View clinical trials related to Cardiovascular Risk Factor.
Filter by:This study aims to assess the prevalence and severity of dementia in an established cohort of community-dwelling older adults living in three neighboring rural Ecuadorian villages (Atahualpa, El Tambo, and Prosperidad), as well as to evaluate clinical and neuroimaging correlates of dementia in the study population. By the use of the Clinical Dementia Rating Scale (CDRS), the study also aims to assess the lower cutoff of the MoCA that better correlates with the occurrence of dementia in the study population. In addition, this study will provides grounds for the initiation of a prospective cohort study to assess factors influencing the development of dementia in the follow-up.
Cardiovascular disease (CVD) claims more lives each year than cancer and chronic respiratory disease combined. Participation in cardiac rehabilitation (CR) reduces mortality and risk of a major cardiovascular event in secondary prevention populations, including older adults. Older adults are less likely to participate in CR, as comorbidities in this population, including arthritis and chronic obstructive pulmonary disease, make participation difficult. Singing is a physical activity that involves components of the vagal nerves manifested as changes in cardiac autonomic regulation. Unlike physical exercise, the effects of singing on cardiovascular health has not been well-studied. The hypothesis for this project is that older patients with CVD will have favorable improvement in cardiovascular biomarkers, including, endothelial function and heart rate variability (HRV), after 30 minutes of singing.
Aging has been associated with reduced bioavailability of nitric oxide(NO) and endotelial dysfunction.Curcumin, a phenolic compound present in the rhizomes of turmeric, possesses cardiovascular protective, anti-inflammatory and antioxidante properties. The present study is evaluating the effects of ingestion of 10 g of curcumin supplementation (CUR) on microvascular responsiveness and tissue oxygen saturation in the elderly with cardiometabolic risks.Twenty eight older individuals have been submitted to 10 g of curcumin suplementation (CUR) or placebo (PLA) (sucralose). Microvascular responsiveness and tissue oxygen saturation have been measured 120 minutes after interventions.
Prescribing lifestyle changes to patients who have cardiovascular disease (CVD) may be an extremely cost effective mechanism of improving health individually and for the NHS. Positive lifestyle changes such as improved diet, increased physical activity, quitting smoking and reducing alcohol consumption have been proven to reform the health status of individuals with CVD. S-PLAC 2 is a phase II study to determine the efficacy of a lifestyle prescription (L℞) in patients and healthcare practitioners in a secondary care setting (i.e. hospital clinics/wards).
The aim of this study is to investigate if the application of lipid in various form (i.e. liquid and solid) affects glycaemia, lipaemia and insulinaemia. In addition, this study aims to test the lipidemic effects of the use of vegetable oil as a substitute in the application for making chocolate confectionery.
The randomized double-blinded placebo-controlled multicenter study will be held in parallel groups. During 5 weeks the efficacy of different endpoints as a measure of response to the daily intake of dietary fibers (8 g of either inulin, pectin, beta-glucan or galactooligosaccharides) will be evaluated. Gut microbiota composition, lipids levels, inflammation markers, microbiome metabolites, changes in quality of life and stool parameters will be assessed in order to predict individual response in participants without serious chronic diseases
The proposed intervention study is designed to evaluate the physiological impact of the regular consumption of the developed foods with improved nutrient profile (verum) in comparison to commercial available foods (control) by a controlled, randomized, double-blind crossover study with patients with measurable cardiovascular risk factors (LDL cholesterol ≥ 120 mg/dl (≥ 3 mmol/l) / Triacylglycerides ≥ 135 mg/dl (≥ 1,5 mmol/l)).
Prescribing lifestyle changes to patients who are at risk of cardiovascular disease, may be an extremely cost effective mechanism of improving health for the individual themselves and the NHS. It is already proven that positive lifestyle changes such as improved diet, increased physical activity, quitting smoking and reducing alcohol consumption can lower the risk of cardiovascular disease, as well as reduce the risk of all-cause mortality. P-PLAC2 (Primary Care - Prescribing Lifestyle Adjustments for Cardiovascular Health) is a Phase II interventional study to determine the efficacy of a Lifestyle Prescription (LRx), from the viewpoint of patients and healthcare practitioners. The study uses a mixed methods design, and full study training and support will be provided to staff involved in the recruitment of patients, through to the behaviour change consultation, and end of study. If the study proves successful, a lifestyle prescription (LRx) could then be made available to support NHS staff throughout all disciplines (specifically those working with patients who are at risk of cardiovascular disease (CVD).
Americans continue to consume high amounts of sodium. Potassium is notable for its blood pressure lowering effects but less is known regarding its effect on the vasculature. This investigation seeks to determine the role of dietary potassium on the vasculature in the presence of a high sodium diet in salt-resistant adults.
Elevated plasma triglycerides (TG) are due to an excess of TG-rich lipoproteins of several different types, most commonly of very-low-density lipoproteins (VLDL), but also intermediate-density lipoproteins (IDL, or VLDL remnants), chylomicrons, and/or chylomicron remnants. Epidemiologic evidence that a moderate elevation in TG is often associated with increased atherosclerotic cardiovascular disease (ASCVD) risk, and more recent evidence from Mendelian randomization studies has shown that elevated TG associated with genetic variants may be a causal factor for ASCVD and possibly for premature all-cause mortality.[1-6] Fasting plasma TG concentrations may be categorized as: normal (< 150 mg/dL ), borderline (150-199 mg/dL), high TG (HTG, 200-499 mg/dL), and very high TG (VHTG, ≥ 500 mg/dL).[7, 8] Risk of acute pancreatitis is increased in VHTG patients, especially those with TG ≥ 1000 mg/dL.[9] For VHTG, the primary goal of therapy is to reduce TG to < 500 mg/dL,[10] whereas there is no specific treatment goal for HTG nor prescription indication. However, the omega-3 fatty acids, EPA and DHA have well-established efficacy in reducing TG in the range of 150-500 when administered at doses of > or = 3 g/d EPA+DHA (reviewed in Skulas-Ray et al. in press). Importantly, administration of omega-3 fatty acids to people with TG in this range lead to a 25% reduction in major adverse cardiovascular endpoints in the recently completed "Reduction of Cardiovascular Events with EPA Intervention Trial" (REDUCE-IT).[11] The results of REDUCE-IT provide compelling evidence for the use 3 g/d omega-3 fatty acid supplementation to reduce cardiovascular risk among patients with TG 150-500 mg/dL. The concentrated EPA supplement used in REDUCE-IT is just one of three long chain n-3 omega-3 fatty acids that influence lipids and lipoproteins and other aspects of cardiovascular risk. Most research has focused on the evaluation of EPA and DHA, which are the two predominant n-3 FA in fish and in n-3 agents, but docosapentaenoic acid (DPA) is present in fish oil, as well, and accumulates in the blood at similar concentrations. The carbon length of the n-3 FA appears important for physiological effects. EPA has a carbon length of 20, DHA has a carbon length of 22, and DPA, the metabolic intermediate of EPA and DHA, is a 22-carbon n-3 FA. DPA may have significant potential for treating HTG and VHTG,[12, 13] but research on this fatty acid remains limited. In a 2-week open-label crossover comparison of 4 g/d of a DPA concentrate (containing unspecified amounts of free DPA and EPA) vs. 4 g/d EPA concentrate in people with HTG, plasma TG were reduced 33% by the DPA concentrate, which was significantly more than the 11% reduction with EPA.[13] Thus, a recent scientific advisory from the American Heart Association (Skulas-Ray et al, in press) concluded that more research is needed to elaborate the lipid and lipoprotein effects of DPA. Additional biomarker research suggests DPA similarly can influence health outcomes that respond to EPA and DHA. For instance, decreased serum concentrations of DPA and DPA + DHA have been associated with increased risk of risk of acute coronary events[14] and myocardial infarction[15], respectively. Plasma DPA was also inversely associated with incident cardiovascular disease (CVD) in some ethnic groups.[16] In conclusion evidence supports a potential role of DPA in improving health, but results from clinical supplementation studies are needed to clarify the effect of DPA supplementation on lipids and lipoproteins as well as other cardiovascular disease risk factors-relative to supplementation with EPA and DHA-to ascertain whether enrichment of omega-3 concentrates with DPA could offer health benefits above and beyond concentrates that only contain EPA and DHA.