Active clinical trials for "Diabetic Ketoacidosis"

The study will systematically evaluate how an emergency manual-a collection of checklists and fact sheets-affects the performance of resuscitation teams during the management of priority one patients in an emergency department.

Objectives: Intravenous (IV) fluid administration is a fundamental component of diabetic ketoacidosis (DKA) treatment. Normal saline (NS), the most common IV fluid used in DKA management, contains more chloride than human blood. Excessive amounts of chloride have been shown to cause a detrimental metabolic acidosis. Other IV fluids have more physiologic chloride levels, such as lactated ringers (LR). This study will compare the rates of hyperchloremic metabolic acidosis in children treated with NS to those treated with LR to determine the effect on overall length of acidosis and length of stay in the hospital or intensive care unit. Design: Single-center, double blinded, randomized controlled trial. Subjects: Children aged 0 to 18 years who present with diabetic ketoacidosis and require pediatric intensive care unit admission. Patients with evidence of shock, multi-organ failure or clinically significant cerebral edema will be excluded. The projected study population will be 104 patients, 52 in each arm. Interventions: Patients will be enrolled within 1 hour of presentation to the emergency room or pediatric intensive care unit if transferred directly from another facility. They will be randomized to receive intravenous fluids containing 0.9% saline or lactated ringers. All patients will be treated using the institutional DKA protocol with the content of the intravenous fluids being the only difference in treatment between arms. Study intervention lasts until the end of the acute management of DKA. Planned measurements and study outcomes: The primary study outcome will be duration of metabolic acidosis. Resolution of metabolic acidosis will be defined in three ways: 1. Normalization of the ketosis; 2. Normalization of the serum pH; 3. Normalization of the serum bicarbonate level. Secondary outcomes will include length of stay in the pediatric intensive care unit and length of stay in the hospital. All outcomes will be correlated with the overall chloride load given via intravenous fluids during DKA management. Regression modelling will control for any baseline differences between the groups in regards to severity of DKA, and if newly diagnosed or poorly controlled diabetes mellitus.

The purpose of this research study is to investigate the use of continuous glucose monitoring (CGM) device DEXCOM G6 in non-critically patients treated for diabetic emergency such as diabetic ketoacidosis (DKA). Patients who have DKA require hourly monitoring of glucose (sugar) level which traditionally requires admission to the intensive care unit (ICU) for hourly fingerstick monitoring. With the use of CGM device, in this research study hourly fingerstick monitoring is replaced by continuous glucose monitor (CGM) which provides glucose levels continuously in real time for nurses and provider. The investigators are testing to see if in the future patients can be treated in the stepdown unit (an intermediate care level between the intensive care unit and the general medical unit) if they do not require higher level of care besides hourly glucose monitoring. Continuous glucose monitoring (CGM) device DEXCOM G6 currently FDA Approved for patients with diabetes and is widely used for glucose monitoring in patients with diabetes in the outpatient setting. The investigators want to study the use of the DEXCOM G6 CGM in the inpatient setting to monitoring glucose levels remotely in the treatment of diabetic emergencies such as diabetic ketoacidosis and compare their care to those receiving hourly fingerstick glucose monitoring in the ICU.

The management goals of diabetic ketoacidosis (DKA) in the pediatric type 1 diabetes (T1DM) population are fluid and electrolyte repletion, insulin administration, and correction of acidosis in order to stabilize the patient. Traditionally, a rapid-acting insulin IV infusion is begun immediately and continued until the acidosis is corrected and hyperglycemia normalized. Once the acidosis is corrected, patients are able to be transitioned to a subcutaneous insulin regimen. The role that a subcutaneous long-acting insulin such as glargine has in the acute treatment of DKA has not been extensively studied. While giving glargine during the treatment of DKA is becoming more common place, few studies have examined the potential risks and benefits of its use. This study will investigate the effects of early administration of glargine during DKA in patients with newly diagnosed TIDM. The design of this study is a prospective, double-blind study of children ages 2-21 who are admitted to the hospital in DKA with a diagnosis of T1DM. The control group will receive all traditional methods of treatment for DKA, including a placebo subcutaneous injection. The study group will receive the same treatment, but will be supplemented with a subcutaneous glargine injection.

Given the longer half life of insulin degludec compared to glargine /levemir ,investigators believe that insulin degludec will reduce the rate of recurrent DKA. The investigator will randomize participants to control and intervention group. Control group will receive Lantus/Levemir and intervention group will receive degludec. The investigators will call participants monthly and see them in the clinic every three months.The investigators will follow them for 1 year and evaluate if there will be a difference in rate of DKA in between these two groups.

Early Basal Insulin Administration in Adult Diabetic Ketoacidosis Management

Type 1 Diabetes is characterized by an absolute lack of insulin caused by autoimmune ß-cell destruction. Looking for different therapeutic approaches, beyond the administration of Insulin SGLT-Inhibitors (SGLT=sodium-glucose cotransporter) like Dapagliflozin look like a promising option to avoid hyperglycaemic excursions which are a reason for glycaemic variability by renal excretion of excessive glucose without administration of extra insulin. But also euglycemic DKA has been reported during SGLT2 add-on therapy to insulin in T1D and mechanistic studies have been called for. The role of Dapagliflozin-induced hyperglucagonemia and stress/infection precipitating euglycemic DKA in this situation is unclear. Thus the purpose of this pilot study is to collect clinical data on the development of DKA after insulin-withdrawal with Dapagliflozin compared to placebo and the added effect of a single dose of 4mg/kg i.v. ACTH as mediator of stress. The first objective is to investigate the time to DKA (defined as Bicarbonate <19 mmol/l) after insulin withdrawal during treatment with a stable 5 day single daily dose of 10mg Dapagliflozin in patients with type 1 Diabetes. In addition it should be evaluate the additional effect of stress, modelled by a single injection of ACTH on DKA development during Dapagliflozin Treatment. We also want to know if Dapagliflozin influences glucagon levels during insulin withdrawal and how this is associated with the time course of DKA development.

The study is a multicenter, randomized controlled trial to compare the safety and efficacy of insulin analogs and human insulins both during acute intravenous treatment and during the transition to subcutaneous insulin in patients with diabetic ketoacidosis (DKA).

The purpose of this trial is to compare two different rates of fluid administration during diabetic ketoacidosis (DKA) treatment in children to determine which fluid administration rate is more beneficial for brain metabolism and for preventing or decreasing brain swelling during DKA.

The investigators will conduct a randomized controlled trial comparing four different intravenous (IV) fluid treatment protocols for pediatric diabetic ketoacidosis (DKA). Two rates of rehydration will be compared; a more rapid rate and a slower rate. Within each of these two basic rehydration protocols, the investigators will vary the type of rehydration fluid used (0.9% saline or 0.45% saline). The investigators will compare the different treatments by conducting assessments of neurological injury, by measuring the frequency of significant cerebral edema, and by measuring long-term neurocognitive function. These studies will allow us to determine whether variations in IV fluid treatment protocols affect acute neurological outcomes of DKA. Additionally, they will provide important data regarding the impact of DKA and DKA treatment on long-term neurocognitive function in children. In this way, the investigators hope to identify a more ideal fluid management strategy for children with DKA. Previous studies have suggested that DKA may cause blood flow to the brain to be reduced and that brain injury might result from this reduction in blood flow and/or the effects of re-establishment of normal blood flow during DKA treatment with insulin and iv fluids. The investigators hypothesize that more rapidly re-establishing normal blood flow to the brain during DKA, by giving fluids more rapidly and using fluids with a higher sodium (salt) content, will help to minimize brain injury caused by DKA.