Active clinical trials for "Acute Kidney Injury"

This prospective cohort study aim to investigate the ability of multiple types of assessments including 1) the modified Venous Excess Ultrasound (VExUS) assessment, 2) non-invasive estimation of absolute blood volume (ABV), and 3) change in carotid Doppler at the start of IKRT to predict IDHE in acutely ill hospitalized patients. The secondary aim will be to determine whether each modality improves the prediction of IHDE compared to the evaluation of the attending physician and whether they also predict cerebral hypoxia during IKRT measured by near-infrared spectroscopy (NIRS). Finally, detailed hemodynamic data including relative blood volume monitoring, tissue oximetry, and other parameters will be collected continuously during IKRT sessions enabling exploratory analyses aimed at identifying hemodynamic phenotypes related to IDHE during IKRT.

Acute kidney injury (AKI) is a frequent problem in the intensive care unit (ICU) affecting more than 50 % of patients. AKI is associated with several adverse outcomes, including increased mortality and increased length of ICU- and hospital stay, in particular in patients requiring Renal Replacement Therapy (RRT). Choosing the optimal time for attempting liberation from RRT is still unclear. With this study, we will describe the ability of renal ultrasound in predicting the outcome of dialysis weaning.

Research in acute care faces many challenges, including enrollment challenges, legal limitations in data sharing, limited funding, and lack of singular ownership of the domain of acute care. To overcome some of these challenges, the Center of Acute Care of the University Medical Center Groningen in the Netherlands, has established a de novo data-, image- and biobank named "Acutelines". Acutelines is initiated to improve recognition and treatment of acute diseases and obtain insight in the consequences of acute diseases, including factors predicting its outcome. Thereby, Acutelines contributes to development of personalized treatment and improves prediction of patient outcomes after an acute admission.

The aim of this study is to evaluate: The diagnostic performance of Fractional Excretion of Urea (FEUrea) for the differential diagnosis of acute kidney injury in patients with cirrhosis and ascites presenting to a tertiary care hospital. The ability of Fractional Excretion of Urea to distinguish between structural group of acute kidney injury (acute tubular necrosis) versus functional group of acute kidney injury (prerenal azotemia and hepatorenal syndrome), and types of functional group (prerenal azotemia versus hepatorenal syndrome type 1).

Acute kidney injury (AKI) is characterized by a rapid decrease in renal function. It is frequent in hospitalized patients and its incidence is higher in critically ill patients. It is associated with high rates of morbidity and mortality. AKI affects over 13 million people per year globally, and results in 1.7 million deaths. It is diagnosed in up to 20% of hospitalized patients and in 30- 60% of critically ill patients. It is the most frequent cause of organ dysfunction in intensive care units and the occurrence of even mild AKI is associated with a 50% higher risk of death. AKI has been associated with longer hospital stays, in-hospital mortality, cardiovascular events, progression to chronic kidney disease and long-term mortality. It results in a significant burden for the society in terms of health resource use during the acute phase and the potential long-term sequelae including development of chronic kidney disease and kidney failure. Yunos et al. have focused on chloride, which is the most abundant strong anion in extracellular fluid. Progression of hyperchloremia in the ICU was identified as a predictor of increased mortality in a large retrospective cohort study of critically ill septic patients. Sadan et al. have shown associations between hyperchloremia and an increased incidence of AKI in patients with subarachnoid hemorrhage, as well as in patients who have undergone abdominal surgery. Abnormal blood chloride concentrations were associated with metabolic acidosis, which may worsen patient outcomes. Moreover, hyperchloremia may be caused by inappropriate fluid management with chloride-rich solutions. Importantly, chloride-rich solutions were reportedly associated with hyperchloremia and major adverse kidney disease, including death, in intensive care settings. Urine samples are relatively easy to collect in ICU, and real-time urinary electrolyte monitoring device is available for clinical use. In addition, recent development of urinary AKI biomarkers has enabled clinical evaluation of kidney function. Komaru et al. examined associations among urinary chloride, mortality, and AKI incidence in ICU patients and concluded that lower urinary chloride concentration was associated with increased mortality and incidence of AKI in the ICU.

The aim of this prospective observational study is to evaluate the impact of acute kidney injury on sarcopenia and frailty in patients with liver cirrhosis.

The research study will investigate the longitudinal cognitive outcomes in subjects admitted as children diagnosed with sepsis who may have had acute kidney injury. Each subject will be contacted 2-15 years after their incident admission in order to solicit responses to a functional and cognitive quality of life survey. Children admitted during the same time frame that did not have kidney injury will also be surveyed.

Acute kidney injury (AKI) is a common clinical syndrome, especially in the hospital patients. AKI is recognized as an important risk factor for incident chronic kidney disease, accelerated progression to end-stage renal disease,and increased risk of short-term and long-term mortality.This study is to observe the prognosis of hospitalized patients with AKI in China.

Acute kidney injury (AKI) is a well-recognized complication in critically ill patients, which often leads to the necessity of mechanical kidney support (CRRT). In current therapeutic regimes, CRRT is used to strictly prevent azotaemia. Thus recent clinical observations, as well as data from animal testing suggest a link between controlled azotaemia and faster renal recovery in AKI patients. The aim of the study is to improve renal recovery.

Current evidence shows that computerized decision support systems (CDSS) have shown to be insufficiently effective to prevent adverse drug reactions (ADRs) at large scale (e.g. whole hospital). Several barriers for successful implementation of CDSS have been identified: over-alerting, lack of specificity of rules, and physician interruption during prescription. The effectiveness of CDSS could be increased in two ways. Firstly, by creating rules that are more specific to a given adverse drug reaction: the current study focuses on acute renal failure and hyperkalemia (two serious and frequent ADR in older hospitalized patients). Secondly, by involving the pharmacist in the review of the alerts so that he/she can transmit, if deemed necessary, a pharmaceutical recommendation to the clinician. This procedure will reduce over-alerting and prevent task interruption. The hypothesis is that the use of specific rules created by a multidisciplinary team and implemented in a CDSS, combined with a strategy for managing and transmitting alerts, can reduce specific ADRs such as hyperkalemia and acute renal failure.