View clinical trials related to Type 1 Diabetes.
Filter by:Hypothesis 1: Treatment with Liraglutide in patients with type 1 diabetes decreases fasting, postprandial and the overall mean glucose concentrations. Aim 1.1: To compare the mean fasting, the mean weekly glucose and the standard deviation of weekly blood glucose concentrations as recorded by continuous glucose monitoring prior to and following 6 weeks and 12 weeks of treatment with 0.6, 1.2 and 1.8 mg of liraglutide daily. In addition, the time spent at glucose concentrations >150 and 200mg/dl and <70 and <40 mg/dl will also be compared. Aim 1.2: To compare the postprandial glucose concentrations following a test meal before and after 12 weeks of treatment with 0.6, 1.2 and 1.8 mg of liraglutide daily. Glucose concentrations will be measured as areas under the curve for the data obtained from the meal challenge. Aim 1.3: To compare HbA1c levels(glycated hemoglobin) before and after 12 weeks of treatment with 0.6, 1.2 and 1.8 mg of liraglutide daily Hypothesis 2: Treatment with Liraglutide in patients with type 1 diabetes decreases postprandial glucagon concentrations and increases postprandial C-peptide concentrations. Aim 2.1: To compare fasting and postprandial glucagon and C-peptide concentrations following a test meal before and after 12 weeks of treatment with 0.6, 1.2 and 1.8 mg of liraglutide daily. Hypothesis 3: Treatment with Liraglutide in patients with type 1 diabetes delays gastric emptying. Aim 3.1: To compare the gastric emptying as measured by acetaminophen absorption before and after 12 weeks of treatment with 0.6, 1.2 and 1.8 mg of liraglutide daily.
The glucose lowering effects of GLP-1 agonists are well established in subjects with type 2 diabetes, however, these have not been studied prospectively in subjects with type 1 diabetes. The investigators have, therefore, designed this study to investigate the central hypothesis that in patients with type 1 diabetes, Liraglutide has a glucose lowering effect. A major secondary objective of this study is to elucidate the mechanisms responsible for its glucose lowering effects and those involved in reducing the insulin dose. The specific aims of this proposal are: Hypothesis 1: Treatment with Liraglutide in patients with type 1 diabetes decreases HbA1c, fasting, postprandial and the overall mean glucose concentrations while decreasing the dose of insulin required. Hypothesis 2: Treatment with Liraglutide in patients with type 1 diabetes decreases basal and postprandial glucagon concentrations and increases basal and postprandial C-peptide concentrations. Hypothesis 3: Treatment with Liraglutide in patients with type 1 diabetes delays gastric emptying.
This is the first prospective randomized double-blind placebo-controlled study to investigate the effect of a GLP-1 analog, specifically liraglutide, on blood glucose levels and variability in subjects with type 1 diabetes treated with insulin. Liraglutide is the preferred GLP-1 analog for this study because the pharmacokinetics and pharmacodynamics of the drug are consistent with a sustained duration of action. The current gold standard for management of type 1 diabetes is based on insulin replacement with novel analogs with specified pharmacodynamic profiles or with unique insulin delivery systems (insulin pump therapy). No other adjuvant therapy has demonstrated sustained benefit in this population. This study will also investigate the effect of liraglutide on suppression of glucagon secretion during meal challenges. This is of particular importance since, in the absence of insulin secretion from the β-cell, there is no paracrine inhibition of glucagon secretion by the α-cell. Dysregulation of glucagon secretion may impact the glycemic control and overall pathogenesis in those with type 1 diabetes. The use of CGM technology in this study will allow us to determine the rapidity, consistency, and sustainability of any response to liraglutide.
The purpose of this study is to see if the use of metformin and sitagliptin used in conjunction with insulin can improve the blood sugars of teenagers with Type 1 diabetes.
Achieving near-normoglycaemia has been established as the main objective for most patients with diabetes. However, it is well known that intensification of treatment is associated with an increase in the frequency of hypoglycemia, especially in the context of insulin therapy. The burden of hypoglycemia in terms of psychological implications, morbidity and even mortality, explains why it has been defined as the main limiting factor to achievement of good metabolic control. Continuous subcutaneous glucose monitoring (CGM) devices have been claimed to be useful in hypoglycemia detection/prevention, allowing theoretically for safer intensification of therapy in diabetic patients. However, accuracy of CGM devices, especially in the hypoglycemic range, raises some concerns. In fact, commercially available CGM devices estimate plasma glucose from measurements in the interstitial fluid and not in plasma. However, the relationship between plasma and interstitial glucose is not fully understood, especially under dynamic conditions, and this may explain the poor CGM performance during rapid changes in blood glucose and hypoglycemia. In this project, the relationship between plasma and interstitial glucose will be evaluated under conditions of normal glucose concentrations and hypoglycemia. Experiments will be performed to assess the role, if any, of different plasma insulin concentrations on the accuracy of CGM. All the information obtained may be relevant to the improvement of the ability of CGM devices to detect hypoglycemia and hypoglycemic risk.
- BACKGROUND: Individuals with diabetes report innate preference for sweet foods, possibly due to genetic variants. In addition, studies have shown that ingestion of fructose promotes lower postprandial blood glucose, compared to glucose. However, excessive intake may increase triglycerides, uric acid and oxidative stress, due to oxidative priority. - AIMS: To investigate the influence of fructose and glucose and taste receptor, type 1, member 2 (TAS1R2) in glucose, triglycerides, uremia, oxidative stress, feelings related to food intake and palatability of individuals with type 1 diabetes. - METHODS: The trial is a single-blind, two-way crossover (1-week washout) study in 30 subjects with type 1 diabetes. Blood samples were collected before and 2-hours after the participants receive 75g of fructose or 75g of glucose dissolved in 200 ml water. Capillary blood glucose were assessed at 30, 90, 120, and 180 minutes to determine glucose, and visual analogue scales for measurement of appetite sensation were assessed at 70, 120, and 190 minutes. - PURPOSE: The research proposal adds knowledge about the TAS1R2 (Ile191Val) polymorphism and around the most suitable monosaccharide for individuals with diabetes type 1.
Currently, patients diagnosed with type 1 diabetes rely on either finger stick or sensor glucose readings when making their insulin dosage decisions. Designing a computerized system that mimics the way insulin is produced naturally in a person who does not have type 1 diabetes holds many challenges; all of which cannot be addressed in just one study. The purpose of the Medtronic Overnight Closed Loop study is to assess the performance of a system designed to automatically infuse the correct insulin dose during the hours that the patient is sleeping. The system consists of an insulin pump that provides insulin to the patient through an infusion set. A sensor inserted just under the patient's skin measures glucose levels and a transmitter sends this information to the pump. To enable the sensor to register the glucose information correctly, it must be set (calibrated) by a finger stick blood glucose 3-4 times a day. In the commercially released system, the physician would recommend the continuous background (basal) insulin rates and the patient would be required to make decisions regarding extra insulin (bolus) for meals or as a response to high glucose levels. In the Closed Loop System, a mobile control system is added to these devices. This consists of an Android phone, a closed loop algorithm and a translator. This system is designed to translate the sensor information and direct the pump to provide the required dosage of insulin automatically without requiring input from the patient. Reliable calibration has proved challenging, and so it is important that the system function safely, even when calibration is inaccurate. In this study, a calibration error will be introduced under very controlled circumstances. This testing will identify if the system can maintain acceptable overnight glucose levels, regardless of whether or not calibration is ideal.
Over the last years, a number of systems for continuous subcutaneous glucose monitoring have been marketed and are routinely used in patients with diabetes to obtain more detailed information about 24-hour glucose profiles. In the hospital, numerous factors influencing glycemic control and possibly leading to glucose excursions out of the desired range exist, e.g. interventions for which the patient has to remain fasting or medications such as corticosteroids or vasopressors. A reliable continuous glucose signal could help to observe levels of glycaemia not only at defined time-points but continuously, making it possible for physicians and nursing staff to better adjust antihyperglycemic therapy and to react before the patient is exposed to severe hypo- or hyperglycaemia. In the hospital setting, vascular access is granted in the majority of patients and could as well be used as an alternative site for continuous glucose monitoring. The aim of the present study is to assess accuracy of the glucose data obtained by means of an intravascular microdialysis-based CGM system against venous blood glucose reference measurements.
To examine the effects of different fixed pramlintide:insulin dose ratios in subjects with type 1 diabetes on postprandial plasma glucose concentrations
Islet transplantation can provide physiologic insulin replacement to patients with type 1 diabetes without the complications associated with whole pancreas transplantation. The purpose of this study is to achieve insulin-independence in patients with type 1 diabetes, thereby eliminating the need for exogenous insulin injections to maintain normal glucose levels, ameliorating severe hypoglycemia and potentially decreasing the development of diabetes-related complications. This study will investigate islet transplantation in subjects who have preserved renal function and subjects who have undergone cadaveric renal transplantation, since the latter subjects are already on immunosuppression. This is a single center, prospective trial of islet transplantation in subjects receiving islets alone or islets after kidney transplant. This is a phase I study investigating the use of islet transplantation for the treatment of type 1 diabetes. Subjects will be eligible for an islet transplant if they meet all of the inclusion criteria and none of the exclusion criteria outlined in the protocol. In brief, the aims of this study are to establish an islet transplant program at the Ohio State University, determine the safety of islet transplantation in islet alone and kidney transplant recipients, determine whether islet transplantation will reduce the frequency of severe hypoglycemic events, determine whether a novel steroid-free immunosuppressive protocol will prevent rejection in islet transplants and to achieve insulin independence at one year after the final islet transplant.