View clinical trials related to Type 1 Diabetes.
Filter by:The purpose of this study is to see whether low blood sugar at night can be reduced by using a system that turns off the insulin pump automatically. The study system includes a continuous glucose monitor (CGM) and an insulin pump. The CGM and pump work with a regular laptop computer. A The system works by (1) measuring the glucose levels under the skin with the CGM, (2) using a computer program on the laptop to predict whether a low blood sugar is likely to occur, and (3) turning off the insulin pump when the computer program predicts that a low blood sugar will occur. We have tested the system in the home environment in individuals with type 1 diabetes age 15 years and older. We have found an indication that the system can decrease the frequency of hypoglycemia. We have not had any serious cases of high blood sugars or other problems. We are now ready to further test the system in the home environment in a younger age group to learn more about its ability to reduce overnight low blood sugar risk. This study has several phases and will take about 3 months for a patient to complete. - First, the patient will use the CGM and pump at home for up to 15 days with the help of a parent/guardian. This is done to determine if the patient meets our study criteria to proceed with the next phase of the study. - If the patient is eligible to continue in the study, the patient will need to use the full study system for at least 5 nights at home with the help of a parent/guardian. This is done to make sure the patient and parent/guardian are able to use the system correctly. The patient may participate in starting and stopping the system at home, but the parent/guardian is responsible for making sure it is used as instructed. - After that, the patient will be asked to use the study system each night for an additional 6 to 8 weeks. The parent/guardian will remain responsible for making sure the system is used as instructed. The study will include about 90 individuals with type 1 diabetes at 3 clinical centers in the United States and Canada. First a study of children 8 to less than 15 years old will be done. Then, a study of children 3 to less than 8 years old will be conducted.
A tonic active epithelial Na+ channel (ENaC) in pre-eclampsia (PE) escaped normal hormonal control may offer an attractive explanatory model for the pathophysiology of established PE. The channel is activated by plasmin. Microalbuminuria predicts the development of pre-eclampsia in pregnant patients with pregestational diabetes type 1. The investigators hypothesize that urine-plasmin excreted in the kidneys, when proteinuria occurs, could be the cause. The investigators want to test the correlation between measurable plasmin/plasminogen in the urine early in pregnancy and the development of preeclampsia in pregnant patients with type 1 diabetes.
Insulin resistance (IR) is an important contributor to increased cardiovascular disease risk in type 1 diabetes (T1D). Non-esterified fatty acid elevation is a significant contributor to IR in T1D and may be a target of intervention. The hypothesis of the study is that isolated fatty acid lowering with acipimox will improve insulin action and blood vessel function and have the benefit of reducing mitochondrial oxidant generation and improving mitochondrial function in T1D. Targeting IR through fatty acid lowering is a novel approach to T1D treatment that may significantly improve current management of TID and of cardiovascular disease (CVD) risk in this high risk population.
Insulin resistance (IR) is an important contributor to increased cardiovascular disease risk in type 1 diabetes (T1D). The purpose of this study is to measure the effect of metformin on insulin sensitivity, vascular function and compliance, and mitochondrial function in T1D. The long term goal is to identify novel non-glycemic approaches to managing cardiovascular disease risk in T1D. The results of this study may validate a novel approach to T1D treatment that could significantly improve current management of cardiovascular disease risk in this high risk population.
A Double-blind Study of the Pharmacokinetic Properties of BIOD-238 and BIOD-250 Compared to Humalog® in Subjects with Type 1 Diabetes
Diabetes is increasingly common among youth, forecasting early complications. Type 1 (T1D) cause early heart disease, shortening lifespan despite modern improvements in control of blood sugars and other risk factors for heart disease. Poor insulin action, otherwise known as insulin resistance (IR), is the main factor causing heart disease in type 2 diabetes (T2D), but the cause of increased heart disease in T1D is unclear. IR may contribute to heart disease in T1D as in T2D, as the investigators and others have found the presence of IR in T1D. Much less is known about IR in T1D, but a better understanding of its role in T1D is critical to understanding causes of heart disease in T1D. The investigators long-term goal is to understand the early causes of heart disease in diabetes so that we can prevent it. The investigators unique initial findings suggest that even reasonably well-controlled, normal weight, T1D youth are IR. The IR appears directly related to the heart, blood vessel, and exercise defects, but in a pattern that appears very different from T2D. The goals of this study are to determine the unique heart, blood vessel and insulin sensitivity abnormalities in T1D youth, and determine whether metformin improves these abnormalities. A clear understanding of these factors will help determine the causes, and what treatments could help each abnormality. Hypothesis 1: Metformin will improve insulin function and mitochondrial function in T1D. Hypothesis 2: Metformin will improve vascular and cardiac function in T1D. All measures will be performed twice, before and after a 3-month randomized, placebo-controlled design where subjects are randomized to either metformin or placebo. The independent impact of insulin action as well as glucose levels, BMI, T1D duration, and gender on baseline outcomes and the impact of changes in insulin action, glucose levels and BMI on response to metformin will also be examined to help customize future strategies to prevent heart disease in T1D. This study will advance the field by providing new information about the role of poor insulin action in the heart disease of T1D, and whether improving insulin action in T1D is helpful. If a focus on directly improving insulin action in T1D youth is supported by our studies, the clinical approach to T1D management may significantly change.
The aim of this pilot study is to determine the impact of caffeine-enhanced energy drinks on blood glucose excursion on heart rate, blood pressure, cardiac output and cognitive performance in patients with type 1 diabetes. Knowledge acquired may inform a wider study of the impact of these drinks. This is a randomised, cross over blinded study in which all participants will participate in the 3 arms of the study. The study will consist of 3 phases, each lasting 3 days. A different study drink will be administered during each phase. There will be an initial screening visit and a pre- study visit before each study phase. Each participant will make 10 visits to the research centre. There will be a week wash out period between each study phase. Prior to each study phase, there will be a 3 day caffeine and alcohol abstinence run-in period. Study drinks will be matched for taste and volume (as far as possible) and will be administered by the use of opaque cups, lids and straws to enable double-blind randomisation for both researcher and participants. Administration of the study drink to participants will be based on Latin squares to provide a balanced treatment order. During the 3 days study period; participants will be required to abstain from all other caffeine containing beverages or confectioneries. The secondary aim is to determine if tolerance to cardiovascular effects of caffeine-enhanced energy drinks is developed following acute short term ingestion.
To cover meal-related insulin requirements, insulin pumps allow insulin to be delivered at high rates over a short period of time (bolus delivery). The length of this period (bolus duration) usually depends on the chosen bolus size and on the used insulin pump model. This study will evaluate the impact of different bolus durations (i.e., durations commonly employed in commercially available insulin pumps: 2 and 40 seconds for delivering 1 Unit of insulin) on the pharmacokinetic and pharmacodynamic properties of an rapid-acting insulin analogue. Objective: To evaluate in type 1 diabetic patients the pharmacodynamics and pharmacokinetics of rapid-acting insulin (insulin lispro) administered as subcutaneous boluses with different bolus durations. Study design: Single-center, randomized, controlled, two-arm cross-over intervention study Population: Twenty type 1 diabetic subjects Intervention: The investigational treatment is the subcutaneous administration of insulin lispro either as one bolus of 15 IU over a period of 30s or as one bolus of 15 IU over a period of 10 min. Plasma samples to assess pharmacodynamic and pharmacokinetic properties will be taken during an 8-hour clamp experiment. Patients will undergo both investigational treatments in a randomized order; between the two clamp visits there will be a wash-out period of 5-21 days. Main study endpoint: Time to maximum glucose infusion rate
To our knowledge, no trial has specifically studied the effect of liraglutide combined with a basal/bolus insulin regimen in type 1 diabetes in a cross-over, double-blind, unicentric model. Moreover, the potential impact of a glucagon-like peptide-1 agonist on measures of abdominal fat (assessed by CT scan), insulin sensitivity (assessed by the gold standard euglycemic-hyperinsulinemic clamp) and satiety sensations have not been evaluated in this population. Hypothesis Overweight participants with type 1 diabetes on liraglutide/insulin treatment will present improved glucose control with decreased HbA1c, decreased fasting and mean weekly glucose concentrations and glycemic excursions as well as increased insulin sensitivity compared to participants on placebo/insulin treatment. Participants with liraglutide/insulin treatment will also present improved endothelial function, lower body weight, central adipose tissue assessed by CT scan and higher satiety sensations assessed by visual analogue scales.
This research study designed to look at how well adolescents' and young adults' blood sugars can be controlled with a "closed loop artificial pancreas" using a continuous glucose sensor, an insulin pump, and a computer program that automatically determines how much insulin to give based on the glucose level. The investigators will also study the effect of wearing a small heating patch, the InsuPatch, at the site of insulin infusion, on the ability of the closed loop system to control the blood sugar levels and to reduce the rise in glucose levels after meals.