Active clinical trials for "Diabetes Mellitus, Type 1"

This study will test whether a new islet transplant procedure will enable patients with type 1 diabetes mellitus to stop insulin therapy. Islets are cell clusters in the pancreas that contain insulin-producing cells. The new procedure features three important advances, first developed by a group in Edmonton, Canada, over the way islet transplants have traditionally been performed: 1) the islets are transplanted immediately after they are removed from the donor; 2) islets are transplanted from two different donors in order to obtain the number of islets in a normal pancreas; and 3) the anti-rejection drug regimen is designed to reduce the harmful side effects of "conditioning" chemotherapy. (In the standard transplant procedure, patients receive intensive chemotherapy following the transplant. This study will use no radiation and lower-dose chemotherapy.) Patients between the ages of 18 and 65 with the diagnosis of type 1 diabetes mellitus for at least 5 years may be eligible for this study. Candidates will be screened with a medical history and physical examination, blood tests, chest X-ray and tuberculin skin test, electrocardiogram and exercise test for heart function, abdominal ultrasound, psychological evaluation, and an arginine stimulated c-peptide test. The latter test determines if the patient is producing any insulin. Eligibility is restricted to patients who make no insulin at all. The study has an active phase lasting 15 months and follow-up that continues indefinitely. Patients will receive 10,000 "islet equivalents" per kilogram (2.2 pounds) of body weight. This will likely require two separate transplant procedures from two donors. Before the first surgery, patients will be given anti-rejection (immune suppressing) drugs, including FK506 and rapamycin (orally) and daclizumab (intravenously). The islets will be infused through a tube placed in the portal vein (the large vein that feeds the liver). After surgery, patients will receive insulin intravenously for 24 hours. They will then have an abdominal ultrasound and blood tests to determine liver function. If fewer than 10,000 islets were transplanted, patients will continue insulin treatment, with the dosages adjusted to account for the transplanted islets. They will take Daclizumab every 2 weeks, and FK506 and rapamycin daily. Blood tests to follow how much of these drugs are in the blood stream will be performed daily at first and then weekly after blood levels of these drugs stabilize. They will be given antibiotics to prevent infections. The arginine test will be repeated 2 weeks after the transplant and periodically thereafter. Blood will be drawn weekly to check drug levels, and monthly for other tests. The investigators will track daily insulin requirements, and these will be recorded monthly. Patients who require a second transplant to achieve the required amount of islets will return for the procedure when a compatible organ is donated. The second procedure will be done as described above. As before, insulin will be infused for 24 hours following surgery. It will then be stopped, however, and will not be resumed unless blood glucose levels reach above 180 milligrams/deciliter. Patients will continue taking FK506 and rapamycin indefinitely. Daclizumab will be given every 2 weeks for 4 doses following the second transplant, and then stopped. Patients will take an antiviral called ganciclovir for 14 weeks and another antibiotic for 1 year following surgery. For the first year after surgery, patients will have frequent blood tests to monitor drug levels and immune function. They will return to NIH for a complete history and physical examination 2 and 3 years after the final islet transplant and will be contacted yearly by phone to ascertain their general health status and whether they remain insulin independent.

Ninety percent of patients with type-1-diabetes will develop late-diabetic complications in the eyes, kidneys, nervous- or cardiovascular-system. Poor glycaemic control is an important risk-factor for development of these late-diabetic complications. The Diabetes Control and Complications Trial (DCCT)-study showed, that improved glycaemic control can prevent the development and progression of these late-diabetic complications. Until now treatment with insulin- and diet-therapy has been the only treatment-modalities available to improve the glycaemic control in patients with type-1-diabetes. A substantial number of these patients still have long-standing poor glycaemic control despite intensive treatment with insulin- and diet-therapy. The antidiabetic drug metformin has shown to be able to improve the glycaemic control in combination with insulin and furthermore reduce both mortality and the risk of developing cardiovascular disease in patients with type-2-diabetes. Only few small studies have investigated the effect of treatment with metformin in patients with type-1-diabetes. These studies have suggested a positive effect of metformin in these patients too. Method: 100 patients with type-1-diabetes with persistent poor glycaemic control i.e. HbA1c > 8.5% during the last 12 months are eligible. Patients are treated for one month with placebo. Hereafter half of the patients will be treated with metformin and the other half continues with placebo for 12 months both as add-on therapy. All patients are continuing ongoing treatment with insulin throughout the study. Before and after the start of treatment with metformin the effect on glycaemic control and other known risk-factors for development of cardiovascular disease i. e. blood-pressure, fasting lipids, urine-albumine-excretion, endothelial dysfunction, inflammation, fibrinolysis etc. is assessed. This study will show if treatment with metformin can improve the glycaemic control and hereby the prognosis of patients with type-1-diabetes with persistent poor glycaemic control despite intensive treatment with insulin- and diet-therapy. This group of patients suffers the highest risk of developing late-diabetic complications with reduced quality of life and life-expectancy as a consequence.

This study will evaluate the safety and effectiveness of a continuous glucose monitor in children with Type 1 diabetes mellitus (T1DM).

This study will determine 1) the safety of AC2993 in patients with type I diabetes; 2) the ability of AC2993 to improve beta cell function; and 3) the effects of immunosuppression on beta cell function. Type I diabetes is an autoimmune disease, in which the immune system attacks the beta cells of the pancreas. These cells produce insulin, which regulates blood sugar. AC2993 may improve the pancreas's ability to produce insulin and help control blood sugar, but it may also activate the original immune response that caused the diabetes. Thus, this study will examine the effects of AC2993 alone as well as in combination with immunosuppressive drugs. Patients between 18 and 60 years of age who have type I diabetes mellitus may be eligible for this 20-month study. They must have had diabetes for at least 5 years and require insulin treatment. Candidates will be screened with a questionnaire, followed by medical history and physical examination, blood and urine tests, a chest x-ray and skin test for tuberculosis, electrocardiogram (EKG), and arginine stimulated C-peptide test (see description below). Participants will undergo the following tests and procedures: Advanced screening phase: Participants undergo a diabetes education program, including instruction on frequent blood glucose monitoring, dietary education on counting carbohydrates, intensive insulin therapy, review of signs and symptoms of low blood sugar (hypoglycemia), and potential treatment with glucagon shots. Patients must administer insulin via an insulin pump or take at least four injections per day including glargine (Lantus) insulin. 4-month run-in phase Arginine-stimulated C-peptide test: This test measures the body's insulin production. The patient is injected with a liquid containing arginine, a normal constituent of food that increases insulin release from beta cells into the blood stream. After the injection, seven blood samples are collected over 10 minutes. Mixed meal stimulated C-peptide test with acetaminophen: This test assesses the response of the beta cells to an ordinary meal and the time it takes for food to pass through the stomach. The patient drinks a food supplement and takes acetaminophen (Tylenol). Blood samples are then drawn through a catheter (plastic tube placed in a vein) every 30 minutes for 4 hours to measure levels of various hormones and the concentration of acetaminophen. Euglycemic clamp: This test measures the body's level of insulin resistance by measuring the amount of glucose necessary to compensate for an increased insulin level while maintaining a prespecified blood glucose level.

The purpose of this study is to evaluate the Extended Mio 30 infusion set (EM30IS) 7-day functioning compared to the regular Mio 30 infusion set (M30IS) 3-day functioning. The study will be carried out in adult patients with type 1 diabetes. Secondary objective, to evaluate the differences in glucose control between the infusion set currently used by participants (Medtronic Quick set infusion sets) and the Medtronic Mio 30 Infusion Set.

The aim of study is impact of additional treatment with new antidiabetic drugs (semaglutide or empagliflozine) compared to control group in T1DM patients - impact on endothelial function measured by FMD and FPF, arterial stiffness - measured by PWV, inflammatory biomarkers, markers of oxidative stress and endothelial progenitor cells (CD 34+/VDRL2, CD 133+/VDRL2) and correlation with glucovariability or time in range, measured with CGM system.

The biggest challenges for glycemic control during the day time involve meals and exercise variations, which are impacted by age, fitness level, duration, intensity and history of exercise. Meal variability has the benefit that meals are typically announced and quantified. Glucose control around exercise, on the other hand, is more complicated if the patient doesn't announce a change in activity level.

A single-center, prospective, 'open-label,' investigator-initiated pilot study evaluating the role of continuous glucose monitor (CGM) use either alone or with remote monitoring capabilities during pregnancy associated with T1DM.

This is a blinded cross-over study to see if extended wear insulin infusion sets can prolong insulin infusion set wear up to 7 days in adults with Type 1 Diabetes.

The primary objective of this project is to examine the impact of a continuous glucose monitoring (CGM) intervention on health and psychological outcomes in young children with type 1 diabetes (T1D).