Active clinical trials for "Hypercholesterolemia"

The main purpose of this study is to evaluate the effect on mental state (known as "neurocognitive function") with use of Praluent.

This study aims to 1) assess the feasibility and acceptability of a prescribed beverage intervention in 50 obese Hispanic adults ages 18-64 years over 6 weeks; and 2) assess preliminary effects of the beverage intervention on cholesterol and triglyceride levels as well as other markers of health such as blood pressure, glucose and markers of inflammation. This project, if successful, will provide early evidence that targeting dietary behavior around beverage intake could be a novel and easily adopted approach to reduce the burden or delay the onset of metabolic abnormalities in obese Hispanic adults. The expected outcome of the proposed project is the identification of feasible and appropriate beverage intervention strategies to improve engagement and adherence to dietary modification approaches for control of metabolic health indicators in this vulnerable ethnic group.

Hypercholesterolemia is considered one of the most important cardiovascular risk factors. Cardiovascular prevention include a class I indication to statins in addition to non-pharmacologic intervention and prevention strategies in patients deemed to be 'high risk'. Along with non-pharmacologic intervention and prevention strategies, newer approaches to reduce cholesterol blood levels currently include nutraceuticals, which are compounds derived from foods with cholesterol lowering actions. However, it remains unclear if nutraceuticals yield additive positive effects other than cholesterol lowering. In particular, there is evidence that Berberine has cardiovascular protective effects and that, in vitro, Morus Alba, mulberry fruit, modulates platelet function by inhibiting platelet activation, thromboxane formation, serotonin secretion, aggregation and thrombus formation. Furthermore, Morus Alba exerts an α-glucosidase inhibitory and antioxidant activity in vitro, which may reduce postprandial glucose peak, thus improving HbA1c concentration. Accordingly, we designated a study to evaluate the effects of two commercially available nutraceutical combined pills [LopiGLIK™, Akademy Pharma, 1 capsule/day containing red yeast rice 220 mg (at least 3,3 mg of Monacolin K) + Berberine 531,25 mg + Morus Alba 200 mg (at least 4 mg of Deoxynojirimycin) vs. Armolipid Plus®, Meda Pharma, 1 capsule/day containing Berberis aristata d.e. 588 mg (equivalent to Berberine chloride 500 mg) + Red yeast rice 200 mg (equivalent to Monacolin K 3 mg) + Policosanol 10 mg + Folic acid 0.2 mg + Coenzyme Q10 2.0 mg + Astaxanthin 0.5 mg] on lipid and metabolic profile, platelet aggregation, endothelial function and coronary flow reserve (CFR). For this purpose patients with hypercholesterolemia not requiring statins or statin intolerant at moderate cardiovascular risk will be subjected at day 0 and at day 28, after 4 weeks of therapy, to blood sampling to evaluate lipid and metabolic profile, peripheral arterial tonometry (EndoPAT), platelet aggregation tests with light transmission aggregometry (LTA), nitric oxide (NO) release, endothelial nitric oxide synthase (eNOS) phosphorylation on platelets. Only for CFR, patients will be further evaluated also after two hours from the administration of the first dose of nutraceutical combined pill. Patients will be randomly assigned to receive therapy with LopiGLIK™ or with Armolipid Plus®.

Primary Objective: To evaluate the efficacy of alirocumab (75 or 150 milligrams [mg] depending on body weight [BW]), administered every 2 weeks (Q2W), on low-density lipoprotein cholesterol (LDL-C) levels at Week 12 of treatment in children and adolescents with homozygous familial hypercholesterolemia (hoFH) of 8 to 17 years of age on top of background treatments. Secondary Objectives: To evaluate the efficacy of alirocumab after 24 and 48 weeks of treatment on LDL-C levels. To evaluate the effects of alirocumab on other lipid parameters (eg, apolipoprotein B [Apo B], non-high density lipoprotein cholesterol [non-HDL-C], total cholesterol [Total-C], high density lipoprotein cholesterol [HDL-C], lipoprotein a [Lp (a)], triglycerides [TG], apolipoprotein A-1 [Apo A-1] levels) after 12, 24, and 48 weeks of treatment. To evaluate the safety and tolerability of alirocumab up to 48 weeks of treatment.

This study will assess the safety and tolerability of Ezetimibe (EZ) 10 mg/Atorvastatin (Atora) 10 mg and EZ 10mg/Atora 20 mg fixed-dose combination (FDC) in Japanese participants with hypercholesterolemia uncontrolled with monotherapy of Ezetimibe 10 mg or Atorvastatin up to 20 mg. There is no formal hypothesis for the study.

Familial hypercholesterolemia (FH) is an autosomal codominant single-gene disorder caused by mutations in the LDL receptor gene that disrupt the normal clearance of LDL particles from the plasma compartment. Heterozygous patients present a 2- to 3-fold raise in plasma LDL-cholesterol (C) concentrations, tendinous xanthomatosis and premature atherosclerotic coronary heart disease (CHD), usually occurring between the age of 35 and 55 years. Since the mid-1970s, LDL-C has been removed from the blood of patients using plasmapheresis, and this technique has been shown to improve the life expectancy of FH homozygotes. LDL apheresis selectively removes LDL particles but not immunoglobulins and other beneficial proteins, thereby overcoming a potential drawback of the traditional plasmapheresis method. LDL-C is effectively reduced by more than 60% immediately after LDL apheresis, although LDL levels rebound rapidly. Dextran sulfate adsorption is a commonly apheresis technique used in familial hypercholesterolemia patients. In this apheresis plasma is separated from red blood cells and passed over columns of cellulose beads containing dextran sulfate which binds apolipoprotein B (apoB) by a highly selective electrostatic binding mechanism. Since LDL, very-low density lipoprotein (VLDL), and Lipoprotein (a) all contain apoB, dextran sulfate adsorption apheresis selectively reduces these lipoproteins while having little effect on the non-apoB containing HDL particles. In clinical practice, LDL apheresis reduces the rate of future cardiovascular events and has been postulated to have additional effects on potentially pro-atherogenic factors. Some proteins have been identified with adhesive characteristics to lipoproteins, rheological, immunological and inflammation relevant proteins16-19 that influence microcirculation as well as the inflammatory response. However, no studies have yet to investigate the impact of LDL apheresis on the expression of different genes involved in cardiovascular disease. The main objective of the present research project is to investigate the impact of the LDL apheresis dextran sulfate adsorption system on the messenger ribonucleic acid (mRNA) expression of genes involved in cardiovascular disease using microarrays analysis in 9 FH homozygotes.

To investigate the effect of a supplement capsule containing LRC™ (L. reuteri NCIMB 30242), taken twice daily with lunch and dinner (NLT 2.5E9 CFU per dose), versus placebo capsule on serum low density lipoprotein (LDL)-cholesterol in otherwise healthy hypercholesterolemic adults after 9 weeks of product consumption.

The study will assess the safety and tolerability of Ezetimibe 10 mg+ Rosuvastatin 2.5 mg and Ezetimibe 10 mg+ Rosuvastatin 5.0 mg for up to 52 weeks in Japanese participants with hypercholesterolemia uncontrolled with monotherapy of Ezetimibe 10 mg or Rosuvastatin up to 5 mg.

Cardiovascular disease (CVD) is associated with high levels of low-density lipoprotein (LDL) cholesterol and low levels of high-density lipoprotein (HDL) cholesterol. CVD results from 'hardening of the arteries' when there is a build-up of cholesterol in the walls of blood vessels. LDL is the main carrier of cholesterol in the body. LDL particles are responsible for transporting cholesterol that is deposited in vessel walls. LDL particles can also be altered in structure and turn into an irritant to the vessel walls. The body responds to the irritating effect of LDL by producing substances that result in inflammation. This sequence of events eventually leads to the vessels becoming permanently damaged. HDL has a protective role in CVD. It is associated with the enzyme paraoxonase which protects the body from the damaging effects of altered LDL particles. Nicotinic acid (niacin) has the ability to lower LDL levels and raise HDL levels thus reducing the incidence of CVD. Our study aims to show that niacin not only has good effects on cholesterol levels but is also able to reduce inflammation. Niacin is often poorly tolerated due to flushing side effect. Tredaptive is a formulation that combines niacin with laropiprant, an agent that reduces flushing hence improving tolerability and compliance. Patients who are receiving cholesterol-lowering medication and whose LDL levels have not reached the recommended target are recruited to the study. The study will be conducted at the Manchester Royal Infirmary. The study has two consecutive 16 week periods. In each period patients will be randomised to either tredaptive or placebo. They will attend for 5 monitoring visits. Apart from the first visit, fasting blood samples will be taken from them during all subsequent visits.

This is a 3-period study. Periods 1 and 2 will evaluate the effects of multiple doses of laropiprant on the antiplatelet effects of clopidogrel and aspirin administered in combination in participants with primary hypercholesterolemia or mixed dyslipidemia. Period 3 will be open-label and will evaluate single dose pharmacokinetics of nicotinic acid and laropiprant components of Tredaptive.