Active clinical trials for "Diabetes Mellitus, Type 1"

The aim of this extension study is to assess the safety and efficacy of Mylan's insulin glargine and Lantus® in T1DM patients.

Type 1 diabetes mellitus (T1DM) is a chronic, autoimmune condition that involves the progressive destruction of pancreatic β-cells, eventually resulting in the loss of insulin production and secretion. Hence, an effective treatment for T1DM should focus on controlling anti-β-cell autoimmunity, combined with regeneration of lost pancreatic β-cell populations, with minimal risk to the patient. This is a phase I and II clinical trial for treatment of patient with confirmed diagnosis of T1DM for at least 12 months prior to enrolment in this trial. This study aims to determine the combined effects of autologous stem cell transplantation and immunomodulation, on regeneration of lost β-cells and halting the immune attack on the pancreatic β-cells, respectively.

To evaluate the accuracy of the Flash Glucose Monitoring system (FGM), Abbot FreeStyle Libre, used today in clinical practice in Sweden in estimating plasma glucose levels. Data will be collected in ambulatory patients with type 1 diabetes to determine safety, accuracy, and reliability.

The purpose of this pilot study is to evaluate the initial efficacy of a reinforcement intervention to enhance physical activity levels in sedentary adolescents and young adults with type 1 diabetes (T1D). The intervention will reinforce patients for meeting physical activity goals, with escalating reinforcers provided when patients achieve continuous weeks of meeting goals. A 12-week trial will be conducted in which 60 patients will be randomized to: (1) standard care or (2) standard care plus reinforcement.

Adolescents with type 1 diabetes (T1D) are at increased risk for problems with adherence and suboptimal glycemic control, and novel approaches are needed to improve outcomes in this high-risk population. The majority of adolescents obtain insufficient sleep (defined as <8 hours/night), and sleep disturbance has been significantly associated with poorer adherence and predicted greater problems with quality of life and worse glycemic control. Yet, no interventions have addressed sleep in youth with T1D. Working from a biopsychosocial and contextual model of sleep, the investigators propose to tailor a sleep-promoting intervention to meet the needs of adolescents with T1D by conducting interviews with to identify the barriers and facilitators to adequate sleep specific to this population. The sleep-promoting intervention will be developed and tested, building on successful sleep interventions in other populations, including components such as limiting caffeine, establishing a media curfew, and positive bedtime routines, while addressing the needs unique to adolescents with T1D, such as fear of hypoglycemia. The study will be conducted by a multidisciplinary team, consisting of Sarah Jaser, PhD, a pediatric psychologist, and two co-investigators, Beth Malow, MD, MS, a neurologist with specialty in sleep medicine, and Jill Simmons, MD, a pediatric endocrinologist. Sleep is a potentially modifiable risk factor that may have both a physiological and behavioral impact on diabetes outcomes. Given the strong associations between sleep and diabetes outcomes in the preliminary data, and recent evidence from sleep restriction studies indicating the impact of insufficient sleep on insulin sensitivity, behavior, and mood, there is reason to believe that a sleep-promoting intervention has the potential to improve outcomes in adolescents with T1D indirectly by improving adherence and directly through its effect on metabolic function. Therefore, the proposed study offers a novel approach to improve adherence, quality of life, and glycemic control in adolescents with T1D.

The purpose of this study is to assess the safety of Tregs + IL-2 and survival of Tregs in patients with recent onset T1DM who receive infusions of autologous Tregs + IL-2.

Type 1diabetes (T1D) is caused by autoimmune destruction of the pancreatic islet ß-cells, leading to an absolute deficiency in insulin. In health, regulatory T cells (Tregs) suppress immune responses against normal tissues, and likewise prevent autoimmune diseases. Tregs are insufficient in T1D. The investigators previously showed that administration of low doses of IL-2 induces selective expansion and activation of Tregs in mice and humans. The investigators hypothesize that Tregs expansion and activation with low doses of IL2 could block the ongoing autoimmune destruction of insulin producing cells in patients with recently diagnosed T1D.

The purpose of this study is to determine if a small dose of glucagon (mini-dose glucagon) is effective for the treatment of non-severe hypoglycemia in adults with type 1 diabetes (T1D).

The diabetes technology group at Imperial College have developed a bio-inspired artificial pancreas (BiAP) system which uses a control algorithm based on a mathematical model of beta-cell physiology. The algorithm is implemented on a miniature silicon microchip within a portable handheld device, which interfaces the components of the artificial pancreas. Development of closed-loop insulin delivery devices to intensify control without hypoglycaemia has been extensively reviewed and have shown encouraging results . However, they have not yet proven to be robust when challenged with uncertainty and the external challenges (such as mixed meal contents, physical exercise, physiological stress and intercurrent illness) that people with Type 1 Diabetes Mellitus (T1DM) may be exposed to outside the clinical environment. The principal research objective is to assess the safety and efficacy of a closed-loop system for T1DM compared to standard insulin pump therapy (open-loop). The primary outcome from the studies will be % time spent with a glucose concentration in the target range (3.9-10.0mmol/l). This outcome incorporates safety as it ensures subjects do not have low or high glucose excursions and is the principal measure of efficacy for closed-loop insulin delivery systems in the scientific literature. Other measured outcomes will be % time spent in euglycaemia (3.9-7.8mmol/l), % time spent in hypoglycaemia (<3.9mmol/l), % time spent in hyperglycaemia (>10mmol/l), mean venous blood and sensor glucose, glycaemic variability as measured by standard metrics (Standard Deviation, Continuous Overlapping Net Glycaemic Action, Lability Index, J-Index, Glycaemic Risk Assessment Diabetes Equation, Mean Of Daily Differences, Mean Amplitude of Glucose Excursion, Average Daily Risk Range, M-VALUE, Mean Average Glucose), glycaemic risk as measured by Low Blood Glucose Index (LBGI) and High Blood Glucose Index (HBGI), closed-loop error grid analysis, glucose area under the curve. All measures have been previously published and validated. This clinical trial protocol assesses the artificial pancreas system in three separate sub-studies: In a bi-hormonal (insulin and glucagon) configuration During and after exercise with bi-hormonal closed loop, and standard insulin opened loop During and after meals of mixed composition with bi-hormonal closed loop, and standard insulin opened loop

The main objective of this study is to determine whether day and night closed-loop insulin delivery for 4 weeks under free living conditions is superior to usual insulin pump therapy in adults with type 1 diabetes and HbA1C<7.5%. This is an open-label, multi center, randomized, crossover design study, involving a 2-4 week run-in period, followed by two 4 weeks study periods during which glucose levels will be controlled either by an automated day- and night closed-loop system or by subjects usual insulin pump therapy in random order. A total of up to 34 adults (aiming for 24 completed subjects) aged 18 years and older with T1D on insulin pump therapy and HbA1C<7.5% will be recruited through diabetes clinics and other established methods in participating centers. 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 time spent with glucose levels above and below target, as recorded by CGM, and other CGM-based metrics.