3 Clinical Trials for Various Conditions
Patients who are on mechanical ventilation in an intensive care unit often require diursis as part of their pre-extubation regimen. The drug of choice for diuresis has traditionally been furosemide. However, this drug cause hypernatremia (a rise in serum sodium) in a significant proportion of patients. Hypernatremia is traditionally treated by providing free water supplementation to the patient. This strategy creates a vicious and unproductive cycle of giving free water, and then diuresing it off. We propose a strategy for breaking this cycle by using a second diuretic-- metolazone-- which has a tendency to rid the body of more sodium, thereby minimizing hypernatremia.
The improved survival rate of extremely low birth weight(ELBW)infants has resulted in new fluid and electrolyte problems that have not been encountered previously,in particular electrolyte imbalance. ELBW infants are especially vulnerable to hypernatremia(serum sodium value \>150 mEq/L). Hypernatremia may be due to rapid dehydration or excessive administration of intravenous fluids(IV)that contain sodium. The current treatment modality for hypernatremia is to increase IV fluids above daily requirements.Enteral sterile water feeds(ESWF)are theorized as an endogenous source of fluids that may decrease elevated electrolytes such as sodium and potassium in premature infants. By giving ESWF to decrease elevated electrolytes, there would be less need for large volumes of IVF that contribute to the co-morbidities of prematurity: bronchopulmonary dysplasia (BPD),intraventricular hemorrhage(IVH)and patent ductus arteriosus(PDA). The purpose of this proposed study is to determine whether enteral sterile water feedings is effective in decreasing the incidence, duration and severity of hypernatremia in ELBW infants.
This primary aim of this study was to critically assess whether or not sweat water content and sodium concentration were acutely regulated by dynamic changes in antidiuretic hormone (arginine vasopressin or AVP) acting on the Vasopressin 2 receptor (V2R) during exercise. Secondary aims were to evaluate running performance and core temperature to further characterize the role of AVP in the coordinated balance of fluid and temperature homeostasis during exercise. The primary hypothesis was that activation of the V2R in sweat glands would result in water reabsorption and fluid conservation during endurance exercise.