Hyperlipidemias: Paoletti R

Poli A, Marangoni F, Paoletti R, Mannarino E, Lupattelli G, Notarbartolo A, Aureli P, Bernini F, Cicero A, Gaddi A, Catapano A, Cricelli C, Gattone M, Marrocco W, Porrini M, Stella R, Vanotti A, Volpe M, Volpe R, Cannella C, Pinto A, Del Toma E, La Vecchia C, Tavani A, Manzato E, Riccardi G, Sirtori C, Zambon A, Anonymous00119. · Nutrition Foundation of Italy, Italy. · Nutr Metab Cardiovasc Dis. · Pubmed #18258418 No free full text.

Abstract: The importance of non-pharmacological control of plasma cholesterol levels in the population is increasing, along with the number of subjects whose plasma lipid levels are non-optimal, or frankly elevated, according to international guidelines. In this context, a panel of experts, organized and coordinated by the Nutrition Foundation of Italy, has evaluated the nutritional and lifestyle interventions to be adopted in the control of plasma cholesterol levels (and specifically of LDL cholesterol levels). This Consensus document summarizes the view of the panel on this topic, with the aim to provide an updated support to clinicians and other health professionals involved in cardiovascular prevention.

Gaddi A, Cicero AF, Odoo FO, Poli AA, Paoletti R, Anonymous00278. · Center for Metabolic diseases and Atherosclerosis, University of Bologna, Italy. · Vasc Health Risk Manag. · Pubmed #18200807 links to  free full text

Abstract: Familial combined hyperlidemia (FCH) is a common metabolic disorder characterized by: (a) increase in cholesterolemia and/or triglyceridemia in at least two members of the same family, (b) intra-individual and intrafamilial variability of the lipid phenotype, and (c) increased risk of premature coronary heart disease (CHD). FCH is very frequent and is one of the most common genetic hyperlipidemias in the general population (prevalence estimated: 0.5%-2.0%), being the most frequent in patients affected by CHD (10%) and among acute myocardial infarction survivors aged less than 60 (11.3%). This percentage increases to 40% when all the myocardial infarction survivors are considered without age limits. However, because of the peculiar variability of laboratory parameters, and because of the frequent overlapping with the features of metabolic syndrome, this serious disease is often not recognized and treated. The aim of this review is to define the main characteristics of the disease in order to simplify its detection and early treatment by all physicians by mean of practical guidelines.

Katan MB, Grundy SM, Jones P, Law M, Miettinen T, Paoletti R, Anonymous00371. · Division of Human Nutrition and Epidemiology, Wageningen University, Bomenweg 2, 6703 HD Wageningen, The Netherlands. · Mayo Clin Proc. · Pubmed #12911045 links to  free full text

Abstract: Foods with plant stanol or sterol esters lower serum cholesterol levels. We summarize the deliberations of 32 experts on the efficacy and safety of sterols and stanols. A meta-analysis of 41 trials showed that intake of 2 g/d of stanols or sterols reduced low-density lipoprotein (LDL) by 10%; higher intakes added little. Efficacy is similar for sterols and stanols, but the food form may substantially affect LDL reduction. Effects are additive with diet or drug interventions: eating foods low in saturated fat and cholesterol and high in stanols or sterols can reduce LDL by 20%; adding sterols or stanols to statin medication is more effective than doubling the statin dose. A meta-analysis of 10 to 15 trials per vitamin showed that plasma levels of vitamins A and D are not affected by stanols or sterols. Alpha carotene, lycopene, and vitamin E levels remained stable relative to their carrier molecule, LDL. Beta carotene levels declined, but adverse health outcomes were not expected. Sterol-enriched foods increased plasma sterol levels, and workshop participants discussed whether this would increase risk, in view of the marked increase of atherosclerosis in patients with homozygous phytosterolemia. This risk is believed to be largely hypothetical, and any increase due to the small increase in plasma plant sterols may be more than offset by the decrease in plasma LDL. There are insufficient data to suggest that plant stanols or sterols either prevent or promote colon carcinogenesis. Safety of sterols and stanols is being monitored by follow-up of samples from the general population; however, the power of such studies to pick up infrequent increases in common diseases, if any exist, is limited. A trial with clinical outcomes probably would not answer remaining questions about infrequent adverse effects. Trials with surrogate end points such as intima-media thickness might corroborate the expected efficacy in reducing atherosclerosis. However, present evidence is sufficient to promote use of sterols and stanols for lowering LDL cholesterol levels in persons at increased risk for coronary heart disease.

Bolego C, Poli A, Cignarella A, Catapano AL, Paoletti R. · Nutrition Foundation of Italy, Via S Pietro all'Orto 17, 20121 Milan, Italy. · Cardiovasc Drugs Ther. · Pubmed #12374904 No free full text.

Abstract: Rosuvastatin (ZD4522) and pitavastatin (NK-104) are novel HMG-CoA reductase inhibitors with a peculiar pharmacological profile. In particular, they show a high potency in decreasing LDL-C and their catabolism is not mediated by the cytochrome P-450 3A4, thus reducing the potential for drug-drug interaction and improving the management of blood cholesterol. As the magnitude of LDL-C reduction is directly associated with the decrease in the incidence of myocardial infarction and mortality for CAD, statins with increased LDL-C lowering potency may ensure the achievement of target LDL-C levels and offer a more aggressive cholesterol control, further improving CAD morbidity and mortality.

Paoletti R, Corsini A, Bellosta S. · Department of Pharmacological Sciences, University of Milan, via Balzaretti 9, 20133 Milan, Italy. · Atheroscler Suppl. · Pubmed #12044584 No free full text.

Abstract: The 3-hydroxy-3-methylglutaryl coenzyme A (HMG-CoA) reductase inhibitors (statins) are effective in reducing the risk of coronary events, and are generally very well tolerated. However, simvastatin, lovastatin, cerivastatin and atorvastatin are biotransformed in the liver primarily by cytochrome P450 (CYP) 3A4, and clinical experience has shown that the risk of adverse effect, such as myopathy, increases with concomitant use of statins with drugs that substantially inhibit CYP 3A4 at therapeutic doses. Indeed, pharmacokinetic interactions (e.g. increased bioavailability), myositis, and rhabdomyolysis have been reported following concurrent use of atorvastatin, cerivastatin, simvastatin or lovastatin and cyclosporine A, mibefradil or nefazodone. In contrast, fluvastatin (mainly metabolized by CYP 2C9) and pravastatin (eliminated by other metabolic routes) are less subject to this interaction. Nevertheless, an increase in pravastatin bioavailability has been reported in the presence of cyclosporine A, possibly because of an interaction at the level of biliary excretion. In summary, some statins may have lower adverse drug interaction potential than others, which is an important determinant of safety during long-term therapy.

Comparato C, Altana C, Bellosta S, Baetta R, Paoletti R, Corsini A. · Department of Pharmacological Sciences, University of Milan, Via Balzaretti 9, 20133 Milano, Italy. · Nutr Metab Cardiovasc Dis. · Pubmed #11887430 No free full text.

Abstract: Clinical trials have firmly established that 3-hydroxy-3-methylglutaryl coenzyme A (HMG-CoA) reductase inhibitors (statins) can induce the regression of vascular atherosclerosis and reduce cardiovascular-related morbidity and death in patients with and without coronary artery disease. It is usually assumed that these beneficial effects are due to the ability of statins to reduce cholesterol synthesis. However, because mevalonic acid is not only the precursor of cholesterol but also of many non-steroidal isoprenoid compounds, the inhibition of HMG-CoA reductase may lead to pleiotropic effects. As shown by the data reported in this review, some statins can interfere with major events involved in the formation of atherosclerotic lesions, regardless of their hypolipidemic properties. The relevance of these effects in humans remains to be established (particularly in view of the high statin doses required to produce a direct vascular action), thus their contribution to the reduction in cardiovascular events observed in clinical trials has become one of the major challenges for future studies aimed at clarifying the anti-atherosclerotic benefits of statins.

Bernini F, Poli A, Paoletti R. · Department of Pharmacological Sciences, University of Milano, Italy. · Cardiovasc Drugs Ther. · Pubmed #11713888 No free full text.

Abstract: Statins effectively lower LDL-cholesterol and some members of this class have been shown to reduce the risk of major cardiovascular events and total mortality in patients with or at risk for coronary heart disease. Statins are in general well tolerated. Withdrawal rates related to adverse events are low (< or =3%). The most common adverse events are mild gastrointestinal symptoms. Elevated serum transaminase levels occur infrequently (< or = 1.5%). These are generally asymptomatic, reversible and rarely require drug withdrawal. Statins do not cause adverse endocrine effects, do not alter glycemic control in diabetic patients, and do not increase cancer risk. Dose-related myopathy and/or rhabdomyolysis also occurs very rarely, although the risk is increased by concomitant administration of cyclosporine, niacin, fibrates, or by CYP3A4 isoenzyme inhibitors (e.g. erythromycin, systemic azole antifungal agents etc.) with statins metabolized by this isoenzyme. The pharmacokinetics of the individual statin should be considered in patients receiving polypharmacological treatments, to minimize the risk of unfavorable drug interactions. Atorvastatin is well tolerated in long-term treatment of dyslipidemia and is characterized by a safety profile similar to the other available statins.

Paoletti R, Bellosta S. · Istituto di Scienze Farmacologiche, Facoltà di Farmacia, Università di Milano, Italy. · Atherosclerosis. · Pubmed #10382831 No free full text.

Abstract: Current treatment strategies and disease management programs for hyperlipidemia employ a range of lipid-lowering drugs. Results from early lipid-lowering trials using diet, fibrates, niacin and other classes of drug showed that lowering plasma cholesterol can significantly reduce the risk of developing ischemic cardiovascular events. The landmark statin trials have clearly demonstrated the benefits of lipid-lowering therapy in coronary heart disease (CHD) prevention and unlike early lipid-lowering studies, a reduction in mortality may become evident with statin therapy during the first year of treatment. The number of successful lipid-intervention trials continues to increase and evidence is accumulating that lipid modification can also reduce the risk of cardiovascular events among individuals with only modest degrees of blood-lipid abnormalities. With increasingly powerful drugs to modify blood lipids, the potential levels at which to initiate treatment and the appropriate target levels are rapidly changing and debate surrounds the question of where the line to initiate treatment should be drawn. The relative lack of major adverse events with statin therapy means that the level of CHD risk at which clinical benefit occurs cannot be determined by the degree of risk at which benefit exceeds adverse events. Therefore, patients with only moderately raised cholesterol levels can be treated because statin treatment is well tolerated. One of the most important aspects of the statin trials is the finding that clinical events, such as death and disability due to coronary artery disease, may be preventable or limited in a significant number of patients if they receive aggressive therapy. Current goals for cholesterol levels in patients with established CHD are rarely achieved with non-aggressive treatment; however, with aggressive lipid lowering statins can achieve these goals in a safe and effective manner.

Paoletti R, Fahmy M, Mahla G, Mizan J, Southworth H. · Department of Pharmacological Sciences, University of Milan, Milan, Italy. · J Cardiovasc Risk. · Pubmed #11873095 No free full text.

Abstract: BACKGROUND: Rosuvastatin (Crestor), a new, highly efficacious statin, has demonstrated dose-dependent low-density lipoprotein cholesterol (LDL-C) reductions of up to 65% in a dose-ranging programme with doses of 1 to 80 mg. DESIGN: A randomized, double-blind multicentre trial compared rosuvastatin with commonly used starting doses of pravastatin and simvastatin to determine relative efficacy in LDL-C reduction and impact on other lipid parameters in primary hypercholesterolaemia. METHODS AND RESULTS: A total of 502 patients (greater-than-or-equal 18 years; LDL-C greater-than-or-equal 4.14 mmol/l [160 mg/dl] and < 6.50 mmol/l [250 mg/dl] and triglycerides less-than-or-equal 4.52 mmol/l [400 mg/dl]) were randomized to 12 weeks of rosuvastatin 5 mg (n = 120) or 10 mg (n = 115), pravastatin 20 mg (n=]137) or simvastatin 20 mg (n = 130). Rosuvastatin 5 and 10 mg reduced LDL-C by 42 and 49%, respectively, compared with 28% for pravastatin (P < 0.001 versus both rosuvastatin doses) and 37% for simvastatin (P < 0.01 versus rosuvastatin 5 mg; P < 0.001 versus 10[?]mg). National Cholesterol Education Program Adult Treatment Panel II (NCEP ATP II) goals were achieved by 87% of rosuvastatin 10[?]mg patients, 71% of rosuvastatin 5[?]mg patients, 53% of pravastatin patients, and 64% of simvastatin patients; similar proportions of patients achieved NCEP ATP III goals. European Atherosclerosis Society (EAS) goals were achieved by 83, 63, 20 and 50% of patients, respectively. All study treatments were well tolerated. CONCLUSIONS: Both doses of rosuvastatin were more effective than pravastatin and simvastatin in meeting NCEP ATP II and EAS LDL-C targets. Rosuvastatin 10 mg was more effective than pravastatin and simvastatin in meeting NCEP ATP III targets.

Pauciullo P, Borgnino C, Paoletti R, Mariani M, Mancini M. · Department of Clinical and Experimental Medicine, Medical School of the University 'Federico II', Via S. Pansini 5, 80131, Naples, Italy. · Atherosclerosis. · Pubmed #10856536 No free full text.

Abstract: Preliminary data suggest that fluvastatin may be safely combined with fibrates. The Fluvastatin Alone and in Combination Treatment Study examined the effects on plasma lipids and safety of a combination of fluvastatin and bezafibrate in patients with coronary artery disease and mixed hyperlipidaemia. A total of 333 patients were randomly allocated in this multicentre double-blind trial to receive 40 mg fluvastatin alone (n=80), 400 mg bezafibrate (n=86), 20 mg fluvastatin+400 mg bezafibrate (n=85) or 40 mg fluvastatin+400 mg bezafibrate (n=82) for 24 weeks. Low-density lipoprotein (LDL)-cholesterol decreased >20% in all fluvastatin-containing regimens, with significantly greater decreases compared with bezafibrate alone (P<0.001). Bezafibrate alone and fluvastatin+bezafibrate combinations resulted in greater increases in high-density lipoprotein (HDL)-cholesterol and decreases in triglycerides compared with fluvastatin alone (P<0.001). Fluvastatin (40 mg)+bezafibrate was the most effective for all lipid parameters with a decrease from baseline at endpoint in LDL-cholesterol of 24%, a decrease in triglycerides of 38% and an increase in HDL-cholesterol of 22%. All treatments were well tolerated with no increase in adverse events for combination therapy versus monotherapy, or between combination regimens. No clinically relevant liver (aspartate aminotransferase [ASAT] or alanine aminotransferase [ALAT]) greater than three times the upper limit of normal) or muscular (creatine phosphokinase (CPK) greater than four times the upper limit of normal) laboratory abnormalities were reported. This large study shows 40 mg fluvastatin in combination with 400 mg bezafibrate to be highly effective and superior to either drug given as monotherapy in mixed hyperlipidaemia, and to be safe and well tolerated.

Cortellaro M, Cofrancesco E, Boschetti C, Cortellaro F, Mancini M, Mariani M, Paoletti R. · University of Milan, Italy. · Thromb Haemost. · Pubmed #10780315 No free full text.

Abstract: AIM OF THE STUDY: We studied the effects of fluvastatin and bezafibrate in monotherapy and in combination on plasma fibrinogen, t-plasminogen activator inhibitor (PAI-1) and C reactive protein (CRP) in patients with coronary artery disease (CAD) and mixed hyperlipidaemia. DESIGN: In this randomised, double blind, multicentre trial 333 patients with stable angina pectoris or previous myocardial infarction or coronary revascularisation and mixed hyperlipidaemia (LDL-cholesterol 135-250 mg/dl and triglycerides (TG) 180-400 mg/dl) were randomised to fluvastatin 40 mg, bezafibrate 400 mg, fluvastatin 20 mg + bezafibrate 400 mg or fluvastatin 40 mg + bezafibrate 400 mg treatments for 24 weeks. RESULTS: Plasma fibrinogen significantly decreased after treatment with the combinations fluvastatin+bezafibrate (-14 and -16%) and with bezafibrate monotherapy (-9%). No significant reduction was observed after fluvastatin monotherapy (-4%). No significant changes were observed in PAI-1 and CRP plasma levels. Combination therapy significantly decreased both LDL-C and TG, and significantly increased HDL-C. CONCLUSIONS: The combined effects on fibrinogen and plasma lipids achieved by fluvastatin and bezafibrate combination treatment might be more useful than the simple reduction of cholesterol in preventing ischaemic cardiovascular disease.

Arnaboldi L, Guzzetta M, Pazzucconi F, Radaelli G, Paoletti R, Sirtori CR, Corsini A. · Department of Pharmacological Sciences, University of Milan, via Balzaretti, 9, 20133 Milan, Italy. <> · Pharmacol Res. · Pubmed #17959387 No free full text.

Abstract: We evaluated the pharmacological activity of whole-blood serum from atorvastatin- vs. simvastatin- (both 40 mg/day) treated hypercholesterolemic patients (n=10) on cultured smooth muscle cell (SMC) proliferation and cholesterol biosynthesis, as related to lipid-lowering effect. Patients received either single or 2-weeks repeated doses of both simvastatin and atorvastatin, following a randomised, double-blind, cross-over design. Blood samples were collected before drug administration and at the scheduled intervals after administration, and the obtained serum was separated by centrifugation, sterilized and frozen until assayed. Cultured SMC were supplemented with medium plus 15% of separate serum sampled from the patients, and grown for 72 h. Proliferation was assayed by a Coulter Counter, while cholesterol biosynthesis was measured by the incorporation of 14C-acetate into cholesterol, under the same experimental conditions. Atorvastatin was more active vs. simvastatin in reducing total- (-28.3% vs. -20.7%; p=0.045) and LDL-cholesterol (-39.8% vs. -30.1%; p=0.011) after a 2-weeks regimen. Serum from atorvastatin-treated patients inhibited SMC proliferation vs.t=0 after both single (AUC -21.6%) and repeated (AUC -26.9%) doses, while serum from simvastatin-treated patients inhibited SMC proliferation only after repeated doses (AUC -24.5%). Interestingly, in the same experimental conditions, the serum concentrations of both statins (and of their active metabolites) were constantly below the detection limits, as shown from the lack of inhibition of cholesterol biosynthesis. The absence of any significant association between the lipid-lowering effects and the inhibition of SMC proliferation, together with no detectable active statin in the serum, suggests that these effects are elicited through independent mechanisms.

Camera M, Toschi V, Comparato C, Baetta R, Rossi F, Fuortes M, Ezekowitz MD, Paoletti R, Tremoli E. · Department of Pharmacological Sciences, University of Milan, Italy. · Thromb Haemost. · Pubmed #12008961 No free full text.

Abstract: High cholesterol levels are a known risk factor for coronary events. The molecular links between high serum cholesterol and the increased thrombogenicity of the arterial wall are still matter of investigation. In the present study we investigate the relationship between plasma cholesterol, thrombus formation and TF expression in a atherosclerotic rabbit model. Hypercholesterolemic rabbits showed a pronounced TF staining as well as NF-kappaB activation in the aortic arch. A consistent vessel wall platelet deposition was also observed. Treatment with fluvastatin reduced lipid accumulation, TF overexpression (-60%), NF-kappaB activation, and platelet deposition (-56%). In vitro studies showed that the drug upregulated IkappaB alpha in unstimulated as well as in TNFalpha-stimulated cells and also impaired the TNFalpha-induced Cdc42 prenylation, indicating that fluvastatin interferes with the transcriptional activation of TF gene. These results indicate that the prothrombotic phenotype of arterial wall, associated with elevated serum cholesterol levels, is mediated by TF overexpression. Fluvastatin treatment reduces the prothrombotic tendency by inhibiting TF synthesis.