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Find 574 clinical trials for diabetes near Maryland. Connect with research centers in your area.
Showing 321-340 of 574 trials
NCT00833846
Type II diabetes mellitus is rapidly becoming a global pandemic with a deleterious impact on cardiovascular morbidity and mortality. Understanding its pathophysiology is important for the development of future therapeutic interventions. Emerging evidence suggests interplay between mitochondrial dysfunction and the development of insulin resistance. Interestingly, mitochondrial dysfunction in skeletal muscle and adipose tissue are early events in the development of type II diabetes mellitus and are proposed to play a role in exacerbating insulin resistance. Although it has been demonstrated that skeletal muscle of insulin-resistant individuals has reduced mitochondria and mitochondrial dysfunction, whether this disruption of mitochondrial function is more widespread has not been explored. We hypothesize that this disruption of mitochondrial function is more systemic and thereby may contribute to the development of peripheral insulin resistance and possibly promote the myriad of complications associated with diabetes. To test these assumptions, we propose an initial proof of concept study to evaluate mitochondrial biology in human platelets in normal volunteers, pre-diabetic and diabetic subjects to assess whether mitochondrial disruption/dysfunction evolves with the progression to type II diabetes. In parallel, proteomic analysis will be performed to evaluate whether the development of insulin resistance and diabetes confers a specific modulation in the biological signature of human platelets with disease progression. To delineate these concepts, we will evaluate study subject's glucose tolerance and insulin sensitivity and draw blood in parallel to study their platelets. Biological readouts will include: 1) the quantification of the mitochondrial proteome and electron transfer chain content; 2) the evaluation of platelet mitochondrial respiratory function and 3) to determine the mitochondrial reactive oxygen species capacity and defenses. If this hypothesis is validated, this study will show that the mitochondrial disruption/dysfunction is a more generalized finding in type II diabetes. Additionally, it would propose the use of platelets as potential biomarkers for early detection of mitochondrial function and assessment of disease. Finally, this would establish a peripheral blood readout of the modification of mitochondrial function as a novel approach to monitor the prevention and/or reversal of insulin resistance and diabetes in response to therapeutic strategies.
NCT00351650
This study will test dihydrotetrabenazine, or 11C-DTBZ, a radioactive tracer, as an imaging agent in positron emission tomography (PET). That tracer may have the ability to noninvasively measure beta cell, that is, -cell mass (BCM) in humans. For researchers hoping to develop new treatments for diabetes mellitus, a method of measuring BCM is very important. In this study, researchers will determine if patients with Type 1 diabetes mellitus, who have almost no BCM, have much less pancreatic uptake of the tracer than do patients without diabetes. Patients ages 18 and older may be eligible for this study. Three groups will be studied: Participants who have Type 1 diabetes, those without diabetes, and those who have been successfully treated with a transplant of the pancreas or pancreas and kidney The study involves three sets of tests that can be done as an outpatient or after being admitted to the hospital. Patients will undergo a medical history and procedures including collection of blood (about 4 teaspoons), pregnancy test for women of childbearing age, magnetic resonance imaging (MRI) scan, PET scan, and tests involving arginine and glucose. Arginine is a substance that stimulates insulin release from the -cells. During the procedure, two intravenous (IV) lines are placed into the arms, one to administer arginine and the other to draw blood (about eight samples during 10 minutes). For the glucose test, patients will drink a solution of dextrose, a sugar, and blood samples will be taken over 2 hours from the IV lines. Some patients experience nausea after drinking the solution. Within 48 hours of either test or both, patients will be placed in the PET scan machine and given an injection of the radioactive material through an IV line. Blood samples of about one-half teaspoon will be drawn before the procedure starts and again every 10 seconds for the first 2 minutes and at several intervals, up to 60 minutes. Finally, patients will also an MRI scan, 30 to 60 minutes long, of the abdomen. This test will be down within two weeks of the PET scan. MRI uses a strong magnetic field and radio waves to obtain images of body organs and tissues. During the scan, patients will be asked to lie still on a table that slides into the tunnel of the scanner. They will be given earplugs, for the machine can be noisy. Patients who have metal within their body that is not compatible with the MRI machine will be withdrawn from the study.