of atherosclerosis.

Effects of lovastatin therapy on susceptibility of LDL to oxidation during alpha-tocopherol supplementation

A randomized, double-masked, crossover clinical trial was carried out to evaluate whether lovastatin therapy (60 mg daily) affects the initiation of oxidation of low density lipoprotein (LDL) in cardiac patients on alpha-tocopherol supplementation therapy (450 IU daily). Twenty-eight men with verified coronary heart disease and hypercholesterolemia received alpha-tocopherol with lovastatin or with dummy tablets in random order. The two 6-week, active-treatment periods were preceded by a washout period of at least 8 weeks. The oxidizability of LDL was determined by 2 methods ex vivo. The depletion times for LDL ubiquinol and LDL alpha-tocopherol were determined in timed samples taken during oxidation induced by 2, 2-azobis(2,4-dimethylvaleronitrile). Copper-mediated oxidation of LDL isolated by rapid density-gradient ultracentrifugation was used to measure the lag time to the propagation phase of conjugated-diene formation. alpha-Tocopherol supplementation led to a 1.9-fold concentration of reduced alpha-tocopherol in LDL (P<0.0001) and to a 2.0-fold longer depletion time (P<0.0001) of alpha-tocopherol compared with determinations after the washout period. A 43% prolongation (P<0.0001) was seen in the lag time of conjugated-diene formation. Lovastatin decreased the depletion time of reduced alpha-tocopherol in metal ion-independent oxidation by 44% and shortened the lag time of conjugated-diene formation in metal ion-dependent oxidation by 7%. In conclusion, alpha-tocopherol supplementation significantly increased the antioxidative capacity of LDL when measured ex vivo, which was partially abolished by concomitant lovastatin therapy.

Protective effect of fluvastatin sodium (XU-62-320), a 3-hydroxy-3-methylglutaryl coenzyme A (HMG-CoA) reductase inhibitor, on oxidative modification of human low-density lipoprotein in vitro

We investigated the protective effect of fluvastatin sodium on the oxidation of low-density lipoprotein (LDL) induced in vitro by copper ions. The extent of lipid peroxidation was assessed by monitoring the increase of UV absorbance at 234 nm, which is the peak absorbance of a conjugated diene. Fluvastatin sodium (1-30 microM) not only prolonged the lag time of oxidation in the initiation step, but also decreased the rate of oxidation in the propagation step, both concentration dependently. Fluvastatin sodium and alpha-tocopherol showed an additive effect when both compounds were added before oxidation. However, when the lag time was prolonged initially by alpha-tocopherol, and fluvastatin sodium and alpha-tocopherol, were further added into the reaction mixture at the end point of the lag phase, fluvastatin sodium still showed an antioxidative effect, whereas alpha-tocopherol showed a pro-oxidative effect. Therefore, the antioxidative property of fluvastatin sodium differs from that of alpha-tocopherol. In this experiment, as neither the double bond-reduced derivative of fluvastatin sodium nor pravastatin sodium showed any protective effect, we concluded that the antioxidative effect of fluvastatin sodium is not a common property of 3-hydroxy-3-methylglutaryl coenzyme A (HMG-CoA) reductase inhibitors, but may be derived from its unique chemical structure. Since the oxidative modification of LDL plays an important role in the genesis of atherosclerosis, fluvastatin sodium may help reduce the risk of atherosclerosis, not only by reducing plasma LDL levels but also by protecting LDL from oxidative modification.

Simvastatin decreases aldehyde production derived from lipoprotein oxidation

Treatment with statins are known to lower plasma and low-density lipoprotein (LDL) cholesterol levels with resultant prevention and regression of atherosclerosis. It has been recently suggested that the action of the statins may also have a direct effect on other mechanisms involved in the atherosclerotic plaque formation. Thus, we investigated whether simvastatin could have an antioxidant effect on plasma lipoproteins. The rate of oxidation of LDL and high-density lipoproteins (HDL) was measured by conjugated diene formation with and without the addition of increasing concentrations of simvastatin (in vitro) and in patients with and without treatment with simvastatin (in vivo). A strong correlation was observed between increasing simvastatin concentration and the lag phase, a negative correlation was observed for maximal rate and maximum diene production in LDL samples (r2 = +0.97, p <0.0001; r2 = -0.92, p <0.0001; r2 = -0.98, p <0.0001, respectively). For HDL no clear correlation could be established with the lag phase, but a strong negative correlation was also observed between simvastatin concentration and maximal rate and maximum diene production (r2 = -0.69, p <0.01; r2 = -0.98, p <0.0001, respectively). After 6 hours of oxidation the production of aldehydes in LDL and HDL was lower (30% and 5%, respectively) in samples obtained during simvastatin therapy with respect to those obtained without treatment. The 2,4-decadienal showed a decrease of 37% and 64% (p <0.05) in both oxidized-LDL and oxidized-HDL particles, respectively, with simvastatin treatment. Our findings demonstrate that simvastatin acts as an antioxidant in lipoprotein particles and, together with its lipid-lowering properties, could play an important role in preventing atherosclerosis.

Fluvastatin, an inhibitor of 3-hydroxy-3-methylglutaryl-CoA reductase, scavenges free radicals and inhibits lipid peroxidation in rat liver microsomes

We investigated the effect of fluvastatin sodium (fluvastatin) and pravastatin, 3-hydroxy-3-methylglutaryl coenzyme A reductase inhibitors, on the formation of thiobarbituric acid reactive substances both in vivo and in vitro in rat liver microsomes and on active oxygen species. Oral administration of fluvastatin at low doses (3.13 and 6.25 mg/kg) inhibited the formation of thiobarbituric acid reactive substances in rat liver microsomes, but high doses (12.5 and 25 mg/kg) did not change the formation of thiobarbituric acid reactive substances. Fluvastatin at any dose used had no effect on the content of cytochrome P-450 and the activity of NADPH-cytochrome P-450 reductase. In in vitro experiments, concentrations of fluvastatin ranging from 1 x 10(-6) - 1 x 10(-4) M markedly inhibited NADPH-dependent lipid peroxidation in liver microsomes, but pravastatin weakly inhibited lipid peroxidation. The order of magnitude of inhibition of each drug on in vitro lipid peroxidation was butylated hydroxytoluene > probucol > or = fluvastatin > pravastatin. Moreover, fluvastatin chemically scavenged active oxygen species such as hydroxyl radicals and superoxide anion generated by the Fenton reaction and by the xanthine-xanthine oxidase system, respectively, but pravastatin showed no scavenging of superoxide anion. These results indicate that the suppression of in vivo and in vitro lipid peroxidation in liver microsomes may be, at least in part, due to the scavenging by fluvastatin of free radicals.

Antioxidant properties of ticlopidine on human low density lipoprotein oxidation

We found that ticlopidine, at therapeutically relevant concentrations (2.5-10 microM), but not aspirin nor salicylate, significantly counteracted copper-driven human LDL oxidation. Ticlopidine, at 5 and 10 microM, was also antioxidant on peroxyl radical-induced LDL oxidation; yet it was ineffectual on thiol and ascorbate oxidation mediated by peroxyl radicals themselves, suggesting that drug antioxidant capacity is somehow related to the lipoprotein nature of the oxidizable substrate, but not to radical scavenging. The drug could not indeed react with the stable free radical 1,1-diphenyl-2-pycrylhydrazyl, nor had apparent metal complexing-inactivating activity. Thus, ticlopidine has antioxidant effects on LDL oxidation, which, together with its anti-platelet activity, could confer peculiar antiatherogenic properties to the drug in vivo.

Relation of clinical benefit to metabolic effects in lipid-lowering therapy

Studies of lipid-modifying therapy show that inhibition of cholesterol synthesis is required in at least 2 sites-in hepatic cells and in cells located in the walls of coronary arteries-if the progression of coronary atherosclerosis is to be decreased in patients with relatively normal levels of low-density lipoprotein (LDL) cholesterol. This is clinically important, because the majority of patients with coronary artery disease do not have severely elevated LDL cholesterol levels. Of the 2 angiographic trials of 3-hydroxy-3-methylglutaryl coenzyme A (HMG CoA) reductase inhibitors ("statins") in patients with coronary artery disease and average cholesterol levels, only the Lipoprotein and Atherosclerosis Study (LCAS) of fluvastatin reported slowed angiographic progression of coronary artery disease in these patients. The change in LDL cholesterol levels during treatment with fluvastatin did not predict the extent of change in coronary atherosclerosis or incidence of clinical cardiac events. Apparently, the metabolic effects of treatment with fluvastatin were more important than the extent to which blood cholesterol levels were lowered. The clinical benefits of treatment with statins should be directly compared in randomized controlled clinical trials among patients with average cholesterol levels.

Statins and the kidney

Experience to date suggests that 3-hydroxy-3-methylglutaryl coenzyme A reductase inhibitors or statins can be used relatively safely and effectively to treat dyslipidaemia complicating renal disease. Recent studies suggest that in addition to lowering plasma lipid levels, these drugs modify other factors that contribute to vascular injury. Furthermore, statins could slow the progression of chronic renal failure and may augment the action of immunosuppressive therapy after renal transplantation. Such newly defined actions, some of which could be unrelated to lipid lowering, are likely to extend the applications of statins in nephrology.

Atorvastatin and gemfibrozil metabolites, but not the parent drugs, are potent antioxidants against lipoprotein oxidation

Increased atherosclerosis risk in hyperlipidemic patients may be a result of the enhanced oxidizability of their plasma lipoproteins. We have previously shown that hypocholesterolemic drug therapy, including the 3-hydroxy-3-methyl-glutaryl CoenzymeA (HMG-CoA) reductase inhibitors, and the hypotriglyceridemic drug bezafibrate, significantly reduced the enhanced susceptibility to oxidation of low density lipoprotein (LDL) isolated from hyperlipidemic patients. Although this antioxidative effect could not be obtained in vitro with all of these drugs, the active drug metabolites, which are formed in vivo, could affect lipoprotein oxidizability. We thus sought to analyze the effect of atorvastatin and gemfibrozil, as well as specific hydroxylated metabolites, on the susceptibility of LDL, very low density lipoprotein (VLDL), and high density lipoprotein (HDL) to oxidation. LDL oxidation induced by either copper ions (10 microM CuSO4), by the free radical generator system 2'-2'-azobis 2-amidino propane hydrochloride (5 mM AAPH), or by the J-774A.1 macrophage-like cell line, was not inhibited by the parent forms of atorvastatin or gemfibrozil, but was substantially inhibited (57-97%), in a concentration-dependent manner, by pharmacological concentrations of the o-hydroxy and the p-hydroxy metabolites of atorvastatin, as well as by the p-hydroxy metabolite (metabolite I) of gemfibrozil. On using the atorvastatin o-hydroxy metabolite and gemfibrozil metabolite I in combination an additive inhibitory effect on LDL oxidizability was found. Similar inhibitory effects (37-96%) of the above metabolites were obtained for the susceptibility of VLDL and HDL to oxidation in the oxidation systems outlined above. The inhibitory effects of these metabolites on LDL, VLDL, and HDL oxidation could be related to their free radical scavenging activity, as well as (mainly for the gemfibrozil metabolite I) to their metal ion chelation capacities. In addition, inhibition of HDL oxidation was associated with the preservation of HDL-associated paraoxonase activity. We conclude that atorvastatin hydroxy metabolites, and gemfibrozil metabolite I possess potent antioxidative potential, and as a result protect LDL, VLDL, and HDL from oxidation. We hypothesize that in addition to their beneficial lipid regulating activity, specific metabolites of both drugs may also reduce the atherogenic potential of lipoproteins through their antioxidant properties.

Direct effects of statins on the vascular wall

The beneficial effects of 3-hydroxy-3-methylglutaryl coenzyme A (HMG-CoA) reductase inhibitors (statins) on coronary events have generally been attributed to their hypocholesterolemic properties. Mevalonate and other intermediates of cholesterol synthesis (isoprenoids) are necessary for cell proliferation and other important cell functions; thus effects other than cholesterol reduction may help to explain the antiatherosclerotic properties of statins. Recently we provided in vitro and in vivo evidence of decreased smooth-muscle cell (SMC) proliferation and migration by fluvastatin and simvastatin, but not by pravastatin, independent of plasma cholesterol reduction. The ability of fluvastatin to interfere with arterial SMC proliferation at therapeutic concentrations (0.1-1 microM) prompted us to investigate the pharmacologic activity of sera from 10 patients treated with fluvastatin, 40 mg once daily, on the proliferation of cultured human arterial myocytes. Pravastatin, 40 mg once daily, displays a lipid-lowering activity similar to that of fluvastatin without affecting SMC proliferation and was investigated as a control for assessing this non-lipid-related effect of fluvastatin. Fluvastatin and pravastatin, given for 6 days to patients with type IIa hypercholesterolemia, resulted in a similar decrease in low-density-lipoprotein (LDL) cholesterol. However, the addition of 15% whole-blood sera from patients treated with fluvastatin to the culture medium resulted in a 43% inhibition of cholesterol synthesis in SMCs (p < 0.01) that mirrored the pharmacokinetic profile of fluvastatin. When SMC proliferation was investigated, a significant inhibition of cell growth (-30%; p < 0.01) was detected with sera obtained 6 h after the last dose. No effect on SMC proliferation or cholesterol biosynthesis was observed when sera from patients treated with pravastatin were evaluated. These results suggest that statins exert a direct antiproliferative effect on the arterial wall, beyond their effects on plasma lipids, which could prevent significant cardiovascular disease.

Direct vascular effects of HMG-CoA reductase inhibitors

Several studies have demonstrated that any beneficial effect of 3-hydroxy-3-methylglutaryl-coenzyme A (HMG-CoA) reductase inhibitors (statins) on coronary events are linked to their hypocholesterolemic properties. However, since mevalonic acid (MVA), the product of the enzyme reaction, is the precursor of numerous metabolites, inhibition of HMG-CoA reductase has the potential to result in pleiotropic effects. MVA and other intermediates of cholesterol synthesis (isoprenoids) are necessary for cell proliferation and other important cell functions, hence effects other than cholesterol reduction may help to explain the antiatherosclerotic properties of statins. Recently, we provided in vitro evidence that fluvastatin, simvastatin, lovastatin, cerivastatin, but not pravastatin, dose-dependently decrease smooth muscle cells (SMC) migration and proliferation, independently of their ability to reduce plasma cholesterol. Moreover, statins are able to reduce the in vitro cholesterol accumulation in macrophages, by blocking cholesterol esterification and endocytosis of modified lipoproteins. This in vitro inhibition was completely prevented by the addition of mevalonate and partially by all-trans farnesol and all-trans geranylgeraniol, confirming the specific role of isoprenoid metabolites--probably through a prenylated protein(s)--in regulating these cellular events. The inhibitory effect of lipophilic statins on SMC proliferation has been recently shown in different models of proliferating cells such as cultured arterial myocytes and rapidly proliferating carotid and femoral intimal lesions in rabbits. Finally, ex vivo studies recently showed that sera from fluvastatin-treated patients interfere with smooth muscle cell proliferation. These results suggest that HMG-CoA reductase inhibitors exert a direct antiatherosclerotic effect in the arterial wall, beyond their effects on plasma lipids, that could translate into a more significant prevention of cardiovascular disease.

Interactions of platelets, macrophages, and lipoproteins in hypercholesterolemia: antiatherogenic effects of HMG-CoA reductase inhibitor therapy

To assess the effect of 3-hydroxy-3-methylglutaryl coenzyme A (HMG-CoA) reductase inhibitors on plasma cholesterol concentrations and on platelet aggregation, lovastatin or fluvastatin, 40 mg daily, was given to hypercholesterolemic patients. After 24 weeks, plasma low-density lipoprotein (LDL) cholesterol concentrations were reduced by 37% after lovastatin therapy and 29% after fluvastatin therapy. The platelet cholesterol/phospholipid ratio was reduced by 33% and 26%, respectively. Platelet aggregation was significantly reduced by 12-15% (p < 0.01) after 4 weeks of therapy with either agent. Lovastatin or fluvastatin therapy reduced platelet aggregation through an in vivo hypocholesterolemic action on the platelet cholesterol content and also through a direct effect on platelet function, as a result of drug binding to the platelets. We also studied the effect of these HMG-CoA reductase inhibitors on LDL susceptibility to oxidation. LDL oxidation (induced by copper ions) was reduced by 31% after lovastatin therapy and by 37% after fluvastatin therapy. The inhibitory effect of HMG-CoA reductase inhibitors on LDL oxidation involved their stimulatory effect on the removal of LDL from the circulation and a direct binding effect of the drugs to the lipoprotein. Because HMG-CoA reductase inhibitors can inhibit platelet aggregation, macrophage foam cell formation, and LDL oxidation, major contributors to atherogenesis, the use of these drugs can significantly attenuate the atherosclerotic process.