View clinical trials related to Type1diabetes.
Filter by:Over 1.25 million Americans have Type 1 Diabetes (T1D), increasing risk for early death from cardiovascular disease (CVD). Despite advances in glycemic and blood pressure control, a child diagnosed with T1D is expected to live up to 17 years less than non-diabetic peers. The strongest risk factor for CVD and mortality in T1D is diabetic kidney disease (DKD). Current treatments, such as control of hyperglycemia and hypertension, are beneficial, but only partially protect against DKD. This limited progress may relate to a narrow focus on clinical manifestations of disease, rather than on the initial metabolic derangements underlying the initiation of DKD. 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. T1D is impacted by several mechanisms which increase renal adenosine triphosphate (ATP) consumption and decrease ATP generation. Caffeine, a methylxanthine, is known to alter kidney function by several mechanisms including natriuresis, hemodynamics and renin-angiotensin-aldosterone system. In contrast, to other natriuretic agents, caffeine is thought to fully inhibit the local tubuloglomerular feedback (TGF) response to increased distal sodium delivery. This observation has broad-ranging implications as caffeine can reduce renal oxygen (O2) consumption without impairing effective renal plasma flow (ERPF) and glomerular filtration rate (GFR). There are also data suggesting that chemicals in coffee besides caffeine may provide important cardio-renal protection. Yet, there are no data examining the impact of coffee-induced natriuresis on intrarenal hemodynamic function and renal energetics in youth-onset T1D. Our overarching hypothesis in the proposed pilot and feasibility trial is that coffee drinking improves renal oxygenation by reducing renal O2 consumption without impairing GFR and ERPF. To address these hypotheses, we will measure GFR, ERPF, renal perfusion and oxygenation in response to 7 days of cold brew coffee (one Starbucks® Cold brew 325ml bottle daily [205mg caffeine]) in an open-label pilot and feasibility trial in 10 adolescents with T1D already enrolled in the CASPER Study (PI: Bjornstad).
Despite advancements in care, most adolescents with T1D have higher BMI and significantly higher HbA1c than recommended and are markedly IR, placing them at increased risk for CVD1,2. Thus, alternative approaches to improve and maintain glycemic control, IR, and BMI for adolescents with T1D are urgently needed. This proposal moves beyond the current insulin and carbohydrate counting-focused lifestyle change paradigm to focus on sleep and circadian misalignment, which will allow for identification of new mechanisms that can be directly translated into future intervention and prevention trials. The goal of the current study is to utilize multiple objective measures of sleep duration, timing (actigraphy), and circadian rhythm (melatonin) in adolescents with type 1 diabetes (T1D; N = 40) and examine relationships with glycemic control, IR, vascular health, and BMI. Further, qualitative methodology will be used to identify barriers and facilitators to healthy sleep in adolescents with T1D.
Adolescents with type 1 diabetes face particular challenges related to having a chronic illness that requires daily intensive self-management and medical follow-up during a period when their social, developmental, educational, and family situations are in flux. When transitioning from pediatric to adult care, over a third of youth have a care gap of >6 months. During this vulnerable period youth are at risk for acute life-threatening complications such as diabetic ketoacidosis, and for poor glycemic control, which confers an increased risk of chronic diabetes complications. Gaps in care may be a result of deficiencies in transition processes causing some young people to be poorly prepared for adult care and dissatisfied with the transition process. Ineffective transition can lead to decreased frequency of diabetes visits and an increased risk of adverse events in young adulthood. Further, risk factors such as psychiatric comorbidity and behavioural problems in adolescents with type 1 diabetes are associated with poor outcomes in early adulthood. Quality improvement initiatives can be designed to optimize care processes such as referral systems to adult diabetes providers. Our overall objective is to optimize care and outcomes for youth with diabetes as they transition to adult care. Specific Aim 1: To improve glycemic control in youth around the time of transition from pediatric to adult diabetes care Specific Aim 2: To evaluate the fidelity and quality of a quality improvement intervention designed to improve transition care processes and to identify contextual factors associated with variation in outcomes.
The study investigates whether additional metformin medication in combination with regular insulin treatment will decrease the need of insulin for women with diabetes mellitus type 1 during pregnancy.
The scientific basis for dietary recommendations in type 1 diabetes is almost lacking, with the current recommendations being based on type 2 diabetes studies. Therefore the overall purpose of this study is to improve the current evidence for dietary recommendations to people with type 1 diabetes. Study aim: To compare how a strictly low carbohydrate diet, a moderately low carbohydrate diet and a traditional diabetes diet (with higher amounts of carbohydrates) affect insulin requirements and metabolic control in individuals with type 1 diabetes. Carbohydrate intake is 50-60% of the total energy intake in the traditional diabetes diet, 30-40% in the moderately low carbohydrate diet and 15-20% in the strictly low carbohydrate diet with a minimum of 50 g carbohydrates/day. A diet with less than 50 g carbohydrates/day is usually called very low carbohydrate diet or ketogenic and will not be tested in this study. Those who wish to participate and meet the inclusion criteria (and none of the exclusion criteria) will be randomized to one of the three diets. The duration of the intervention is 6 months after which the participants will be able to choose their own diet for another 6 months. The main study visits are at baseline (screening and study start), 3, 6, 9, and 12 months. Shorter visits will be at 3 and 6 weeks. The participants will meet with a study nurse, dietitian and doctor. They will attend two carbohydrate counting courses before the start of the intervention in order to be able to match their insulin to the amount carbohydrates they eat. Participants will receive written materials about their diets with menus and recipes for better adherence to the diet. The primary endpoint is the change in insulin requirements within and between groups (for secondary endpoints please see relevant section). For assessing the different endpoints the participants will provide blood, urine and feces samples for lab analyses as well as register their insulin use, blood glucose, diet, physical activity and any blood ketones or hypoglycemia electronically or in written forms. Continuous/flash glucose monitoring (CGM/FGM) will be also used. Dietary assessment and adherence will be based on 3-4 day food diaries before every scheduled study visit.
Type 1 diabetes is associated with a significant increase in mortality, cardiovascular disease, injuries on eyes and kidneys. These risks are largely dependent on glycemic control. Multiple strategies of achieving good glycemic control exist. Despite this, only about 20 % of patients in Sweden reach the target HbA1c of ≤ 52 mmol/mol. It is well-known that when the motivation is high, a large proportion of patients reach good glycaemic control with current treatments, e.g. most pregnant women reach a much better glycaemic control. The patient is then motivated to a greater extent in managing the disease, e.g. by carefully dosing insulin and more closely monitoring blood glucose levels. Moreover, besides lack of motivation, specific psychiatric conditions are well-known barriers in being compliant with treatments such as depression, eating disorders and attention deficit disorders (ADHD). Further, identified specific diabetes-related psychosocial factors include severe fear of hypoglycaemia, diabetes-burnout, unrealistic treatment goals, poor relationship with physician, feelings of powerlessness and treatment skepticism. These parameters can be measured via a diabetes distress scale where a high score is correlated to higher HbA1c. The majority of outpatient diabetes clinics in Sweden today request the resource of a diabetes-educated psychologist. However, more evidence is needed from randomized multicentre trials whether such a resource would help to improve HbA1c, reduce diabetes-related distress and improve quality of life. The primary aim of the current study is to evaluate whether the assistance of a diabetes-educated psychologist in the diabetes care of patients with type 1 diabetes improves HbA1c. Secondary endpoints include studying its influence on diabetes-related distress and quality of life. The study is a 1 year randomized trial where the intervention group will meet with a diabetes-educated psychologist in addition to conventional care.
Diabetes technology is changing and has quickly become an integral part of diabetes care and management. The study team plans to study the effects of introducing technology to newly diagnosed type 1 diabetes patients. The investigators hypothesize that early access to continuous glucose monitoring (CGM) technology will potentially improve satisfaction scores, hemoglobin A1c, glycemic control, reduce hypoglycemia, and ease the burden of disease when compared to new onset patients who receive standard of care access to CGM.
It is thought that altered brain lactate handling is involved in the development of impaired awareness of hypoglycemia (IAH), i.e. the inability to timely detect hypoglycemia in people with type 1 diabetes (T1DM). Infusion of lactate diminishes symptomatic and hormonal responses to hypoglycemia in patients with normal awareness of hypoglycemia (NAH), resembling the situation of patients with IAH. It is unknown whether this attenuating effect is due to brain lactate oxidation or the result of lactate-induced alterations of global and regional cerebral blood flow (CBF). Normally, hypoglycemia causes a redistribution of CBF towards the thalamus, from where the sympathetic response to hypoglycemia is coordinated, but in IAH this effect is absent and global CBF is increased. We hypothesize that lactate infusion in patients with NAH will result in blunting of thalamic activation and/or enhanced global CBF. If so, these results may help delineating the pathogenesis of IAH which eventually creates new avenues to protect against the morbidity associated with hypoglycemia and IAH. Study design: Single-blind placebo controlled, randomized cross-over intervention study Study population: T1DM patients with NAH (n=10) Intervention: On two separate occasions, patients with T1DM and NAH will undergo a hyperinsulinemic euglycemic-hypoglycemic glucose clamp with or without the infusion of exogenous lactate. ASL-MRI will be applied to measure global and regional changes in CBF. Main study parameters/endpoints: The change in regional thalamic CBF in response to intravenous lactate infusion compared to placebo, during hypoglycemia
The "Open Artificial Pancreas System (OpenAPS)" was designed to quickly spread technology and knowledge about the construction of artificial pancreas systems to patients with diabetes without awaiting clinical regulatory approval. OpenAPS is based on a privately shared software programs and available insulin pumps and glucose sensors. OpenAPS includes a "decision making" algorithm, which issues adaptions of basal rates to insulin pumps, which represents all fundamental aspects of closed loop artificial pancreas systems. The present study aims to compare the accuracy and performance of a self-constructed OpenAPS system with the approved hybrid closed loop system Medtronic Minimed 670G. While wearing the Medtronic Minimed 670G in automode, study participants will wear an OpenAPS system in parallel, which does calculate basal rate adaptions based on continuous glucose monitoring data and its respective algorithm. The investigators aim to recruit 15 participants in an open label, single-center, single-arm, observational study. Insulin injection will only be provided by the Medtronic 670G HCL system (Basal rate insulin). The OpenAPS system will be worn contemporaneously, calculate recommended basal rate insulin adjustments but will not inject insulin. The maximum treatment period will be 2 weeks per patient.
The objective is to develop a novel system to predict and prevent nocturnal hypoglycemia in type 1 diabetic (T1D) patients, focused in patients with multiple daily injections (MDI) therapy. The general idea is to make use of previous-day information in the moment when patients go to sleep, and then predict if in the next following hours any hypoglycemic event will occur. If the system will have predicted any hypoglycemic event in that moment, it is expected that it will be able to warn the patient to take some action: such as reduce basal insulin dose or to consume a snack before sleep. 10 patients with T1D for more than five years will be included. It is a longitudinal, prospective, interventional study in which every patient will use intermittently scanned Continuous Glucose Monitoring (isCGM) and a physical activity tracker during 12 weeks. Moreover, during this period, patients will store in a mobile application (Freestyle LibreLink) or in a reader information regarding their diabetes management activities, such as insulin delivery doses and meal consumption.