View clinical trials related to Peripheral Vascular Diseases.
Filter by:This is a double-blinded, randomized, crossover design study to assess the effects of dietary nitrate supplementation (beetroot juice) on peripheral artery disease (PAD) patients (ages 50-85) diagnosed with Fontaine stage I or II PAD (as determined by vascular surgeon, Dr. Pipinos at UNMC). Exclusion criteria include: 1) experience severe claudication (leg pain) at rest or tissue loss due to PAD (Fontaine stage III and IV), 2) have limited walking capacity due to conditions other than PAD, 3) are already supplementing with a form of dietary nitrate, or 4) have an allergy to beetroot juice. Subjects will be required to visit the lab 3 times and will be randomized to receive either the supplement or the placebo for the 2nd and 3rd visits. There will be a washout period of 14 days between the 2nd and 3rd visits. Visit 1 will take approximately 2 hours and the 2nd/3rd visits will take approximately 1.5 hours. Total experimentation period will last approximately 15 days. Visit 1 will consist of non-invasive baseline testing including assessment of endothelial function (flow-mediated dilation by ultrasound imaging), maximal walking capacity (Gardner treadmill protocol), leg function (near-infrared spectroscopy, time to onset claudication, blood flow to lower extremities), and body core temperature (rectal thermometer). Visits 2 and 3 will require consumption of either the supplement or placebo. The same tests from the baseline measurements will be performed for visits 2 and 3. There will be a recommended fourth visit, albeit not required, to review study results.
Title: Impacts of mitochondrial-targeted antioxidant on leg blood flow and skeletal muscle mitochondrial function in peripheral artery disease patients. Peripheral artery disease (PAD) is a common cardiovascular disease, in which narrowed arteries reduce blood flow to the limbs, causing pain, immobility and in some cases amputation or death. PAD patients have shown higher levels of systemic and skeletal muscle inflammation due to the impaired oxygen transfer capacity of these blood vessels. This attenuated oxygen transfer capacity causes hypoxic conditions in the skeletal muscle and results in mitochondrial dysfunction and elevated reactive oxygen species (ROS). These harmful byproducts of cell metabolism are the major cause of intermittent claudication, defined as pain in the legs that results in significant functional limitations. One potential defensive mechanism to these negative consequences may be having higher antioxidant capacity, which would improve blood vessel vasodilatory function, enabling more blood to transfer to the skeletal muscles. Therefore, the purpose of this project is to examine the impact of mitochondrial targeted antioxidant (MitoQ) intake on oxygen transfer capacity of blood vessels, skeletal muscle mitochondrial function, leg function, and claudication in patients with PAD. Blood vessel oxygen transfer capacity in the leg will be assessed in the femoral and popliteal arteries. Skeletal muscle mitochondrial function and ROS levels will be analyzed in human skeletal muscle via near infrared spectroscopy and through blood samples. Leg function will be assessed by walking on a force platform embedded treadmill and claudication times will be assessed with the Gardner maximal walking distance treadmill test.
The aim of this randomized controlled trial is to: Phase I: To explore, in a first pilot phase, the adequate combination of hypoxia severity and exercise intensity in patients with symptomatic lower extremity artery disease (LEAD). Acute walking performances and physiological responses (vascular and muscular) to a normobaric hypoxic exercise performed will be assessed at two different altitudes (1500 m and 2500 m).
This study evaluate topical anaesthesia application for 30 minutes before tranradial catheterization during cardiac catheterization can reduce pain and decrease radial artery spasm
Peripheral artery disease (PAD) is the third most prevalent cardiovascular disease worldwide, with over 200 million people affected. Most prominent symptom is leg pain while walking known as intermittent claudication. Based on the currently existing gaps in the management of intermittent claudication, the objective of the this study is to explore the clinical effectiveness and cost advantage of TeGeCoach, a 12-month long home-based exercise program, compared to usual care. TeGeCoach consists of telephone health coaching, remote walking exercise monitoring based on wearable activity monitors and intensified primary care. It is hypothesized that TeGeCoach will improve functional outcomes and will reduce total health care costs.
Nitric oxide has been shown to be an important regulator within the cardiovascular system, responsible for regulation of blood flow, blood pressure and vascular growth. Cardiovascular diseases show a reduced ability of the peripheral blood vessels to dilate due to decreased levels of NO with concomitant increased levels of oxidative stress, which is extremely detrimental to patients with PAD, as the limited oxygen delivery to skeletal muscles ultimately results in claudication and reduced physical ability. However, this reduced oxygen delivery and utilization may be able to be improved as previous studies have revealed that tetrahydrobiopterin (BH4), is an important cofactor responsible for NO production. Furthermore, recent studies have shown that endothelial BH4 levels are associated with the vascular pathophysiological response to hypoxia, as it directly mediates endothelial nitric oxide synthase regulation and reduces superoxide production. Additionally, acute administration of BH4 was shown to improve vascular function, specifically, endothelial mediated vasodilatory function, in patients with systemic vascular and coronary disease, as well as six minute walking distances in patients with hypertension. Therefore, the purpose of this proposed study will be to examine the effects of BH4 on vascular function, oxidative stress and leg performance in patients with PAD. This study will examine patients with a classification of stage 1 or stage 2 peripheral artery disease who demonstrate a history of exercise-limiting claudication. Blood vessel oxygen transfer capacity in the leg will be assessed in the femoral and popliteal arteries with ultrasound, and blood vessel dilatory ability will be assessed in the brachial artery with flow-mediated dilation. Skeletal muscle mitochondrial function will be measured with near infrared spectroscopy, and ROS levels will be analyzed through blood samples. Leg function will be measured with an isokinetic dynamometer.
Test the theory that abnormalities in the large blood vessels that deliver blood to your leg and the very small blood vessels in your leg's muscles (invisible to the eye) work together to worsen your leg function and walking.
The study aim is to evaluate the effectiveness of a coached, smartphone-enabled exercise program versus physician directed exercise therapy (usual care).
Background: Patients suffering with atherosclerotic peripheral arterial disease (PAD) have limited therapeutic options to improve claudication. Supervised exercise programs are generally effective in improving leg pain from walking, but are poorly adhered to because of patient discomfort. The benefit of exercise training programs is thought to be mediated in part through repeated ischemic stimuli that activate endogenous regenerative mechanisms. In preliminary studies, exercise-induced tissue desaturation by near infrared spectroscopy (NIRS) precedes the onset of leg pain. This proposal aims to explore a novel strategy of exercise training in PAD based on measured tissue hypoxia rather than pain symptoms using NIRS to non-invasively characterize muscle oxygen tension. Methods: In subjects with symptomatic peripheral arterial disease, the efficacy of a novel NIRS-based strategy of thrice-weekly exercise training will be assessed. Enrolled subjects will be randomized to NIRS-based training, traditional claudication-based training, or self-directed walking. The hypotheses tested include: 1) NIRS-directed exercise improves claudication to a similar degree as symptom-directed exercise training and 2) is superior to self-directed walking. In the symptom-based group, physical effort will be dictated by claudication symptoms, whereas in the hypoxia-based training program, physical effort is dictated by NIRS measure of calf oxygen tension. Efficacy in the training programs will be evaluated by total walking time on a standard graded treadmill test after 12 weeks. Other measures will be claudication onset time, subjective and objective measures of physical activity, changes in vascular function. In addition, the hypothesis that hypoxia-directed training will result in increased ischemic signaling and increased progenitor cell mobilization to a degree similar as in claudication-based training will be tested. Conclusions: These experiments will test whether a training strategy based on tissue hypoxia (measured by NIRS) is as effective as and more tolerable than traditional symptom-based training programs in PAD. In addition, these experiments will characterize mechanistic responses to hypoxia that may account for clinical improvements that exercise training affords.
Randomized multicenter clinical trial consisting of two arms; one arm treated with PTA plus the MicroStent® System and one arm treated with PTA alone. Purpose to evaluate the safety and effectiveness of using the MicroStent® Peripheral Vascular Stent System, hereafter referred to as the MicroStent® System, for the treatment of infrapopliteal lesions in subjects with peripheral arterial disease.