Active clinical trials for "Diabetes Mellitus, Type 1"

Type 1 Diabetes (T1D) is an autoimmune disease. This means that the immune system (the part of the body which helps fight infections) mistakenly attacks and destroys the cells that produce insulin (islet cells found in the pancreas). As these cells are destroyed, the body's ability to produce insulin decreases. The autoimmune process is thought to be initiated by a gene-environment interaction. The genetics involved in the development of T1D are fairly well understood. There is a higher risk of developing T1D with the presence of the human leukocyte antigen (HLA) DR3 or DR4. It is also known that not everyone with these genes actually develops T1D. Therefore, one or more environmental factors are thought to contribute to the process of developing T1D. The consumption of the anti-inflammatory fatty acids, the omega-3 fatty acids, has decreased significantly in the past 100 years. At the same time a rise in the incidence of T1D, especially in young children has occurred. Because of the warnings to eliminate fish during pregnancy, pregnant women are consuming even less omega-3 fatty acids during fetal development. Observations have been made that children who have received omega-3 fatty acid supplementation have a lower risk of T1D. Omega-3 fatty acids could have a protective effect that may occur during pregnancy, infancy, or both. The mechanism of this protection may be due to the DHA mediated suppression of the inflammatory response. Patients at higher risk for T1D have an increased pro-inflammatory environment. We hypothesize that DHA supplementation during pregnancy and early childhood will block the initial pro-inflammatory events and prevent development of islet cell autoimmunity in children at higher risk for T1D. This study is a feasibility study to determine if a full-scale DHA supplementation study will be implemented. If a full study is implemented, the primary outcome will be to determine if nutritional supplementation with omega-3 fatty acids during the last trimester of a mother's pregnancy and/or the first three years of life for children who are at higher risk of T1D will prevent the development of islet autoimmunity.

This is a multi-center, randomized controlled trial to test whether a clinic-integrated, low intensity, multi-component behavioral intervention is effective in preventing the deterioration in glycemic control, treatment adherence, and quality of life that commonly occur during late childhood and early adolescence in youth with type 1 diabetes. The study will also examine mechanisms and processes that influence the effectiveness of family management of diabetes during this developmental period.

Diabetes mellitus is a long-term multi-organ disease with severe implications that constitute a major health problem worldwide. Type 1 diabetes is an autoimmune disorder in which the body's own immune system attacks and destroys the cells that make insulin. Exogenous administration of insulin is the primary method of controlling type 1 diabetes by regulating blood glucose levels, but this treatment does not reverse nor prevent disease progression. Our hypothesis is that when implanting stimulated total bone marrow by arterial injection directly into the pancreas, we will achieve functional recovery of insulin-producing cells. This study will include patients with chronic type 1 diabetes and absence of lesions in target organs. We will follow the evolution of patients receiving autologous total bone marrow implantation by selective catheterization and compare to a non-treatment control group. All subjects will continue to use insulin therapy as needed to maintain the best possible glucose control. The objective is to achieve a significant increase in C-peptide levels indicating a regeneration of the beta islet cells with a decrease in exogenous insulin usage in at least 70% of the patients. This study is a follow-up to our initial study in which 22 patients received autologous total bone marrow. The initial study was 100% safe but additional studies like the one described above are needed to show efficacy.

Type 1 diabetes is a common chronic disease of childhood. It is not yet preventable. Multiple daily injections of insulin, tests of blood sugar, and careful dietary planning are required lifelong to prevent long-term complications such as blindness and kidney failure. Recent studies of potential risk factors in children with diabetes, along with studies revealing the immunologic properties of vitamin D, and experiments in animals suggest higher doses of vitamin D may prevent type 1 diabetes. For proof for human children, a randomized trial will compare groups at risk randomly assigned to receive either the usual vitamin D supplement or a higher amount, 2000 IU daily. This initial study is a small scale test of procedures.

The primary aim is to evaluate the anti proteinuric effect of increasing doses of the ACE inhibitor, lisinopril: 20, 40 and 60 mg daily in type 1 diabetic patients with hypertension and diabetic nephropathy. The secondary aim is to evaluate the effect on blood pressure (24 hour ambulatory blood pressure) and kidney function (glomerular filtration rate (GFR)). The tertiary aim is to evaluate differences in response to treatment according to ACE/insertion/deletion (ID)-genotypes and other genetic variants in the genes of the renin angiotensin system.

OBJECTIVE: This study is being conducted by the Type 1 Diabetes TrialNet Study Group, funded by the National Institutes of Health, in collaboration with the European C-Peptide Group. The goal is to evaluate comparability and reproducibility of measures of beta cell function in type 1 diabetes comparing the mixed meal tolerance tests (MMTT) and glucagon stimulation test (GST). These two tests will be compared to assess the relationship between the MMTT and IV (intravenous) Glucagon stimulated C-peptide responses as measured by time to peak C-peptide and AUC (area under the curve) values. Based on the understanding that type 1 diabetes results from an immune mediated loss of pancreatic beta cells, therapeutic trials and newer measures of beta cell function can be evaluated as endpoints for clinical trials. Direct assessment of residual beta cell function is an appropriate endpoint, as retention of beta cell function in patients with T1D is known to result in improved glycemic control and reduced hypoglycemia, retinopathy and nephropathy. Endogenous beta cell function or insulin secretion is best measured by determination of C-peptide (which is co-secreted with insulin in a 1:1 molar ratio). Intervention studies over the past few decades have usually used measurement of C-peptide. However, the relationship between these or other measures of beta cell function has not been well studied. The relative advantages of one measure over another in terms of variability, sensitivity and burden to the subject is unknown. In addition, the optimal conditions for the conduct of the test need to be determined. An important goal is to develop an international consensus about the conduct of metabolic tests in the context of large, multicenter trials involving type 1 diabetes (T1D) by balancing the scientific data with the burden on the subject.

This trial is conducted in the United States of America (USA). The aim of this trial is to assess control of blood sugar, safety, and patient acceptance of insulin aspart compared to insulin lispro, both in insulin pumps, in standard clinical practice.

Closed-loop strategy is composed of three components: glucose sensor to read glucose levels, insulin pump to infuse insulin and a dosing mathematical algorithm to decide on the required insulin dosages based on the sensor's readings. The objective of this pilot study is to inform both the decision whether to conduct a confirmatory study and the design of the larger confirmatory trial. In addition, we want to estimate postprandial glucose levels parameters and confidence interval in an 11-hour in-patient study with standardized conditions in adults with type 1 diabetes, estimate the size and direction of the treatment effect. Faster insulin Aspart (FiAsp) will provide preliminary evidence of efficacy to regulate postprandial glucose levels compared to rapid-acting Aspart in adults with type 1 diabetes using insulin pump therapy.

Randomized, controlled, double-blinded, multicenter, phase I/II clinical trial to evaluate the safety of low-dose IL-2 and determine whether low-dose IL-2 therapy for one year, can prevent further loss of beta-cell function in patients with established T1D, (primary outcome). The study will carefully examine various effects of low-dose IL-2 on the immune system in patients with T1D, including effects on Treg and other cell subsets, and disease-specific autoimmune responses.

Closed-loop strategy is composed of three components: glucose sensor to read glucose levels, insulin pump to infuse insulin and a dosing mathematical algorithm to decide on the required insulin dosages based on the sensor's readings. A dual-hormone closed loop strategy regulates glucose levels through the infusion of two hormones: insulin and glucagon. The objective of this study is to compare, in a randomized multicenter trial, the effectiveness of single-hormone closed-loop, dual-hormone closed-loop, and sensor-augmented pump therapy with low-glucose suspend in regulating day-and-night glucose levels in outpatient settings for 15 weeks in adolescents and adults. The investigators hypothesize that dual-hormone closed-loop will reduce time spent in hypoglycemia compared to single-hormone closed-loop, which in turn will be more effective than sensor-augmented pump therapy with low-glucose suspend.