50 Clinical Trials for Various Conditions
Primary Objective: To assess the effects of subcutaneous (SC) doses of alirocumab on the elimination (measured by Fractional Clearance Rate (FCR)) of apolipoprotein B (apoB) in low density lipoprotein (LDL) in adults with mildly elevated LDL-cholesterol (LDL-C). Secondary Objectives: To assess the effects of SC doses of alirocumab on: * Various parameters of the metabolism and turnover in plasma of different lipoproteins * Plasma lipids concentration: total cholesterol, high density lipoprotein cholesterol (HDL-C), triglycerides, low density lipoprotein cholesterol (LDL-C), apoB, lipoprotein(a) (Lp(a)) * Lipoprotein particle size profile * PCSK9 (free and total) concentrations in serum To assess safety and tolerability of alirocumab. To assess emergence of anti-alirocumab antibodies. To document serum alirocumab concentrations.
This study evaluates the effect on LDL cholesterol of the 3 drugs given together in the cardiovascular fixed dose combination pill (acetylsalicylic acid, simvastatin, and ramipril) as compared to the effect on LDL cholesterol of simvastatin given alone. Approximately 76 subjects will be screened, 60 randomized in order about 52 subjects to finish the study.
This is an open label pilot clinical trial on a cohort of 15 Lupus patients from the Center for Rheumatic Disease. Clinical evaluations and laboratory tests will be done and then if eligible, the patients will receive oral atorvastatin, at a fixed dose of 40mg/day. Statins have been shown to induce clinical improvement in rheumatoid arthritis patients, as well as lupus patients. The effectiveness has been noted within 8 to 14 days, we will do our study for 3 months. Clinical and laboratory tests will be checked at the 1 and 3 month interval. We hypothesize that statin drugs (atorvastatin) slow the progression of SLE(Systemic Lupus Erythematosus) disease activity and down regulates TLR(Toll-like receptors) 2,4,and 9 pathways in addition to lowering lipid levels.
This is a phase 1 study in otherwise healthy participants with high LDL cholesterol. Following multiple doses of LY3015014, the safety and tolerability of the drug, how the body handles the drug, and the drug's effect on the body will be evaluated. Participants will participate in the study for approximately 3 months not including screening. Screening is required within 42 days prior to the start of the study.
The purpose of this study is to determine the efficacy of Lipitor (Atorvastatin) for the treatment of PCOS with elevated LDL cholesterol.
This study will compare the side effects of two laser treatments for diabetic macular edema, a common condition in patients with diabetes. In macular edema, blood vessels in the retina-a thin layer of tissue that lines the back of the eye-become leaky and the retina swells. The macula-the center part of the retina that is responsible for fine vision-may also swell and cause vision loss. Traditional laser treatment (argon blue or green, or yellow) for macular swelling, or edema, causes scarring that can expand and possibly lead to more loss of vision. A different type of laser (diode) may have less damaging effects to the eye and fewer long-term adverse effects, but this is not known. The results of this study on side effects of the treatments will be used to design a larger study of effectiveness. The study will also examine whether vitamin E can reduce the damage caused by laser treatment. Patients with elevated cholesterol levels will be invited to participate in a cholesterol reduction part of the study to compare normal-pace cholesterol reduction with accelerated reduction. Patients 18 years of age and older with type 1 or type 2 diabetes and macular edema may be eligible for this study. Candidates will be screened with the following tests and procedures: * Medical history and physical examination. * Eye examination to assess visual acuity (eye chart test) and eye pressure, and to examine pupils, lens, retina and eye movements. The pupils will be dilated with drops for this examination. * Blood tests to measure cholesterol and vitamin E blood levels, blood clotting time, hemoglobin A1C (a measure of diabetes control), and to evaluate liver and kidney function. * Eye photography to help evaluate the status of the retina and changes that may occur in the future. Special photographs of the inside of the eye are taken using a camera that flashes a bright light into the eye. * Fluorescein angiography to evaluate the eye's blood vessels. A yellow dye is injected into an arm vein and travels to the blood vessels in the eyes. Pictures of the retina are taken using a camera that flashes a blue light into the eye. The pictures show if any dye has leaked from the vessels into the retina, indicating possible blood vessel abnormality. * Multifocal electroretinogram to measure electrical responses generated within the retina. The test, which takes about 1-1/2 hours, is painless. Participants will be randomly assigned to take 1600 IU of vitamin E or placebo (an inactive, look-alike pill) daily. After taking the pills for 3 months or more, patients who require laser treatment will be randomly assigned to one of the two laser therapies. (Patients with macular edema in both eyes will receive both treatments, one in each eye.) For these procedures, eye drops are put in the eye to numb the surface and a contact lens is placed on the eye during the laser beam application. Several visits may be required for additional laser treatments. The maximum number of treatments depends on how well they are working. Patients will return for follow-up visits 1, 3, and 6 months after the first treatment, and then every 6 months until either the patient returns for a 3-year visit; the last enrolled patient returns for the 1-year visit; or the patient requests to leave the study. During the follow-up visits, patients' response to treatment will be evaluated with repeat tests of several of the screening exams.
This study will compare the side effects of two laser treatments for diabetic macular edema, a common condition in patients with diabetes. In macular edema, blood vessels in the retina, a thin layer of tissue that lines the back of the eye become leaky and the retina swells. The macula, the center part of the retina that is responsible for fine vision may also swell, causing vision loss. Traditional laser treatment (argon blue or green or yellow) for macular swelling, or edema, causes scarring that can expand and possibly lead to more loss of vision. Studies with a different type of laser (diode) may be less damaging. The results of this study on side effects of the treatments will be used to design a larger study of effectiveness. This study will also examine whether celecoxib (Celebrex® (Registered Trademark)), an anti-arthritis drug that reduces inflammation and swelling, can reduce inflammation and swelling of the retina. Patients with elevated cholesterol levels will be invited to participate in a cholesterol reduction part of the study to compare normal-pace cholesterol reduction with accelerated reduction. Patients 18 years of age and older with type 1 or type 2 diabetes and macular edema that requires laser treatment may be eligible for this study. Candidates will be screened with the following tests and procedures: * Medical history: to review past medical conditions and treatments. * Physical examination: to measure vital signs (pulse, blood pressure, temperature, breathing rate) and examine the head and neck, heart, lungs, abdomen, arms and legs. * Eye examination: to assess visual acuity (eye chart test) and examine pupils, lens, retina, and eye movements. The pupils will be dilated with drops for this examination. * Blood tests: to measure cholesterol, blood clotting time, hemoglobin A1C (a measure of diabetes control), and to evaluate liver and kidney function. * Eye photography: to help evaluate the status of the retina and changes that may occur in the future. Special photographs of the inside of the eye are taken using a camera that flashes a bright light into the eye. From 2 to 20 pictures may be taken, depending on the eye condition. * Fluorescein angiography: to evaluate the eye's blood vessels. A yellow dye is injected into an arm vein and travels to the blood vessels in the eyes. Pictures of the retina are taken using a camera that flashes a blue light into the eye. The pictures show if any dye has leaked from the vessels into the retina, indicating possible blood vessel abnormality. Participants will be randomly assigned to take celecoxib or placebo (an inactive, look-alike pill). Participants who have elevated cholesterol levels may return for a brief visit after 1 month. All patients will return for follow-up visits at 3, 6, and 12 months. Patients who require laser treatment will be randomly assigned to one of the two laser treatments. For these procedures, eye drops are put in the eye to numb the surface and a contact lens is placed on the eye during the laser beam application. Several visits may be required for additional laser treatments. The maximum number of treatments depends on how well the treatment is working. Patients who respond well to the study medication may receive no laser treatments. After the first year, patients will be followed every 6 months until either the patient returns for a 3-year visit, the last enrolled patient returns for the 1-year visit, or the patient requests to leave the study. During the follow-up visits, patients' response to treatment will be evaluated with repeat tests of several of the screening exams.
This study will compare the side effects of two laser treatments for diabetic macular edema, a common condition in patients with diabetes. In macular edema, blood vessels in the retina-a thin layer of tissue that lines the back of the eye-become leaky and the retina swells. The macula-the center part of the retina that is responsible for fine vision-may also swell and cause vision loss. Traditional laser treatment (argon blue or green or yellow) for macular swelling, or edema, causes scarring that can expand and possibly lead to more loss of vision. Studies with a different type of laser (diode) have shown no adverse effects to the retina, but long-term effects of this treatment are not known. The results of this study on side effects of the treatments will be used to design a larger study of effectiveness. This study will also examine whether vitamin E can reduce the damage caused by laser treatment. Patients with diabetic eye disease who take vitamin E have increased blood flow through the vessels of the retina, as well as improved kidney function. Patients with elevated cholesterol levels will be invited to participate in a cholesterol reduction part of the study to compare normal-pace cholesterol reduction with accelerated reduction. Patients 18 years of age and older with type 1 or type 2 diabetes and macular edema may be eligible for this study. Candidates will be screened with the following tests and procedures: * Medical history - to review past medical conditions and treatments. * Physical examination - to measure vital signs (pulse, blood pressure, temperature, breathing rate) and examine the head and neck, heart, lungs, abdomen, arms and legs. * Eye examination - to assess visual acuity (eye chart test) and examine pupils, lens, retina, and eye movements. The pupils will be dilated with drops for this examination. * Blood tests - to measure cholesterol and vitamin E blood levels, blood clotting time, hemoglobin A1C (a measure of diabetes control), and to evaluate liver and kidney function. * Photography - to help evaluate the status of the retina and changes that may occur in the future. Special photographs of the inside of the eye are taken using a camera that flashes a bright light into the eye. From 2 to 20 pictures may be taken, depending on the eye condition. * Fluorescein angiography - to evaluate the eye's blood vessels. A yellow dye is injected into an arm vein and travels to the blood vessels in the eyes. Pictures of the retina are taken using a camera that flashes a blue light into the eye. The pictures show if any dye has leaked from the vessels into the retina, indicating possible blood vessel abnormality. Participants will be randomly assigned to receive one of the two laser treatments. They will also be randomly assigned to take 1600 IU of vitamin E or placebo (an inactive, look-alike pill) daily. For the laser treatment, eye drops are put in the eye to numb the surface and a contact lens is placed on the eye during the laser beam application. Several visits may be required for additional laser treatments. The maximum number of treatments depends on how well the treatment is working. On their first visit, patients will be given vitamin C. After taking the vitamin for 1 month, they will return to the clinic for the first laser treatment. They will followed 1, 3, 6, 9, and 12 months after the first treatment, and then every 6 months until either 1) the patient returns for a 3-year visit; 2) the last enrolled patient returns for the 1-year visit, or the patient requests to leave the study. During these visits, several of the exams described above will be repeated to evaluate the response to treatment and check for side effects of the vitamin E.
The primary objective was to evaluate the effect of 12 weeks of subcutaneous evolocumab (AMG 145) every 2 weeks (Q2W) or every 4 weeks (Q4W), compared with placebo, on the percent change from baseline in LDL-C when used as monotherapy in adults with hypercholesterolemia.
The purpose of the study is to assess the effect of AZD0780 on the pharmacokinetics of rosuvastatin, and to assess the safety and tolerability of AZD0780 single dose, in healthy participants administered alone and in combination with rosuvastatin.
The primary objective of this study was to assess users' ability to administer a full dose of evolocumab in a home-use setting using either an automated mini-doser (AMD) or autoinjector/pen (AI/pen).
The primary objective of this study was to assess users' ability to administer a full dose of evolocumab in home-use using either a pre-filled syringe or autoinjector/pen.
The main aim of this study is to assess the effects of AZD0780 when added on top of ezetimibe or ezetimibe and rosuvastatin or ezetimibe and bempedoic acid.
The purpose and objective of this study is to improve cholesterol treatment among blood donors with FH (Familial Hypercholesterolemia).
The purpose of this extension study was to evaluate the efficacy, safety, and tolerability of long-term dosing of Inclisiran. The study was a global multicenter study.
AZD8233 has not been evaluated in clinical studies previously. This is a first-in-human (FiH) study. This study will assess the safety, tolerability and pharmacokinetics (PK) of AZD8233, following subcutaneous (SC) administration of single ascending dose (SAD) of AZD8233. This study will also investigate the pharmacodynamics (PD) of AZD8233 by investigating the effect of AZD8233 on levels of cholesterol and related biomarkers.
The purpose of this study is to determine if triplet therapy with bempedoic acid (ETC-1002) 180mg, ezetimibe 10mg, and atorvastatin 20mg is effective and safe versus placebo in patients with elevated LDL cholesterol.
The purpose of this study is to determine if bempedoic acid (ETC-1002) added-on to ezetimibe therapy is effective and safe versus placebo in patients with elevated LDL cholesterol.
This study is designed to investigate the safety, tolerability, pharmacokinetics and pharmacodynamics of LGT209 in hypercholesterolemic patients taking common statin medications and in healthy volunteers.
The primary objective was to evaluate the effect of 12 weeks of evolocumab subcutaneous (SC) monotherapy every 2 weeks (Q2W) and monthly (QM), compared with placebo and ezetimibe, on percent change from baseline in low-density lipoprotein cholesterol (LDL-C) in adults with a 10-year Framingham risk score of 10% or less.
12 week study to assess the LDL-C lowering efficacy, other lipid and glycemic measures, and safety of bempedoic acid/ezetimibe FDC compared to ezetimibe and placebo in patients with type 2 diabetes (T2D) and elevated LDL-C
This study will compare 2 treatments in the way they affect cholesterol levels and the amount of HIV in the blood.
The goal of this implementation trial is to learn if providing education to doctors and patients who have had a heart event works to prevent future heart problems. The main questions it aims to answer are: 1. Does educating the doctors in a health system improve how often patients in the hospital for a heart event have their cholesterol checked? 2. Can a "care champion" who calls patients who have been discharged from the hospital after a heart event help patients to achieve their cholesterol goals? Researchers will compare the number of people who achieve their cholesterol goals with the help of the care champion to the number of people who did so without the intervention to see if the care champion works to help patients lower their cholesterol. Participants will: Complete two 15 minute surveys over the phone - 1 at enrollment and 1 at the end of the study 6 months later.
This is a Phase III, placebo-controlled, double-blind, randomized study in participants with HeFH and elevated LDL-C to evaluate the efficacy, safety, and tolerability of subcutaneous (SC) injection(s) of inclisiran. The study will be multicenter and international.
Cardiovascular disease (CVD) is the leading cause of disparities in years of life lost by race and low socioeconomic status. Statins have been shown to decrease the risk of cardiovascular events among individuals with high CVD risk. Yet, despite increased statin use and overall declining CVD rates, disparities in statin use and disparities in the control of high cholesterol by race, ethnicity, and socioeconomic status have persisted. Objective: To improve the appropriate use of statins for primary cardiovascular disease prevention among high risk individuals at community health centers through a system of population health management that uses electronic health record (EHR) data to identify patients for targeted education and outreach. Aim 1: Conduct a randomized controlled trial among individuals with 10-year risk for myocardial infarction or coronary death of 10% or higher to determine if the population health management intervention, compared to usual care, results in higher rates of documented statin treatment discussions within 6 months (primary process outcome), higher rates of statin prescribing within 6 months (secondary process outcome), and higher rates of significant low-density lipoprotein cholesterol (LDL-C) lowering defined as a follow up LDL-C ≥30 mg/dL lower than baseline (primary clinical outcome). Aim 2: Interview patients who received the intervention to identify barriers to success Aim 3: Assess the overall costs of the intervention and the costs per each patient who achieves significant LDL-C lowering compared to patient who received usual care.
The study is to assess the long-term safety, tolerability, and efficacy after 48 and 72 weeks with monthly (Q4W \[\<31 days\]) dosing of subcutaneous (SC) LIB003 300 mg administered in patients with CVD or at high risk for CVD (including HoFH and HeFH) on stable diet and oral LDL-C lowering drug therapy who completed one of the LIB003 Phase 3 base studies.
CKJX839D12302 is a pivotal Phase III study designed to test the hypothesis that treatment with inclisiran sodium 300 milligram (mg) subcutaneous (s.c.) administered on Day 1, Day 90, and every 6 months thereafter in patients at high cardiovascular (CV) risk without a prior major atherosclerotic cardiovascular disease (ASCVD) event will significantly reduce the risk of 4-Point-Major Adverse Cardiovascular Events (4P-MACE) defined as a composite of CV death, non-fatal myocardial infarction (MI), non-fatal ischemic stroke, and urgent coronary revascularization, compared to placebo.
This is a Phase III, placebo-controlled, double-blind, randomized study in participants with ASCVD and elevated LDL-C despite maximum tolerated dose of LDL-C lowering therapies to evaluate the efficacy, safety, and tolerability of subcutaneous (SC) inclisiran injection(s). The study will be a multicenter study in the United States.
The purpose of this study is to see if bemedoic acid (ETC-1002) is effective versus placebo in patients with high cardiovascular risk and elevated LDL cholesterol not adequately controlled by their current therapy.
The purpose of this study is to see if ETC-1002 (bempedoic acid) is safe and well-tolerated versus placebo in patients with high cardiovascular risk and elevated LDL cholesterol that is not adequately controlled by their current therapy.