Furosemide in Early Acute Kidney Injury
Acute renal failure, now referred to as acute kidney injury, is common in intensive care unit patients, contributes to high morbidity and mortality, and has no proven interventions with benefit once established. In addition to supportive care, these patients frequently receive diuretic therapy, most commonly furosemide.
Prior trials showed no impact of furosemide on clinical outcomes and perhaps harm, however, these trials suffered from numerous limitations and lack applicability to modern intensive care unit patients. As a result, there appears a disconnect between clinical practice and available evidence. Survey data supports the view of clinical equipoise for use of furosemide in intensive care unit patients with early acute kidney injury. Moreover, these data also confirm there is an urgent need for higher quality and more definitive evidence from randomized trial on furosemide use in early acute kidney injury.
Accordingly, the investigators propose to conduct a pilot phase II randomized, blinded, placebo-controlled trial comparing furosemide to placebo in ICU patients with early acute kidney injury.
The specific aims of this study are:
1. To compare the efficacy and safety of a continuous infusion of furosemide versus placebo titrated to the physiology parameter of urine output in early acute kidney injury on the primary outcome of progression in severity of kidney injury in intensive care unit patients with early AKI and stratified by the presence of sepsis.
2. To evaluate selected secondary endpoints on the impact of furosemide versus placebo, specifically: fluid balance goals; electrolyte and acid-base balance; the need for renal replacement therapy (i.e. dialysis); total duration of acute kidney injury; the rate of renal recovery; and mortality.
3. To compare the impact of furosemide versus placebo on the trajectory of serum and urinary biomarkers (neutrophil gelatinase-associated lipocalin [NGAL], interleukin-18 [IL-18]) and evaluate whether these biomarkers perform superior to conventional measures (creatinine, urea) for monitoring the progression of kidney injury and the prediction of outcome.
This trial represents part of a larger initiative aimed towards expanding our understanding of the treatment of acute kidney injury in intensive care unit patients and evaluating interventions that may potentially reduce kidney injury and improve clinical outcomes.
Study Design, Setting and Patient Population
This is a phase II randomized, blinded, placebo-controlled trial of ICU patients with early AKI with randomization stratified by sepsis. This study will be performed at the University of Alberta Hospital (UAH) General Systems Intensive Care Unit (GSICU). All patients admitted to the GSICU will be screened for eligibility.
1. Acute kidney injury (AKI) - The operational definition for early AKI will be defined and classified according to the RIFLE criteria (and modified AKIN). The presence of early AKI will be defined by the RIFLE class - RISK: an abrupt (within 48hr) reduction in kidney function characterized by an relative increase in serum creatinine of >50% (1.5 fold) or >26.5 mcmol/L from baseline or a reduction in urine output of ≤0.5 mL/kg/hr for >6 hours.
Description of Study Flow
Patients will be identified in the ICU by daily surveillance of admitted patients by the PI and/or research coordinator or when identified by the treating ICU physician. Each patient's eligibility will be verified by use of a one-page checklist that summarizes the inclusion and exclusion criteria. This checklist will be included in the standardized case-report form (CRF).
Following obtainment of consent, patients will be commenced on a continuous infusion of either the intervention (furosemide) or identical placebo (0.9% NaCl). The study protocol for administration of furosemide by continuous infusion is adapted from the phase I study by Ostermann et al. The study infusion bag will contain 2000mg of furosemide in 500mL of 0.9%NaCl for a final concentration of 4mg/mL. The continuous infusion will be titrated to achieve a target urine output in the range of 1.0-2.0 mL/kg/hr. Each patient will be administered a loading dose of 0.4 mg/kg as a separate infusion bag followed by a continuous infusion commenced at a dose of 0.0125 ml/kg/hr. The maximum infusion rate will be 0.125ml/kg/hr. The urine output will be assessed hourly. If the target urine output has been achieved, then the current infusion rate will be continued. If the target urine output has not been achieved, the dose will be increased to the next infusion rate in the algorithm. If the urine output is too brisk (>2mL/kg/hr), the dose will be maintained unless any of the following criteria are fulfilled: decrease in mean arterial pressure <65 AND/OR addition of or an increase in vasoactive requirements of ≥20% to achieve goal mean arterial pressure OR central venous pressure <8 cmH2O OR central venous oxygen saturation <60% OR a cardiac index <2.0L/min/1.73m2 (if measured). If any of these criteria are achieved, the dose will be decreased to the next lower infusion rate in the algorithm. If any of the aforementioned criteria have been fulfilled AND urine output remains >2mL/kg/hr for 2 consecutive hours despite the lowest infusion rate, the treatment will be discontinued for 1 hour then resumed at the lowest infusion rate. The fulfillment of these criteria will be brought to the attention of the consultant ICU physician for review. At any time during the trial, if the responsible ICU physician believes that diuretics are urgently indicated (pulmonary edema), diuretics can be administered and this event will be documented.
All other aspects of patient management within the parameters outlined (methods of fluid resuscitation, choice of fluids, vasoactive therapy, choice of vasoactive therapy, adjuvant therapies such as hrAPC, intensive insulin therapy, will be at the discretion of the consultant ICU physician.
The study drug infusion will be continued until any one of the following events occur:
1. the patient is initiated on RRT;
2. the patient dies;
3. the patient is discharged from the ICU;
4. the patient recovers kidney function; or
5. the patient develops a recognized adverse reaction potentially related to the study infusion.
Methods of Randomization
The randomization sequence will be created at a single central location at the University of Alberta Hospital (EPICORE Centre). The sequence will be stratified by the presence of a diagnosis of sepsis.
Detailed clinical, physiologic, laboratory and outcome data will be collected. Data will be collected each day on whether the primary endpoint (progression of AKI) has occurred, for evidence of any secondary endpoints and criteria for trial discontinuation. Plasma and urine will be collected for biomarkers studies. Any study protocol violations will be recorded. The adjudication of protocol violations will be determined by a study investigator blinded to the treatment allocation.
We plan to follow all patients to determine the duration of AKI, continued need for RRT, renal recovery and mortality until death or discharge from hospital and at 30, 60 and 90-days after randomization.
Allocation: Randomized, Control: Placebo Control, Endpoint Classification: Efficacy Study, Intervention Model: Parallel Assignment, Masking: Double Blind (Subject, Caregiver, Investigator, Outcomes Assessor), Primary Purpose: Treatment
Acute Renal Failure
General Systems Intensive Care Unit, University of Alberta
University of Alberta
Results (where available)
- Source: http://clinicaltrials.gov/show/NCT00978354
- Information obtained from ClinicalTrials.gov on July 15, 2010
Medical and Biotech [MESH] Definitions
A severe irreversible decline in the ability of kidneys to remove wastes, concentrate URINE, and maintain ELECTROLYTE BALANCE; BLOOD PRESSURE; and CALCIUM metabolism. Renal failure, either acute (KIDNEY FAILURE, ACUTE) or chronic (KIDNEY FAILURE, CHRONIC), requires HEMODIALYSIS.
Conditions in which the KIDNEYS perform below the normal level in the ability to remove wastes, concentrate URINE, and maintain ELECTROLYTE BALANCE; BLOOD PRESSURE; and CALCIUM metabolism. Renal insufficiency can be classified by the degree of kidney damage (as measured by the level of PROTEINURIA) and reduction in GLOMERULAR FILTRATION RATE. The most severe form is KIDNEY FAILURE. Renal function may deteriorate slowly (RENAL INSUFFICIENCY, CHRONIC) or precipitously (RENAL INSUFFICIENCY, ACUTE).
Renal Insufficiency, Acute
Conditions in which the function of KIDNEYS deteriorates suddenly in a matter of days or even hours. It is characterized by the sudden drop in GLOMERULAR FILTRATION RATE; (GMR). The most severe stage is when the GFR drops below 15 ml per min (ACUTE KIDNEY FAILURE).
Kidney Failure, Acute
A severe stage of acute renal insufficiency, characterized by the sudden decrease in GLOMERULAR FILTRATION RATE to less than 15 ml per min, sometime to less than 1 to 2 ml per min. It is usually associated with OLIGURIA; EDEMA; and increase in BLOOD UREA NITROGEN and serum CREATININE concentrations.
Kidney Tubular Necrosis, Acute
Acute kidney failure resulting from destruction of EPITHELIAL CELLS of the KIDNEY TUBULES. It is commonly attributed to exposure to toxic agents or renal ISCHEMIA following severe TRAUMA.
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