View clinical trials related to Type 1 Diabetes.
Filter by:A single-arm, multi-center, clinical study to assess the safety profile of the Tandem t:slim X2 with Control-IQ system in children with T1D aged 2-6 years old under free living condition
This prospective, open-label pilot/feasibility study of 10 youth with T1D is to evaluate glycemic and metabolic changes taking place with a very low carbohydrate diet.
Glucagon regulation and response in persons with T1D at the basal state and in response to various stimuli remains unclear. Dr. Philip Cryer has previously reported that, in T1D young adults with a course of the disease of 16+9 years, the absence of endogenous insulin secretion results in increased glucagon secretion after a mixed meal, concluding that endogenous insulin reciprocally regulates the alpha-cell glucagon secretion and also suggesting that glucagon dysregulation may play an important role in post-prandial hyperglycemia in T1D. Interestingly, recent research on human islets have shown that insulin inhibits counter-regulatory glucagon secretion by a paracrine effect mediated by SGLT2-dependent stimulation of somatostatin release. An important gap in our knowledge is whether the timing of prandial insulin doses affects the glucagon response to a hyperglycemic stimulus in patients with T1D who have undetectable C-peptide. Whether appropriately timed exogenous insulin can modify the glucagon response to glucose fluctuations has not been studied. As such, this pilot study aims to characterize the glucagon response to meal-time hyperglycemia and to compare the difference in glucagon secretion when mealtime bolus insulin is given before the meal versus after the meal with the objective of understanding factors that contribute to the peak post-prandial blood glucose and AUC of blood glucose after a mixed meal in this target population.
Type 1 diabetes (T1D) is a complex metabolic disorder with many pathophysiological disturbances including insulin resistance (IR) and mitochondrial dysfunction which are causally related to the development of diabetic kidney disease (DKD) and which contribute to reduced life expectancy. Renal hypoxia, stemming from a potential metabolic mismatch between increased renal energy expenditure and impaired substrate utilization, is increasingly proposed as a unifying early pathway in the development of DKD. By examining the interplay between factors responsible for increased renal adenosine triphosphate (ATP) consumption and decreased ATP generation in young adults with and without T1D, this study hopes to identify novel therapeutic targets to impede the development of DKD in future trials. The investigators propose to address the specific aims in a cross-sectional study with 30 adults with T1D and 20 controls without a diagnosis of diabetes. For this protocol, participants will complete a one day study visit at Children's Hospital Colorado. Patients will undergo a Dual-energy X-Ray Absorptiometry (DXA) scan to assess body composition, renal Magnetic Resonance Imaging (MRI) to quantify renal oxygenation and perfusion, and a Positron Emission Tomography/Computed Tomography (PET/CT) scan to quantify renal O2 consumption. After the PET and MRI, participants will undergo a hyperinsulinemic-euglycemic clamp to quantify insulin sensitivity. Glomerular Filtration Rate (GFR) and Effective Renal Plasma Flow (ERPF) will be measured by iohexol and PAH clearances during the hyperinsulinemic-euglycemic clamp. To further investigate the mechanisms of renal damage in T1D, two optional procedures are included in the study: 1) kidney biopsy procedure and 2) induction of induced pluripotent stem cells (iPSCs) to assess morphometrics and genetic expression of renal tissue.
The main objective of this study is to determine whether home use of day and night closed loop insulin delivery under free living conditions applying faster insulin aspart (FiAsp) is non-inferior to home use of closed-loop applying standard insulin aspart. This is a double-blind, multi-centre, randomised, crossover design study, involving a run-in period followed by two study periods during which glucose levels will be controlled either by an automated closed-loop system using standard rapid acting insulin analogue or by an automated closed-loop system using faster insulin aspart in random order. Subjects will receive appropriate training in the safe use of closed-loop insulin delivery system. Subjects will have regular contact with the study team during the home study phase including 24/7 telephone support. The primary outcome is time spent in target range between 3.9 and 10.0 mmol/L as recorded by CGM during home stay. Secondary outcomes are the HbA1c, time spent with glucose levels above and below target, as recorded by CGM, and other CGM based metrics.
Despite recent pharmacological and technological advantages, hypoglycemia remains to be the key limiting factor in achieving optimal glycemic control in people with type 1 diabetes. State-of-the-art treatment for type 1 diabetes is insulin in pens or pumps that focus on reducing hyperglycemia after relative insulin deficiency e.g. after food intake. In recent years, we focused on adding low-dose glucagon to insulin therapies for the treatment and prevention of hypoglycemia - referred to as "dual-hormone treatment". We have shown that low-dose glucagon is efficient in treating mild hypoglycemia and that several factors may affect its glucose response. Our next step is to test whether the combined delivery of insulin and glucagon can improve glucose control in individuals with type 1 diabetes. In this proposal, we want to test the efficacy, safety and feasibility of a dual-hormone closed-loop system, also known as an artificial pancreas. The closed-loop system involves automatic infusion of glucagon and insulin based on continuous glucose measurements. The system will be tested in a 33-hour in-clinic study comparing the glucose control by the combined automatic delivery of insulin and glucagon with the automatic delivery of insulin-only. The study is performed at Steno Diabetes Center Copenhagen (SDCC) in collaboration with the Technical University of Denmark (DTU). We expect that the study will clarify whether low-dose glucagon added to insulin therapy can improve the glucose control in adults with type 1 diabetes. We believe that the utilization of glucagon will allow for a weight neutral optimization of glucose control, reduce risk of hypoglycemia and reduce disease burden that will reduce diabetes complications and cardiovascular diseases.
The purpose of this study is to 1) convene African American and Latino Community Coalitions to adapt Family Teamwork (FT) for school-age youth, and integrate FT with the Smart and Secure Children (SSC) program community-based, peer delivery format, 2) identify facilitators and barriers to parental involvement in diabetes management for African American and Latino parents of children (5-9 years) with T1D to refine, with Community Coalitions the adapted and integrated Family Teamwork- Peer Delivery (FT-P), and 3) evaluate the feasibility, satisfaction, and preliminary outcomes of the FT-P program among African American and Latino parents of school-aged children (5-9 years) withT1D. A randomized pilot trials will be conducted with African American and Latino families to examine the feasibility, parent satisfaction, and preliminary outcomes of FT-P. Families will be stratified by race/ethnicity, age, and HbA1c strata, and randomized to FT-P plus standard diabetes care or to standard diabetes care alone after completion of baseline assessment using a random numbers table generated by a program created through Baylor College of Medicine's Institute for Clinical Training and Research data management specialists.
Observational study of patients at Boston Childrens Hospital with type 1 diabetes (T1D) who elected to treat their diabetes with the Medtronic 670 G hybrid closed loop insulin pump.
In this study, liver samples will be collected, processed and stored in a specialized, clinical grade, cell bank for potential future clinical use. A set of ex-vivo immunogenicity and transdiffrentiation tests will be carried to confirm the ability of this cryopreserved cell batch to be used as clinical grade raw material. Biopsies will be collected during TP or PP with the assumption that some of the patients (especially PP patients will not go through Islets autotransplantation) will develop brittle diabetes, thus Orgenesis therapy can provide them in the long run, a treatment. In terms of T1DM the purpose is to have available clinical grade raw material for cell replacement therapy. The collected liver samples will be proliferated (up to passage 4) for future use. A portion of the stored cells will be utilized in a small-scale process to test possible immunogenicity performed on the collected blood sample. The assay will provide data whether immunomodulation treatment will be required in the future clinical trials. Also the transdffrentiated cells (AIPs) will be tested according to release criteria relevant for clinical IPC production. Liver biopsy donors will be contacted upon approval of the consecutive study and will have study recruitment priority. The donors can refuse to participate in the future study or may not need the therapy, however, their biopsies will be stored for a potential use if required, after the therapy is approved.
Postprandial glycemic excursions are major determinants of overall glycemic control in type 1 diabetes. Carbohydrate content of ingested meals is the main determinant of post-meal glucose excursion. Accurate carbohydrate counting is a critical aspect of managing postprandial blood glucose levels. accurate carbohydrate counting is considered by patients as a significant burden and frustrating task. The closed-loop system (CLS) 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 study is to compare the efficacy of two strategies to regulate glucose levels in outpatient settings in adults with type 1 diabetes: 1) single-hormone CLS with rapid acting insulin analogue combined with carbohydrate counting; 2) single-hormone CLS with rapid acting insulin analogue combined with simplified qualitative meal-size estimation. A sub-study will also be proposed to participants. Postprandial exercise combines two situations complicating CLS operation: a high plasma insulin due to insulin on-board related to meal boluses and rapid blood glucose changes (postprandial blood glucose excursion and then drop during exercise) making input from the glucose sensor less accurate. The objective of this sub-study will be to explore the safety and efficacy of the CLS using the combined strategy of pre-meal exercise announcement and meal bolus reduction of 33% when exercise is performed 1 hour compared to 2 hours post meal time.