View clinical trials related to Acute Kidney Injury.
Filter by:This is an Open-label, Prospective, Multicenter Study to Assess the SAfety of Regional Citrate Anticoagulation Delivered by the multiFiltratePRO system in Adult Patients Requiring Continuous Renal Replacement Therapy (SARCA Study).
Circulatory shock occurs when the supply of oxygen in the tissues decreases, which leads to cell damage and affects about one third of patients admitted to Intensive Care Units (ICU). Cardiac Output (CO) can be defined as the volume of blood ejected by the left ventricle per minute and is a very useful hemodynamic parameter in the monitoring of patients with signs of circulatory shock, since it can help define the etiology and management of such patients. Nevertheless, this parameter is underused in patients treated in Emergency Units, as its measurement usually involves invasive methods and few are available in this scenario. The pulmonary artery catheter is considered the gold standard method for determining the cardiac output, however, since it is an invasive method, in recent decades other devices capable of providing this hemodynamic variable in a less invasive way have been developed. Any method capable of providing CO without the need for pulmonary artery catheter insertion is called minimally invasive CO monitoring. The potential advantages of using these methods include the simplicity of measurements, faster acquisition of hemodynamic parameters and the possibility of implementing a monitoring strategy in places such as emergencies and emergency rooms. The evaluation of these parameters allows a faster determination of the etiology of circulatory shock, which enables the early initiation of goal-guided therapy. It is known that the use of goal-guided therapy proved to be effective in reducing peri- and postoperative morbidity and mortality in patients with high surgical risk; this strategy is also associated with reduced mortality, length of stay in the ICU and on mechanical ventilation in patients admitted to the ICU who are fluid responsive. To date, there is no data regarding the impact of a hemodynamic optimization strategy on patients in the first hours of shock. The investigators aim to assess whether goal-based hemodynamic therapy, through non-invasive hemodynamic monitoring, reduces the incidence of acute renal failure in patients with circulatory shock. A multicenter, randomized, open-label study will be carried out. The study will include patients over 18 years of age with signs of shock (systolic blood pressure less than 90 mmHg and/or mean arterial pressure less than 70 mmHg plus at least one of the following changes: lactate greater than 15 mg/dL, oliguria, neurological changes, and capillary refill time greater than 3 seconds) and who have signed an informed consent form (ICF). Included patients will be randomized in a 1:1 ratio into two groups. The Goal-Directed Therapy Group will be the one in which patients will be monitored by the ClearSightâ„¢ System (Edwards Life Sciences, Irvine, CA, USA) in the first 24 hours after randomization, where the parameters cardiac index (CI), systolic volume (SV), systolic blood pressure (SBP) and mean arterial pressure (MAP) will be used to determine medical management; if the CI is less than 2.2 L/min/m² and the SV less than 35 mL/beat, an aliquot of 500 mL of crystalloid solution will be administered; if the patient presents with CI less than 2.2 L/min/m², associated with SV greater than 35 mL/beat, dobutamine will be initiated; in patients with SBP less than 90 mmHg and/or MAP less than 70 mmHg, associated with SV greater than or equal to 35 mL/beat, norepinephrine will be initiated. In the Conventional Therapy group, the allocated patients will be treated according to the assistant team, where the following parameters will be evaluated: blood pressure, peripheral oximetry, heart rate, respiratory rate, and urine output; patients showing signs of hypovolemia will receive crystalloid solution; those who remain with hypotension refractory to volume replacement will be given vasoactive drugs; those with suggestive of cardiogenic shock will be given inotropic drugs; these procedures will be determined according to the clinical judgment of the assistant team.
Acute kidney injury (AKI) is a common and serious complication after aortic dissection (AD), and it is closely related to the inflammatory response associated with cardiopulmonary bypass. Hemoperfusion can reduce the level of systemic inflammatory response effectively in patients with sepsis. Some studies have tried to apply hemoperfusion to cardiopulmonary bypass surgery, and put forward the concept of "absorptive cardiopulmonary bypass", but there are few related research reports. The use of hemoperfusion during cardiopulmonary bypass can reduce the level of systemic inflammatory response, thereby reducing the risk of postoperative AKI and improving the prognosis of patients. The Cardiovascular Surgery Department of the First Affiliated Hospital of Jiaotong University is one of the first demonstration units of "adsorption-type cardiopulmonary bypass" in China. Our previous retrospective analysis shown that intraoperative hemoperfusion can effectively reduce the occurrence of postoperative AKI in patients with AD, compared with traditional cardiopulmonary bypass. In addition, previous studies have found that the increased expression of CIRP after cardiopulmonary bypass can aggravate the oxidative stress and mitochondrial dynamics disorder in renal tubular epithelial cells, thereby inducing AKI. This project is a single-center randomized controlled study. It intends to investigate whether the application of hemoperfusion during cardiopulmonary bypass in patients with AD to reduce the level of systemic inflammatory response can reduce the incidence of postoperative AKI and improve the patient's discharge outcome. At the same time, exploratory studies were conducted to investigate whether hemoperfusion could effectively reduce the expression level of CIRP in the circulation. The successful implementation of this study can provide effective intervention methods and related theoretical basis for reducing the risk of AKI after aortic dissection.
To understand the long-term epidemiology, develop effective risk-prediction and stratification tools, and understand the pathobiology of kidney disease in COVID-19 survivors.
Acute kidney injury (AKI) is increasing worldwide in recent years and is a major risk factor of chronic kidney disease (CKD). AKI, acute kidney disease (AKD) and CKD form a continuum whereby initial kidney injury leads to ongoing renal injury and eventually end-stage renal disease if no effective treatment is applied. Nevertheless, there are no useful pharmacotherapies approved clinically for the treatment of AKI and subsequent CKD. Previous studies of the investigators have confirmed that pericytes are the primary cell source of scar-producing myofibroblasts. Furthermore, the investigators had demonstrated that significant epigenetic modification in transcriptome analysis of pericytes develops in different stage of AKI-CKD continuum. These epigenetic memory made pericytes obtain proliferative and pro-fibrotic phenotypes in activated status and persist in inactivated status. Demethylation by azacitidine prevented AKI-CKD transition, and attenuated fibrogenesis induced by a second adenine-AKI. Azacitidine has been approved in the United States Food and Drug Administration and European Union for treatment of adult acute myeloid leukemia (AML), particularly recommended front-line treatment for older patients with acute myeloid leukemia who are not candidates for intensive treatment regimens. Dosage of azacitidine in clinical trial is calculated according to previous study and is lower than chemotherapeutic dose. Low dose azacitidine has demethylation effect and less cytotoxicity. CSA-AKI is the second commonest cause of AKI in ICU. The investigators plan to initiate a double-blind randomized controlled trial (RCT) to recruit CSA-AKI patients. The patients will be divided as azacitidine group and placebo group. Patients in azacitidine group will receive three doses of low dose azacitidine in one week when AKI is diagnosed. After that, the investigators will follow up their renal function and urine protein every three month. Primary composite outcomes include a decline of at least 50% in the estimated GFR, an increase of urine protein-creatinine ratio (UPCR) over 1000 mg/g, and the development of end stage renal disease (ESRD). Secondary outcome is overall mortality.
Managing patients with renal failure requires an understanding of the molecular mechanisms that lead to its occurrence (i.e. upstream of the disease), its worsening and its persistence (i.e. downstream), while also specifying the risk of worsening renal failure (risk stratification, intolerance to the treatment or complications (infectious, metabolic, cardiovascular, cancer…). Nephrogene 2.0 aims to study these different components of kidney, immune and solid organ transplantation (SOT)-related diseases.
Assessment of the performance of multiPlus dialysate based on the serum creatinine removal 6 hours (360 min) after start of continuous veno-venous haemodialysis/ haemodiafiltration [CVVHD(F)]. multiPlus is a phosphate-containing dialysis solution for the use in continuous renal replacement therapy (CRRT) during acute kidney injury (AKI).
Renal Replacement Therapy (RRT) needs an extracorporeal circulation to conduct blood to the dialysis membrane and driving back to the patient. This extracorporeal circulation induces inevitably a risk of coagulation activation and premature clotting of the circuit. Heparin is thereby commonly used to prevent such thrombosis but exposed patient to risk of hemorrhage. This risk of hemorrhage may be important in ICU population, particularly in severe trauma patients. The calcium is an important determinant of coagulation cascade. The use of specific citrate enriched dialysate without calcium (CITRASATE®) allows to suddenly lower the calcium concentration in extracorporeal plasma, leading to a regional ineffectiveness of clotting and limited heparin needs. This low calcium plasmatic concentration into the extracorporeal circulation has however to be normalized to not generate a systemic hypocalcemia. In our ICU, a local calcium substitution protocol based on dialysate flow is used in clinical practice. Commonly used in our unit, there is a lack data to evaluate the CITRASATE dialysate in a critical population. The aim goal of our study will be to assess safety and efficacy of intermittent renal replacement therapy using CITRASATE® in critically-ill patients.
Investigators predict that the information that can be obtained in terms of renal functions before clinical development in sepsis patients can be valuable in terms of guiding treatment algorithms, planning renal replacement therapies and using drugs that are toxic to the kidneys.
Traditional HD therapy is very effective in clearing urea and smaller middle molecules, but is limited in clearing larger middle molecules. These accumulated large middle-molecular-weight uremic toxins may cause and aggravate inflammation, atherosclerosis and calcification, which indirectly lead to the death of patients. Studies have shown that, compared to conventional high-flux HD (HF-HD), HDF that combines diffusion and convection can reduce the all-cause mortality. Compared to the conventional HF-HD, HDF can more effectively clear larger molecular toxins in one session, which may be related to the better clearance effect of HDF on middle-molecular-weight toxins Theranova's innovative Medium Cut-Off® membranes has high permeability and selectivity to uremic toxins (clearance of a molecular weight of up to 45 kDa) and can retain essential proteins, to maintain patient's albumin level during the HD treatment[9]. Its unique membrane and high cut-off characteristics expand the clearance range beyond those of flux membrane dialyzers. Theranova 400 can be widely used in most blood purification centers under conventional HD equipment and treatment modes, with the effect similar to HDF This study is to demonstrate non-inferiority of the Theranova 400 Dialyzer in hemodialysis (HD) mode (hereinafter referred to as Theranova 400) compared to hemodiafiltration (HDF), using FX 800 in HDF mode (hereinafter referred to as FX 800).