View clinical trials related to Acute Kidney Injury.
Filter by:Acute kidney injury(AKI) is a common and severe complication after the cardiac surgery. Postoperative AKI increases the in-hospital stay, intensive care unit(ICU) stay and postoperative mortality. Aortic surgery is the most risky surgery that causes the postoperative AKI, and the incidence of AKI after aortic surgery is about 50%. Statin is a 3-hydroxy-3-methyl-glutaryl co-enzyme A (HMG CoA) reductase inhibitors and is used primarily to lower the level of plasma cholesterol. Apart from the antilipid effect, statin has pleiotropic effects include anti-inflammation, decrease of oxidative stress, recovery of endothelial cell injury and stabilization of thrombus. The pathology of AKI after aortic surgery include not only hypoperfusion of renal blood flow but also thromboembolism, inflammatory reaction after use of cardiopulmonary bypass(CPB) and oxidative stress. Therefore, the incidence of AKI after aortic surgery can be expected to decrease after the perioperative use of statin because of the pleiotropic effects of it. The aim of this study is to examine the association between preoperative statin treatment and the incidence of postoperative acute kidney injury(AKI) in patients undergoing aortic surgery
Hepatorenal syndrome (HRS) is a common cause of acute kidney injury (AKI) in cirrhotic patients and has a one month survival rate of 50% and a 3 month survival rate of 20%. The leading theory behind HRS is selective vasoconstriction of renal vasculature in the setting of decreased systemic vascular resistance. Patients with liver cirrhosis suffer from a large degree of third spacing in the form of peripheral edema and ascites. In addition treatment with multiple drugs, including diuretics puts these patients at higher risks of prerenal AKI and ischemic acute tubular necrosis (ATN). AKI occurring due to HRS, prerenal AKI and ischemic or nephrotoxic ATN have different pathophysiologic mechanisms and are treated differently with significantly different outcomes. While renal perfusion is expected to be reduced in HRS and prerenal AKI, it is normal or increased in ATN. Prerenal AKI has the most favorable prognosis among these pathologies and treatment simply consists of volume expansion with blood, albumin, crystalloids or colloids. In clinical practice vasoactive agents such as midodrine and octreotide are used to increase the tone of splanchnic vessels and to improve renal perfusion. These interventions would not affect renal function in cases with ATN. Unfortunately, the diagnostic criteria proposed by the International Club for Ascites (ICA) for HRS are not specific and do not always exclude patients with other forms of acute kidney injury. Therefore, availability of a simple diagnostic tool for measurement of renal blood flow (RBF) at the bedside would be of great value in management of cases with cirrhosis of the liver presenting with acute reduction in kidney function. However, currently, there are no practical and simple tools available for this purpose. Contrast enhanced ultrasonography (CEU) involves the intravenous injection of gas-filled microbubbles to enhance the ultrasound image of the organs and mainly to assess tissue vascularity and blood flow. We and others have used CEU to assess changes in RBF in response to physiologic stimuli and therapeutic interventions. Here we propose a prospective, pilot diagnostic study to validate the use of CEU, in assessing RBF in cirrhotic patients with AKI, and to assess the utility of CEU to differentiate between causes of AKI in cirrhotic patients. Our hypothesis is that CEU will show arteriolar vasoconstriction and decreased blood flow in the renal cortex in patients with HRS which would not change in response to volume expansion. On the contrary, patients with prerenal AKI will have reduced RBF which will increase after volume expansion. Finally, those with ATN will not have a reduced RBF at baseline. We plan to enroll 25 patients with liver cirrhosis and acute kidney injury who are admitted to the University of Virginia hospital into the study. CEU will be performed on all subjects to measure baseline RBF. CEU will be repeated in all subjects within 24 hours after volume expansion with at least 1gm/kg of albumin (up to 100 gm/day) to assess a potential change. Hourly urine output and serum creatinine will be monitored for potential renal response to the volume expansion as part of clinical care. For the subgroup of subjects who receive treatment with combination therapy with albumin, midodrine, and octreotide (AMO) RBF assessment with CEU will be repeated after at least 48 hours of receiving this combination. Renal response will be assessed by monitoring urine output and serum creatinine monitored as part of clinical care. All subjects will have measurements of fractional excretion of sodium (FENa) and urea (FEUrea) and urine microscopy as a part of their routine clinical care (work up of AKI). The results of these tests and the response to volume expansion will be used to categorize subjects into three categories of AKI (HRS, prerenal AKI, ATN). Correlations between RBF and its changes between different therapeutic interventions and renal diagnosis will be tested in this study.
A recent analysis of over 4500 cardiac surgical patients at the Royal Infirmary of Edinburgh has confirmed that acute kidney injury (AKI) is not only a relatively common post-operative complication but is associated with prolonged hospital stay, and increased risk of death. There is currently no specific therapy available except supportive care. In laboratory studies, heme arginate (HA), a drug licensed for human use, has been shown to upregulate the anti-inflammatory enzyme hemeoxygenase-1 (HO-1) and protect aged mice from acute kidney injury. This study will bring this research into the human arena. It will aim to evaluate the minimum effective dose of HA and verify its safety in this specific group of patients. This will be the next step in investigating if HA could be a potential protective treatment for reducing AKI in patients about to have cardiac surgery. Patients who are due to have cardiac surgery and are aged 60 or above will be approached for inclusion in the study. If agreeable, they will be randomly assigned to receive either HA at a dose of 1mg/kg or 3mg/kg. There will be 10 patients in each group. Blood tests will be taken just before the study drug is given, at 6 hours, 24 hours and 7 days post dose. These samples will be used to examine the effect of HA on HO-1 at different doses, and will verify drug safety. Any adverse effects of the drug will be evaluated, although HA has an excellent safety profile when used as it is currently licensed for acute porphyria. Urine samples will also be collected to assess inflammation and quantify urinary biomarkers of AKI. This will set the scene for a randomised clinical trial of HA in cardiac surgical patients at high risk of AKI.
To compare staged ureteroscopy following initial urinary drainage versus direct ureteroscopy without initial urinary drainage in the treatment of obstructive calcular anuria with acute renal failure in children.
The objectives of the study are the following: - To evaluate the pharmacokinetic profile of Sildenafil in cardiac surgery patients at risk of acute kidney injury - To determine the safety and tolerability of Sildenafil in cardiac surgery patients at risk of acute kidney injury
This will be the first-in-human (FIH) study with CXA-10. The main purpose of this trial is to demonstrate the tolerability, safety and pharmacokinetics (PK) of CXA-10 at various incremental doses, and to demonstrate the safety and tolerability of the rate of the emulsion vehicle infusion in healthy volunteers. In addition, associated pharmacodynamic (PD) effects of CXA-10 will be investigated.
Acute Kidney Injury (AKI) is a common and severe complication in critically ill patients which is associated with increased morbidity and mortality as well as high costs of medical care. NGAL (neutrophil gelatinase-associated lipocalin, lipocalin-2, siderocalin) is a biomarker, that is expressed in several tissues including the kidneys. Renal expression of NGAL is dramatically increased in kidney injury from a variety of causes, and NGAL is released into both urine and plasma. NGAL levels rise within two hours of the insult, making NGAL an early and sensitive biomarker of kidney injury, with the potential to assist clinicians in managing patients at risk of kidney injury. This study is designed to validate the assigned NGAL cutoff value by comparing to clinical diagnosis of AKI as determined by current clinical practice in the US. The study sites will enroll consecutive ICU patients. Patients are given standard clinical care and lab-work. Each day, one additional urine and two additional plasma samples will be drawn and frozen. These additional samples are shipped to Sponsor for retrospective NGAL measurements. The duration of each subject´s participation will be until discharge from the ICU, or for a maximum 8 days, whichever comes first. In addition serum creatinine values will continue to be collected manually from the hospital data system for 48 hours after discharge from the ICU. (If subject has been in ICU for 8 or more days, the follow up values are collected while the patient is still in the ICU). 250 subjects will be enrolled in total at the three investigator sites. At least 40 patients must be enrolled at each site. The NGAL value will be matched to the "clinical diagnosis" of acute kidney injury (AKI) as specified by KDIGO® guidelines. The clinical diagnosis will be assigned by a three-person adjudication panel based on the entries in the eCRF by the investigators. Adjudicators are blinded for investigation site, AKI-diagnosis by treating physician, and NGAL values. A comparison of AKI diagnosis based on the cutoff value 250 ng/mL and clinical diagnosis as assigned by the majority of the adjudication panel will be conducted.
The risk for postoperative acute kidney injury (pAKI), as for any other postoperative complications (PC), comes from a number of interactions between a patient's health before surgery, strength to tolerate surgery and influences on the operating room environment. At this time doctors do not have good tools to predict which patients may be at risk of having this complication. The purpose of this research study is to develop a urine test that can be used to predict the risk for having problems with kidney function after major surgery.
Contrast-induced nephropathy (CIN) is a side-effect of intravascular administration of iodinated contrast material. It is defined as an absolute (>44μmol/l) or relative (>25%) increase in serum creatinine from baseline values within 48-72 hours of iodinated contrast material administration, and usually resolves within two weeks. In some cases CIN has been associated with persistent renal failure, increased risk of dialysis, and mortality. It is not clear however, whether CIN is causally related to this increased risk or whether risk of morbidity and mortality is inherent in those at risk of CIN. CIN itself is asymptomatic and no treatment for CIN exists. Therefore, the focus lies on its prevention. Prevention guidelines have been drawn up in most countries and been implemented in most radiological departments. In the Netherlands, currently two guidelines for the prevention of CIN coexist, issued by CBO (Centraal BegeleidingsOrgaan) and VMS (Veiligheids Management Systeem). The prevention guidelines aim to increase patient safety by identifying patients that may be at risk of CIN (mostly patients with chronic renal insufficiency), and subsequently administering prophylactic intravenous hydration to the so identified patients, in order to prevent CIN (intravenous normal saline 4-12 hours before and 4-12 hours after exposure to iodinated contrast material). Needless to say, the introduction of these guidelines has had a great impact on patient- and health care burden. In the Netherlands alone it is estimated that yearly 100.000 to 150.000 patients receive the prophylactic treatment, incurring a total cost of over 50 million Euro. Considering the steady yearly increase of contrast procedures and the ageing population, it is evident that, in future, these numbers shall only increase further. The prophylactic treatment prescribed by the guidelines is based on a consensus of the opinion of experts in general agreement that the treatment is beneficial. However, the effectiveness of prophylactic hydration has never been adequately evaluated. Sufficiently large randomised trials comparing prophylactic intravenous hydration with a proper control group receiving no prophylactic treatment are not available, and baseline CIN incidences in untreated populations are unknown. Thus, it is not clear whether prophylactic hydration achieves its aim to prevent CIN. In order to be able to take effective measures to the benefit of patient safety, it is important to distinguish between the mechanisms underlying CIN and the ensuing increased risk of morbidity and mortality: whether it be biological variation of serum creatinine, renal damage, or cholesterol embolism; whether any causality exists between these and iodinated contrast material; and whether prophylactic intravenous hydration can prevent these from occurring without incurring more risks than it removes. These, in short, are the aims of the AMACING study.
Intraoperative intravenous fluid management practice varies greatly between anesthesiologists. Postoperative fluid based weight gain is associated with major morbidity. Postoperative respiratory complications are associated with increased morbidity, mortality and hospital costs. The literature shows conflicting data regarding intraoperative fluid resuscitation volume. No large-scale studies have focused on intraoperative fluid management and postoperative respiratory dysfunction. Hypotheses: Primary - Liberal intraoperative fluid resuscitation is associated with an increased risk of 30 day mortality Secondary - Liberal intraoperative fluid resuscitation is associated with increased likelihood of postoperative respiratory failure, pulmonary edema, reintubation, atelectasis, acute kidney injury and peri-extubation oxygen desaturation.