View clinical trials related to Type 1 Diabetes.
Filter by:Participants will be asked to wear a continuous glucose monitor for at least three days on three separate occasions. One testing session will be a no-exercise resting control session (90 minutes). One will be a moderate aerobic exercise session (30 minutes of exercise, 60 minutes of recovery), and the third will be a moderate weight-lifting session (~30 minutes of exercise, 60 minutes of recovery).The investigators will measure changes in blood glucose during exercise by drawing blood during and after exercise. Post-exercise glucose trends will be examined using continuous glucose monitoring.
Female participants with type 1 diabetes using oral contraceptives will be asked to wear a continuous glucose monitor for at least three days on two separate occasions (once during the last week of active pills and once during the no pill/placebo pill phase of the menstrual cycle). An exercise session (45 minutes of aerobic exercise at 60% VO2peak on a cycle ergometer) will take place at 5 pm on the second day of glucose monitoring.
The purpose of this research study is to understand how type 1 diabetes (T1D) increases the risk for cardiovascular diseases (heart attack and stroke). To this end, the investigators will compare apolipoprotein and triglyceride kinetics in people wtih T1D and healthy control participants.
Osteopenia and osteoporosis, particularly related to insulinopenia, are common in type 1 diabetes and increase the risk of fractures. Musculoskeletal disorders of the upper limb are a common complication of type 1 diabetes. However, there is no official recommendation for screening for musculoskeletal disorders in France.
Carbohydrates are the nutrient in the diet with the greatest impact on blood glucose. Inadequate carbohydrate counts are associated with higher A1c and greater variations in postprandial blood glucose. Clinical guidelines for the nutritional treatment of diabetes recommend that patients with DM1 learn carbohydrate counting or some similar systematic strategy that allows for better metabolic control. However, despite the recommendations, this is still not a reality for most healthcare services treating individuals diagnosed with DM1.
Type 1 diabetes (T1D) is caused by the destruction of insulin-producing cells by effector T cells (Teffs), due to a deficiency of regulatory T cells (Tregs). Ciclosporin effectively blocks the Teffs and controls diabetes, but cannot be considered as a long-term treatment. Low-dose interleukin-2 (ld IL-2) activates and expands Tregs in humans. Hence, Ld IL-2 in patients in whom the autoimmune process was blocked early by a short treatment (2 months) of cyclosporine should restore immune homeostasis and maintain some insulin production over the long term.
The objective of this proposal is to demonstrate a viable, functionally integrated multivariable artificial pancreas (mvAP) that will address meal, physical activity (PA) and acute psychological stress (APS) challenges without any manual inputs to better regulate glucose levels of people with diabetes. Acute psychological stress and many other forms of PA besides planned exercise can affect blood glucose levels and cause challenges to maintaining euglycemia for people with type 1 diabetes mellitus (T1DM). Various PA and APS affect the metabolism and sensitivity to insulin in different ways. Hence, their types, intensities and durations, and their individual and concurrent presence must be detected in order to determine the optimal insulin administration. The mvAP approach provides a well-integrated and user-friendly technology with minimal burden on the user and mitigates the effects of unexpected PA and APS inducements. Twenty subjects with type 1 diabetes (ages 18-60) who use insulin pumps enrolled in this study. The study will take place at the UIC-College of Nursing Diabetes and Exercise Laboratory. The protocol will include 1 screening visit and 5 sessions at the laboratory. The primary activities at each meeting will include: (1) screening; (2) measurement of peak exercise capacity; (3) estimation of maximal strength from submaximal strength tests; (4) Trier Social Stress Test; (5) submaximal bouts of aerobic and resistance exercise, and activities of daily living with and without stress (e.g., mental calculations, video games). These activities will be included visit 3, 4 and 5 as appropriate. In addition, subjects will perform activities at home include: housekeeping chores, stationary bike (if available); treadmill (if available); walking; and light weights (if available). Periodically, the research assistant will call the subject during these times and ask them to perform stress-inducing activities while performing the activity. The stress inducing activities will include mental challenges such as a mathematical computation while performing the activity. The subjects will be called at home 3-5 times during the study. The fully automated algorithm will be tested in a home setting, however, the methodology will be developed and approved for testing later in the study.
National multi-center non-interventional case-control cohort study with collection of biological samples to characterize the autoimmune T and B lymphocytes involved in the development of type 1 diabetes.
Islet transplantation is an effective modality for treating type 1 diabetes. Despite marked progress in clinical islet transplantation with the achievement and maintenance of insulin independence in over half of recipients up to 5 years, transplant approaches are limited to those that struggle to control their diabetes. Furthermore, this approach remains restricted due to the scarcity of human pancreas donors. While transplanting insulin-producing cells into the liver has been demonstrated as an efficacious means of restoring glycemic control to patients with T1D, the procedure often results in cell loss, and carries risks. Moreover, transplant in to the liver does not permit imaging or retrieval of donor islets. The ability to retrieve the cells is also important for safety reasons. In theory, the space under the skin is an attractive alternate site for transplanting insulin producing cell, due to ready access, and potential for monitoring cellular transplant function through novel imaging techniques. However, transplantation of insulin producing cells into an unmodified site under the skin universally fails to reverse diabetes in research animal models, or in human studies. Other techniques using devices with different type of technologies and biomaterials have been explored with variable success. Unfortunately, the foreign body and inflammatory reaction persist in the implant. Shapiro Lab, has developed a novel technique called 'device-less' (DL) transplant modality. This approach was designed to harness an innate foreign body response in a favorable and controlled manner, to induce growth of new blood vessels to allow the survival of the insulin producing cells without the natural body response to foreign body. Briefly, this site transforms the inhospitable under the skin site into a viable location through the temporary implantation of a small tube called angiocatheter. For this study, 5 patients will received transplant in to the modified site under the skin using the DL transplant technique.
An intensive 13 weeks program that aims to improve glucose control in children with type 1 diabetes.