Active clinical trials for "Diabetic Ketoacidosis"

This is a randomized, double-blind, placebo-controlled trial to determine if administration of intravenous thiamine will lead to quicker resolution of acidosis in patients admitted to the hospital with diabetic ketoacidosis. The investigators will secondarily investigate whether thiamine improves cellular oxygen consumption, shortens intensive care unit (ICU) and hospital stay or decreases hospital resource utilization.

The safety and efficacy of basal insulin during intravenous insulin infusion for hyperglycemic crisis patients under critical care is still unknown. We assumed that concurrent basal insulin subcutaneous injection and intravenous insulin infusion for critically ill DKA and HHS patients would shorten the time of hyperglycemic crisis correction and achieved better glycemic control(decrease hypoglycemia and rebound hyperglycemia).

Diabetic ketoacidosis (DKA) is a medical emergency that is associated with significant morbidity and mortality for both patients with type I and type II diabetes. By correcting hyperglycemia and inhibiting the release of free fatty acids, insulin administration leads to decreased ketone formation and resolution of acidosis. Short-acting intravenous insulin is often preferred to subcutaneous administration for initial management due to its short half-life and ease of titration, but patients will eventually need to transition to subcutaneous insulin prior to discharge. The timing of initiation or resumption of home long-acting subcutaneous insulin is controversial in the treatment of DKA. It is currently unknown if resuming a portion or all of the patient's home basal regimen during the initial treatment phase of DKA will provide an impact on patient care. The purpose of this study is to evaluate the impact of early glargine administration if the patient was not previously on basal insulin or resuming the patient's home basal insulin regimen within two hours after the start of the intravenous insulin infusion in addition to usual care will improve patient outcomes.

The study aims to compare between the use of continuous low dose insulin infusion versus co-administration of low dose continuous insulin infusion and early subcutaneous insulin glargine in diabetic ketoacidosis patients with chronic renal impairment. aim to investigate the effect of using the long acting insulin analogue glargine on the resolution time of diabetic ketoacidosis in renal impairment patients who have altered insulin pharmacokinetics and pharmacodynamics and the rate of adverse effects of this approach

Severe diabetic ketoacidosis (DKA) is a potentially serious complication of diabetes mellitus. The treatment regimen is based on insulin and rehydration. The choice of rehydration solution is a question that remains open. We sought to compare the effect of sodium chloride 0.9% (SC) versus ringer lactate (RL) in the resolution of severe DKA as well as on the variation of electrolytes.

Diabetic ketoacidosis (DKA), a frequent complication of diabetes, is the consequence of a profound insulin deficiency responsible for osmotic polyuria and thus major losses of water, glucose, sodium and potassium as well as a metabolic acidosis due to the uncontrolled production of ketonic acids. Management includes fluid replacement, insulin therapy and correction of metabolic disorders (including potassium loss). Initially described in patients with type 1 diabetes (T1D), it is now often observed in patients with type 2 diabetes (T2D) in whom it is more a matter of insulin resistance than an absolute deficiency. However, international guidelines recommend a similar dose of intravenous insulin (0.10 IU/kg/hour) regardless of the type of diabetes. During treatment, metabolic complications are frequent and potentially serious, especially in T2D due to cardiovascular comorbidities. The research hypothesis is that decreasing the insulin dose will reduce metabolic complications without influencing time to resolution in adult patients, regardless of diabetes type.

The objectives of SHINE study are to confirm the safety aspects of the SHINE SYSTEM. Moreover, the goal of this clinical investigation is the initial evaluation of sensor's performance by assessing sensor's ability to qualitatively detect the appropriate analytes in subjects with diabetes of 18 years and older.

Diabetic ketoacidosis (DKA) is a common acute complication of type 1 diabetes mellitus (T1DM). DKA is characterized by hyperglycemia, metabolic acidosis, increased levels of ketone bodies in blood and urine. This leads to osmotic diuresis and severe depletion of water and electrolytes from both the intra- and extracellular fluid (ECF) compartments. Estimation of the degree of dehydration for children admitted with DKA is of great clinical importance. The calculation of the amount of deficit therapy depends on the estimated degree of dehydration. However, the degree of dehydration present during DKA is difficult to be clinically assessed. Hyperosmolality tends to preserve intravascular volume with maintenance of peripheral pulses, blood pressure, and urine output until extreme volume depletion occurs. Metabolic acidosis leads to hyperventilation and dry oral mucosa as well as decreased peripheral vascular resistance and cardiac function . consequently, hyper-osmolality may lead to an underestimation of the degree of dehydration, whereas metabolic acidosis may lead to an overestimation of the degree of dehydration. This makes the physical findings unreliable in this setting. Several clinical and biochemical markers were suggested to assess and stage the degree of dehydration at hospital admission. The blood urea nitrogen , hematocrit , plasma albumin are useful markers of the degree of ECF contraction.However, Several previous studies demonstrated that there was no agreement between assessed and measured degree of dehydration which is calculated according to change in body weight at admission and after correction of dehydration. there were tendencies to overestimated or underestimate the degree of dehydration between different physicians. The assessment of the magnitude of dehydration in DKA is of major interest and continues to be a subject of research. This study aims to assess the association between different clinical and laboratory parameters in children with diabetic ketoacidosis and the degree of dehydration at hospital admission among those children.

The goal of this blinded, cluster cross-over, randomised controlled trial is to determine whether fluid therapy with Plasma-Lyte® 148 increases the number of days alive and days out of hospital to day-28 compared to 0.9% sodium chloride ('0.9% saline') in critically ill patients presenting to the Emergency Department (ED) and deemed to require admission to a critical care area (ICU, HDU) with moderate to severe diabetic ketoacidosis (DKA).

Sodium glucose co-transporter 2 (SGLT2) inhibitors have revolutionized care for people living with type 2 diabetes mellitus (T2DM). They reduce a person's risk of heart failure, renal failure, myocardial infarction, stroke, cardiovascular mortality, and potentially all-cause mortality. Remarkably, some of these benefits also extend to people who do not have T2DM. While the benefits of SGLT2 inhibitors are impressive, there is one life-threatening side effect associated with their use: diabetic ketoacidosis (DKA). The ability to predict which patients are at highest risk of DKA is needed to sufficiently mitigate this risk. Moreover, considering the impressive benefits of SGLT2 inhibitors, identifying patients at the lowest risk of SGLT2 inhibitor-associated DKA is also important so that providers do not overestimate risk in those who stand to benefit most. Advances in genomic technologies and related analyses have provided unprecedented opportunities to bring genomics-driven precision medicine initiatives to the forefront of clinical research. Leading these developments has been the progress made by genome-wide association studies (GWAS) due to decreasing genotyping costs, and consequently, the ability to routinely study large numbers of patients. These approaches allow for systematic screening of the genome in an unbiased manner and have accelerated the discovery of genetic variants and novel biological processes that contribute to the development of adverse treatment outcomes. By using innovative approaches, which harness large cohorts of population controls, sample size limitations that are associated with rare adverse drug reactions such as SGLT2 inhibitor-associated DKA can be overcome. The DANGER study represents a highly innovative new direction wherein partnership among basic science researchers and computational biologists will lead to the application of genomic techniques to identify genetic variants that may be associated with SGLT2 inhibitor-associated DKA.