View clinical trials related to Cardiovascular Diseases.
Filter by:The purpose of this study is to investigate whether basic periodontal therapy aim to reduce subgingival levels of Porphyromonas gingivalis and Aggregatibacter actinomycetemcomitans, has an impact on the vascular function of patients suffering from established cardiovascular disease.
This project will examine the association between (cardio)vascular disease, blood supply to the brain, and cerebrovascular endothelial activation. Also, we will investigate the impact of exercise rehabilitation on brain vascularization, cerebrovascular endothelial function and blood flow control.
The principal research objective is to determine whether inorganic nitrate in the form of beetroot juice compared to placebo control prevents the systemic inflammation that underlies typhoid vaccine-induced endothelial dysfunction
The objective of this study is to elucidate the relationship between inflammation and lipoprotein atherogenicity, and to determine the relative contribution of inflammation and lipids to CV risk in RA. The central hypothesis of this study is that inflammation and lipoprotein atherogenicity is tightly linked such that both factors are important to assess CV risk in RA. Further, the investigators hypothesize that this relationship is obscured by a consideration of routine lipids alone.
This is a Phase I, first-in-human (FIH) study to assess the safety, tolerability, pharmacokinetics (PK) and Pharmacodynamics (PD) of AZD4831 after single and multiple ascending doses in healthy male subjects
The purpose of this study is to see if exercise is helpful for improving memory, concentration thinking abilities, physical function, and quality of life for adults aged 50 to 89 years living with HIV and who have two or more cardiovascular disease risk factors. The study will test two kinds of intervention exercises: one group will walk for exercise and the second group will stretch for exercise. Members of both interventions will be asked to participate in one-on-one interviews/assessments, measures of physical functioning, and some sessions with others who are also enrolled in the study.
Cardiovascular diseases are the leading causes of morbidity and mortality in Brazil and surgical procedures to treat these disorders have grown dramatically in recent years. Since the first heart surgery in successful open field in humans, conducted in 1953 by John Lewis, many techniques have been used to improve the outcome of surgery and reduce their side effects. The low-level laser therapy (LBP) has been widely used in clinical practice for pain relief purposes, reducing inflammation and stimulating tissue healing. However, the effect of this therapy has been little elucidated in patients with cardiac disease. The objective of this study is to evaluate the effect of low level laser therapy on the inflammatory profile and cardiac tissue healing markers of patients in the postoperative period of CABG surgery.
The study will determine the feasibility and efficacy of adapting an evidence-based intervention (EBI) to reduce cardiovascular disease (CVD) risk factors in rural African American communities and determine the acceptability of mobile technology in these communities to support behavior change.
This study is designed to investigate the effect of a structured resistance training program on glycemic control, measured by hemoglobin A1c (glycated hemoglobin), in patients with type 2 diabetes (T2DM) who are enrolled in outpatient cardiac rehabilitation. The investigator will compare the experimental group receiving resistance training to a control group made of patients enrolled in outpatient cardiac rehabilitation and perform 3 aerobic exercise modalities during their sessions, which is the current standard of care.
Williams syndrome is a rare genetic disorder occurring in 1:8000-12,000 individuals. It is caused by the deletion of 25-27 coding genes, including elastin (ELN) on the 7th human chromosome. Haploinsufficiency for these genes leads to the features of the condition, including: - Distinctive facial features; - Characteristic vascular problems including hypertension, focal vascular stenosis, (when present in the aorta this is referred to as SVAS), vascular stiffness and differences in heart rate variability; - Endocrine abnormalities including hypercalcemia, hypothyroidism, and early puberty; - Metabolic concerns with colic and failure to gain weight in infancy and obesity and early glucose intolerance in adulthood; - Characteristic neurocognitive profile comprised of cognitive impairment, high sociality with concurrent social awkwardness, difficulty with visual-spatial tasks, relative strengths in speech, and lack of social fear; - Anxiety and chronic pain in adulthood Most individuals with WS carry the same basic deletion on Chromosome 7q11.23. However, each feature may present as mild or more severe in any given individual. Variation in the presence and severity of these vascular phenotypes remains unexplained. The supravalvar aortic stenosis (SVAS) phenotype is caused by haploinsufficiency for elastin. This can come about due to the WS deletion (as above) or due to heterozygous variation in elastin (ELN) gene itself in this region. When this protein is reduced, connective tissues lose its strength, flexibility, and overall support. When this happens in the aorta, it may cause vascular narrowing that presents as shortness of breath, chest pain, and even heart failure if left untreated. Narrowing also occurs in other vessels especially the pulmonary and renal arteries. Changes in non-vascular elastic tissues such as the skin and lungs also occur. As in WBS, phenotypic variation also occurs in people with ELN gene changes--This variability remains unexplained despite all the on-going research. Most individuals with features of SVAS have either WS or an elastin variant. There are, however, a smaller number of individuals with the phenotypic features of the condition whose genetic underpinnings are yet to be defined (they are referred to as SVAS-like). Additionally, there are 26 other coding genes within the WS critical region that contribute to various other features of the condition Objective: 1. To collect historical information and to bank DNA, cells, and tissue from individuals with genetic alterations in the WS/ELN gene region, those with an SVAS -like phenotype and unaffected family members/controls to facilitate future research into the many phenotypes seen in these individuals. 2. Currently, we plan to use the collected samples to identify genetic and environmental factors that contribute to the variability in different phenotypes (vascular and non-vascular) in individuals with WS, SVAS and SVAS-like conditions, individuals with variation in WS genes other than elastin and unaffected family members and controls. For the non-vascular features of WS and SVAS-like conditions for which a specific gene has not been implicated in the disease, we would also like to identify causative genes as well as modifiers. Likewise, by evaluating people with variation in other WS region genes, we can determine what contribution those genes make to the studied phenotypes. Controls will be both used to assess the frequency of genetic features in people without the phenotype in question and to evaluate heritability, penetrance, and expressivity of relevant variants. Eligibility: People ages 0-85 with either WS, SVAS, and/or an SVAS-like condition, unaffected family members or adult unrelated controls. Design: This study is not a treatment protocol. This study will consist of: Collection of personal history (questionnaires) and medical record data (relevant physician notes, lab and diagnostic tests and studies) to study the natural history of these conditions, allow stratification of disease severity, and identification of environmental risk factors; Collection of blood, saliva, urine and surgical tissue waste to allow DNA and RNA preparation as well as study of tissues both in situ and through the generation of IPSCs; Expression studies on available tissues (lymphocytes, IPSCs, vascular, skin, other collected tissues) to look for differential regulation of target genes; Direct imaging of tissues (lymphocytes, IPSCs, vascular, skin, other collected tissues); Storage of collected data and specimens for future research; A questionnaire may be sent to participants or parent/guardian or LAR to respond on behalf of participant.