View clinical trials related to Type 1 Diabetes Mellitus.
Filter by:This study evaluates the use of an established internet-based cognitive behavioral therapy intervention in a group of adolescents with type 1 diabetes and mild to moderate depressive symptoms. Half of the participants will receive the internet-based intervention while the other half will receive usual care.
The main goal of this study is to find a reasonably safe and tolerable treatment for adult patients with type 1-diabetes and that regain some of the endogenous insulin secretion, improve the patients' quality of life (QoL) and reduce the risk of both short- and long-term complications. The hypothesis tested is that oral GABA treatment with the newly developed compound Remygen will be safe and induce regain of some endogenous insulin secretion in adult patients with type 1-diabetes diagnosis for more than five years. The first part of the study will include 6 patients and be performed as a Safety and Dose Escalation study in three steps. The main study is a three-arm, open label, single center, clinical trial. Eligible patients will be randomized into one of three active treatment arms to receive oral GABA treatment for 6 months.
The purpose of this study is to determine whether 8 weeks of Liraglutide or Golimumab can transiently improve beta cell function in patients with longstanding Type 1 diabetes (T1D) who secrete proinsulin and little/no C-peptide.
Over 1.25 million Americans have type 1 diabetes (T1D), increasing risk for early death from cardiorenal disease. The strongest risk factor for cardiovascular disease (CVD) and mortality in T1D is diabetic kidney disease (DKD). Current treatments, such as control of hyperglycemia and hypertension, are beneficial, but only partially protect against DKD. Hyperfiltration is common in youth with T1D, and predicts progressive DKD. Hyperfiltration is also associated with early changes in intrarenal hemodynamic function, including increased renal plasma flow (RPF) and glomerular pressure. Intrarenal hemodynamic function is strongly influenced by the renin-angiotensin-aldosterone system (RAAS), which is also considered a key player in the pathogenesis of DKD. Preliminary data demonstrate differences in intrarenal hemodynamic function and RAAS activation in early and advanced DKD in T1D. However, the pathophysiology contributing to the differences observed in RAAS activation and intrarenal hemodynamic function in T1D are poorly defined Animal research demonstrates that arginine vasopressin (AVP) acts directly to modify intrarenal hemodynamic function, but also indirectly by activating RAAS. Preliminary data suggest that elevated copeptin, a marker of AVP, which predicts DKD in T1D adults, independently of other risk factors. However, no human studies to date have examined how copeptin relates to intrarenal hemodynamic function in early DKD in T1D. A better understanding of this relationship is critical to inform development of new therapies targeting the AVP system in T1D. Accordingly, in this study, the investigators propose to define the relationship between copeptin and intrarenal hemodynamics in early stages of DKD, by studying copeptin levels, renal plasma flow, and glomerular filtration in youth (n=50) aged 12-21 y with T1D duration < 10 y.
This study aims to clarify the underlying hereditary and autoimmune factors that contribute to clinical type 1 diabetes and gain a better understanding of the natural history of the disease.
1. The accuracy of the sensors (Dexcom G5 vs FreeStyle Libre Flash glucose monitoring) will be evaluated by simultaneous wearing of the 2 sensors during 2 weeks. During these 2 weeks the patients will do at least four capillary blood glucose measurements to compare with the sensor results. 2. Patient satisfaction will be evaluated using a questionnaire that will be completed after the Dexcom G5 sensor has been worn for 1 month. 3. The data recorded by the FreeStyle Libre Flash glucose monitoring system (average glucose,% above target, % within target, % under target, amount of hypoglycemia) in the month prior to the 2 weeks of double sensor wear will be compared to the same data recorded by the Dexcom G5 mobile CGM system during the first month of use.
Subjects with type 1 diabetes will be observed in the diabetes research center clinic following a meal and an insulin injection. Breath and sweat samples will be collected at intervals throughout the visit, with increased frequency during hypoglycemia. Collaborators with the MITRE Corporation will perform analyses on these samples to identify any relationships between volatile organic compounds in breath and sweat and hypoglycemia.
This is a 3-month extension study (DCLP3 Extension) following a primary trial (DCLP3 or NCT03563313) to assess efficacy and safety of a closed loop system (t:slim X2 with Control-IQ Technology) in a large randomized controlled trial. Upon completion of the NIH 3-month extension study, subjects will be invited to participate in a continued use phase with Control-IQ Technology, funded by Tandem Diabetes Care, until the equipment has received FDA approval for commercial use.
Our lab has developed an artificial pancreas system called the McGill Artificial Pancreas (MAP) for automating insulin delivery. Using patient's basal-bolus parameters (basal rates and ICRs), the artificial pancreas involves a control algorithm that modulates insulin infusion based on the sensor readings and meal information. However, because basal-bolus parameters are difficult to optimize, proper glycemic control is not always achieved. Therefore, we have developed a learning algorithm that estimates optimal basal-bolus parameters using data over several days. The algorithm examines daily glucose, insulin, and meal data to make changes in patients' basal rates and ICRs. The objective of this project is to test our artificial pancreas system with and without the learning algorithm using a randomized crossover design in between 31 and 67 children and adolescents at camp Carowanis. We hypothesize that adding a learning algorithm to the artificial pancreas will improve the performance of our artificial pancreas system by increasing the time spent in target glucose range (4mmol/L - 10mmol/L) compared with the artificial pancreas system alone.
The objective of the study is to assess efficacy and safety of a closed loop system (t:slim X2 with Control-IQ Technology) in a large randomized controlled trial.