Active clinical trials for "Hypoglycemia"

This research study is designed to investigate the effect of hypoglycemia (low blood sugar) on blood flow to and biochemistry in the brain.

Patients with insulin-dependent diabetes mellitus (DM) and chronic kidney disease (CKD) exhibit an excessive risk for cardiac arrhythmias, in particular sudden cardiac death (SCD). Various studies have shown that hypoglycemic episodes are strong predictors of cardiovascular mortality in both type 1 and type 2 diabetic patients. Experimental data and small clinical studies link hypoglycemia with ECG changes and SCD, but little is known about the direct association of hypoglycemic events and/or rapid swings in blood glucose with arrhythmias in this high risk population. Ideally, an algorithm should help to identify patients at risk for hypoglycemia-associated arrhythmias and SCD, but hitherto systematic analyses of blood glucose values and 12-channel ECGs are lacking in these patients. In this validation study a 12-lead ECG T-shirt consisting of textile electrodes and a data logging device wich can record long-term 12-lead ECG data will be tested. The purpose of the T-shirt is to improve the patient's comfort for long-term recordings and to prevent adverse effects of regular ECG electrodes. Current systems are limited by the use of ECG electrodes involving disadvantages like severe direct side effects on the skin such as rash and bullous lesions as well as slipping electrodes. By the means of the proposed ECG T-shirt those drawbacks will be avoided.

This will be a quasi-experimental study comparing blood glucose values 30 minutes after feeding alone or feeding + 40% dextrose gel in newborns at risk for transient neonatal hypoglycemia.

This study is a clinical, randomized, crossover study. The study investigates the effect of a low-carbohydrate-high-protein pre-exercise meal on preventing exercise-induced hypoglycemia in people with type 1 diabetes. The hypothesis is that intake of a low-carbohydrate-high-protein meal can reduce the duration and depth of hypoglycemia during and after exercise in people with type 1 diabetes compared with an isocaloric high-carbohydrate-low-protein meal with identical fat content. The study will contribute with new knowledge about importance of meal composition on preventing exercise-induced hypoglycemia.

The aim of the study is to prove whether the use of the SmartGuard feature of the MiniMed system significantly reduces hypoglycemic excursions and thus provide proactive protection to the user.

In the unfortunate case of severe hypoglycaemia, glucagon is the first-line treatment because of its potent and rapid action starting as fast as 5 minutes after subcutaneous or intramuscular injection. Large dose of glucagon such as 1 mg subcutaneous is usually associated with undesirable side-effects such as nausea, vomiting, bloating and headache. The overall objective of this research proposal is to assess the efficacy of lower subcutaneous doses of glucagon (0.1 mg or 0.2 mg) to correct hypoglycaemia compared to the standard dose (1.0 mg) in adults with type 1 diabetes mellitus (T1D). It is postulated that much lower dosages of glucagon (0.1 or 0.2 mg) injected subcutaneously will be just as effective as the current recommended dose of 1.0 mg to correct hypoglycaemia without the undesirable gastro-intestinal side effects.

The purpose of the project is to improve in-patient safety by lowering the risk of severe hypoglycemia (low blood sugar) for patients with diabetes on insulin therapy and to improve communication between healthcare providers. The procedures of the study are: the hospital patient information system [Pharmacy Event System,(PES)] will generate for healthcare providers a real-time risk alert of severe hypoglycemia (low blood sugar) the real-time PES risk alert will be sent via a beeper to the patient's charge nurse the charge nurse will follow the specific guidelines in the alert for assessment of the patient's care and insulin regimen the charge nurse will then notify the physician of the patient's assessment and of the recommendation for change/no change in insulin regimen and/or clinical care the alerted charge nurse and physician will complete a collaboration scale

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.

The purpose of this study is to evaluate the accuracy and reliability of the continuous glucose monitoring system the FreeStyle Navigator® (Abbott, Diabetes Care) in critically ill patients by comparing subcutaneous measuring with the current standard of arterial measuring by a point of care glucometer.

The investigators know that intensive insulin therapy and tight glucose control is associated with reduction of diabetic complications. However, many patients on insulin don't achieve this because of the risk and the fear of hypoglycaemia (too low blood glucose). There has been a lot of work done recently looking at the mechanisms by which the brain detects hypoglycaemia. A key player is a potassium channel in the brain (KATP channel). Studies have shown that when these channels are opened, there is a release of hormones such as adrenaline that can help in raising blood sugars to counteract and increase awareness of hypoglycaemia. The investigators study aims to look at an old drug called diazoxide, which is able to open KATP channels. The investigators aim to see if diazoxide will amplify the release of hormones such as adrenaline when the blood sugar is low. If this is the case, this will aid quicker recovery following hypoglycaemia. The investigators aim to do this by performing a well established experimental protocol that has been performed safely over the last 20 years called a clamp study. The clamp study will involve slowly bringing the blood sugars down using insulin and intravenous glucose in a controlled fashion. The main outcome will be the hormonal responses (adrenaline response) at a blood sugar level of 2.5mmol/L. Symptoms of hypoglycaemia will be monitored, as well as working memory tests using standardised questionnaires. The design of the investigators study will be a randomised trial comparing the effects of diazoxide with placebo in which all patients will receive both diazoxide and placebo in random order (crossover design).