Active clinical trials for "Diabetes Mellitus, Type 1"

This trial will study the ability of islet transplantation to restore glycemic control and achieve insulin independence in type 1 diabetic subjects with life-threatening hypoglycemia and unawareness, or recurrent hyperglycemia with ketoacidosis.

The purpose of this study is to see if giving the study drug in a slow and steady dose will lower blood sugars during the meal and after-meal time.

Insulin dependent diabetes mellitus (also called type 1 diabetes mellitus or T1DM) is caused by the destruction of insulin-producing cells in the pancreas. People with T1DM do not produce enough insulin, which is necessary for proper regulation of blood sugar levels. T1DM is an autoimmune disease. An autoimmune disease is a disease in which the body's immune system attacks the body itself. In addition to regulating blood sugar, insulin may have the ability to protect cells in the pancreas from attack by the immune system. This study will evaluate whether an insulin-based vaccine can protect cells from autoimmune destruction. Study hypothesis: IFA-enhanced human insulin B-chain vaccination will lead to the arrest or slowing of the ongoing autoimmunity, and this will result in an appreciable difference in functioning B cell mass compared to the placebo treated group by the end of the study.

The purpose of the study is to determine whether E1 and G1 are safe and effective in the treatment of type 1 diabetes. Type 1 diabetes is an autoimmune disease, in which the immune system attacks pancreatic beta cells. These cells produce insulin, which regulates blood glucose. The mainstay of current treatment for type 1 diabetes is dietary control and daily parenteral administration of insulin. Recent diabetes research has increasingly focused on pancreatic islet cell replacement, either by islet cell transplantation or by endogenous regeneration of islet cells. During fetal development, islet precursor cells proliferate and differentiate into mature beta cells capable of producing insulin. This process is known as islet cell neogenesis. Islet cell neogenesis normally ceases around birth, however, the adult pancreas still retains significant potential for islet regeneration, as shown by tissue repair following pancreatic injury. Pre-clinical studies have shown that E1 and G1 can re-establish islet cell neogenesis and increase pancreatic insulin production in diabetic animal models. It is therefore postulated that treatment with E1 and G1 may produce islet cell regeneration in type 1 diabetic patients.

The long-term effects of high blood sugar include blindness, kidney failure, and nerve damage that can ultimately cause loss of limbs. Research has shown that high blood sugar increases the amount of reactive oxygen species (ROS) produced in diabetics, and that the increase in ROS causes damage to eyes, kidneys, and nerves by a process called "oxidative stress." We postulate that alpha-lipoic acid, a potent anti-oxidant, can stop ROS from forming, thereby preventing long-term complications in diabetes. In this pilot study, we will be giving 30 teenagers with type 1 diabetes (T1D) controlled-release alpha-lipoic acid for 3 months, and comparing the amount of oxidative stress before and after treatment. Ten teenagers with T1D will receive placebo instead of alpha-lipoic acid and undergo the same research protocol to aid in validation of outcome measures.

An initial pilot and feasibility study will be conducted using a Sequential, Multiple Assignment, Randomized Trial (SMART) design to identify acceptable and effective dietary strategies to optimize both glycemic control and weight management in young adults with Type 1 diabetes (T1D). This pilot trial will include a ten-and-a-half month behavioral intervention, with co-primary outcomes of glycemic control (HbA1C and hypoglycemia) and weight loss. The pilot trial will assess acceptability and adherence to three distinct, evidence-based dietary approaches designed to address weight management and glycemic control. Behavioral counseling strategies, use of carbohydrate counting for insulin dosing, and encouragement of physical activity will be the same across the three dietary approaches. COVID-19 PROVISIONS: Due to restrictions in place on in-person visits due to COVID-19 precautions, some subjects may remain in the study longer than 10.5 months. As of June 2020, the study transitioned to a completely virtual format. Those who were due for a measurement visit during the time that research activities were halted, prior to the approval of the virtual procedures, remained on the diet they were currently assigned to, supported by bi-weekly Registered Dietitian (RD) counseling, until they were able to be scheduled for a virtual visit.

This study will consist of a randomized controlled trial to test a novel Transdisciplinary Care (TC) model of delivery of care for type 1 diabetes in adolescence. Adolescents and their parents/caregivers (n=150) will be randomized to Usual Care or TC care in a 1:2 ratio. Approximately half of those in TC care will received TC in person and half will receive it through telehealth. TC visits will consist of conjoint management of T1D by a TC team consisting of an Advanced Practice Nurse, Dietitian and Psychologist who will see parent-adolescent dyads together within the same visit. TC team members have trained each other in their respective disciplines. Outcome measures include glycohemoglobin (HbA1c) and questionnaires assessing diabetes self management behaviors. Other ancillary/exploratory measures are also completed.

Achieving near-normoglycemia has been established as the main objective for most patients with diabetes. Despite growing evidence about the health benefits of regular exercise in diabetes, exercise-associated glycemic imbalance remains a challenge in subjects with type 1 diabetes (T1D) due to a higher risk of hypoglycemia. Automatic glucose control, the so-called artificial pancreas (AP) or closed-loop system, may represent the ideal solution for reaching the therapeutic goals in diabetic patients. Intuitively, closed-loop insulin delivery may be superior to open-loop insulin delivery due to a better compensation of the variability of subcutaneous insulin absorption and the intra-subject insulin sensitivity. However, several challenges exist to effectively realize an optimal closed-loop control of blood glucose during exercise. Indeed, the physical exercise induces one of the major glucose perturbations that need to be controlled by an artificial pancreas and is currently one of the main challenges found in clinical validations of the few existing prototypes of an artificial pancreas. In particular, experiments carried out with the currently used algorithms for glucose control (the so called PID (proportional-integrative-derivative) and MPC) showed that closed-loop insulin delivery is deteriorated by exercise, increasing the risk of hypoglycemia even with pre-exercise carbohydrate ingestion when non-announcement strategies are used. In this project, a rigorous clinical testing of a novel closed-loop controller ('artificial pancreas') will be carried out in T1D patients treated with continuous subcutaneous insulin infusion (CSII). The innovative element of the controller is a safety auxiliary feedback based on sliding mode reference conditioning (SMRC), which has been demonstrated to limit over-insulinization and the resulting hypoglycemia, reducing glycaemic variability. Announced and unannounced exercise will be performed in T1D subjects treated with CSII, comparing the number of hypoglycemic episodes with a controller-driven insulin delivery (closed-loop study) based on continuous subcutaneous glucose monitoring (CGM). If any glucose value <70 mg/dL 15 gr of glucose will be provided. Moreover 15gr of glucose will be provided in AP studies when AP system recommends it. The hypothesis is that closed loop control will provide better glycemic control, with less hypoglycemia episodes.

Insufficient sleep and sleep irregularity (variability in sleep duration) are increasingly recognized as important contributors to glucose control and diabetes distress in type 1 diabetes (T1D). Up to 40% of adults with T1D had a sleep duration less than 6-6.5 hours per night. Diabetes distress is reported (40% prevalence) in individuals with T1D and is associated with poor glucose control. Despite findings that sleep disturbances are common in T1D, the current understanding of the effects of strategies to improve sleep on diabetes distress, and glucose control is limited. The purpose of this pilot study is to evaluate the effects of a sleep intervention on sleep duration, diabetes distress and glucose control in individuals with T1D and habitual short sleep. A randomized controlled trial in 20 adults aged 18 to 65 years with T1D is proposed. Eligible participants will be randomly assigned to a sleep intervention group or a control group. Differences between the two groups on the outcomes of sleep duration, diabetes distress and glucose control will be evaluated. Findings from this proposed pilot study will serve as the foundation for a larger clinical trial to improve sleep, reduce diabetes distress, and improve glucose control.

This is prospective randomized open single center clinical study to compare effect of sirolimus vs mycophenolate tacrolimus based protocol on pancreas and kidney graft survival in simultaneous pancreas and kidney recipients.