View clinical trials related to Renal Insufficiency, Chronic.
Filter by:The goal of this clinical trial is to understand the communication occurring between Black and Caucasian patients and their transplant providers during transplant evaluation consultations and assess relationships between these communicative elements and patient and provider factors, patient-reported outcomes and living donor transplant outcomes - living donor referrals, evaluations, and transplants. We will use these findings to inform the development of a communication skills training for transplant providers and test the impact of the training on providers' communication about live donor kidney transplants with Black and Caucasian patients and living donor transplant outcomes. The main questions it aims to answer are: - How does the use of the use of instrumental, relational and affective communication by patients and providers during the transplant consultation differ by patient and provider factors, patient-reported outcomes and patient ethnicity? - What elements of instrumental, relational and affective communication will be predictive of live donor kidney transplant (LDKT) process outcomes (LD inquiries and evaluations, and actual LDKTs)? Participants will be asked to complete brief surveys before and after the transplant consultation and to give permission for the consultation to be audiorecorded. This data will be used to develop a training to educate providers on the key communication factors predictive of LDKT process outcomes specific to Black and Caucasian patients, and provide guidance on their application during patient consultations. Researchers will then compare communication and patient-reported and LDKT process outcomes between trained and untrained providers to see whether the training has any effect on living donor inquiries and evaluations, and actual LDKTs.
factors contributing to thrombocytopenia in ESRD include uremia, blood loss, sepsis, and heparin treatment (2). Haemodialysis (HD) has been also identified as a potential cause of thrombocytopenia due to the interaction of dialysis membranes with platelets, triggering adhesion, aggregation, and activation. Renal replacement therapy has improved in recent decades, particularly with the use of synthetic and highly biocompatible dialyzer membranes. During hemodialysis treatment, patients are exposed to a variety of components of the dialysis circuit and thrombocytopenia is not uncommon
Blood flow to the kidneys is important in the development of kidney diseases. Currently we do not have ways of measuring and monitoring kidney blood flow for patients in real-time. This is a major barrier to investigation and management of acute kidney injury (AKI) and chronic kidney disease (CKD). Kidney blood flow can be reliably measured using a specialised type of MRI scan, but this is expensive and difficult to do in people who are unwell. Contrast-enhanced ultrasound (CEUS) is a new technique, which uses a contrast containing microbubbles to measure blood flow. The benefits of this method are that it is relatively inexpensive, the contrast agents are not kidney-damaging and it can be done at the bedside. We want to compare contrast enhanced ultrasound against the current best-measure of kidney blood flow, to see if it is giving accurate information about kidney blood flow. We will do this by doing both MRI and contrast enhanced ultrasound scans in people with chronic kidney disease and comparing the results.
Lupus nephritis (LN) is a common manifestation in patients with systemic lupus erythematosus (SLE), and is an important cause of acute kidney injury and chronic kidney disease (CKD). Although the standard-of-care treatments for active severe LN are effective, a substantial proportion of LN patients still develop CKD and eventually end-stage kidney disease (ESKD). Cardiovascular complications are common and is a leading cause of death in SLE and LN patients. It is well recognized that LN patients had multiple risk factors for cardiovascular complications such as diabetes mellitus (DM), dyslipidaemia and vascular inflammation. Sodium-glucose co-transporter 2 (SGLT2) inhibitor are initially developed as an oral anti-diabetic agent and has shown to be effective in glycaemic control, has benefits in lipid metabolism, cardiovascular and renal outcomes, and also well tolerated by patients. Various trials have also demonstrated the benefits of SGLT2 inhibitor in the reduction of CKD, ESKD, and renal or cardiovascular death. However, the effect of SGLT2 inhibitor in LN remains unclear. The purpose of this study is to investigate the effect of SGLT2 on renal outcomes in LN patients with CKD, as well as the side effects, metabolic profiles, immunological functions and disease stability.
This study is asses the hematological changes in children with chronic kidney disease stage 3 to 5 including - Complete blood picture - Coagulation profile (PT, PC, PTT) - Iron study
Assess frequency of renal affection in mafld
The aim of this research study is to look at the body composition (such as muscle and fat) in people with chronic kidney disease (CKD) and comparing it with body composition is people without CKD. The investigators currently understand loss of muscle function and mass (sarcopenia) affect the general health of people as they age, but this process seems to be more common, accelerated, and occurs earlier in people with CKD. There is limited evidence in this area, and we believe that if we understand when and how sarcopenia affects people with CKD, investigators can guide future trials and treatments to help treat sarcopenia, and in turn improve quality of life and health outcomes in people with CKD.
The goal of this clinical trial is to determine the feasibility of remote clinical trial conduct in patients with type 2 diabetes and elevated albuminuria. The main questions it aims to answer are: - What is the feasibility (and advantages) of remote clinical trial conduct with multiple medications in patients with type 2 diabetes and elevated albuminuria? - What is the individual response to the SGLT2 inhibitor empagliflozin in urine albumin-creatinine ratio? - What is the individual response to the SGLT2 inhibitor empagliflozin in systolic blood pressure, body weight, eGFR, and fasting plasma glucose? - Can suboptimal treatment responses to empagliflozin be overcome by the addition or substitution with finerenone? Participants will collect all study data in the comfort of their own environments - First-morning void urine samples - Capillary blood samples - Blood pressure - Body weight Participants will be assigned to a 3-week treatment period with empagliflozin 10 mg/day. Based on the albuminuria response after 2 weeks, participants will be allocated to one of three treatment regimens after the 3-week treatment period with empagliflozin: - Continue empagliflozin for 4 more weeks (good response). - Continue empagliflozin for 4 more weeks and add finerenone 10 or 20 mg will be added for 4 weeks (moderate response). - Stop empagliflozin and start finerenone 10 or 20 mg for 4 weeks (no response)
This is a pilot trial of a 16-week physical activity and power training program among 30 Veterans/arm with advanced chronic kidney disease. The trial aims to test whether the program is tolerable to Veterans.
Background: The patient presenting Chronic Kidney Disease, with etiology of diabetes mellitus (DM), has a metabolic alteration characterized by an elevation of glycemia and accompanied by cardiovascular complications, this increases the morbidity and mortality associated with the disease. Therefore, it is necessary to maintain adequate metabolic control to reduce the incidence of these complications. This task is extraordinarily difficult without the use of Icodextrin due to the optimal adjustment of insulin, due to the additional supply of glucose contained in the Dialysis Bosas and which is absorbed through the peritoneum. Under this premise, it is of utmost importance the surveillance of the patient through constant glycemic monitoring to provide an overview of the metabolic status of our patients, this will allow clinically relevant data to improve care, minimize expenses in the health system and implement measures for decision making in the adjustment of dialysis treatment. Objective: To use continuous glucose monitoring to detect whether the type, dose, route of administration and timing of insulin application are associated with the patterns provided by continuous glucose monitoring (magnitude and duration of periods of hyper and/or hypoglycemia) in 24-hour periods of tissue glucose. Material and methods: This is a cross-sectional, non-interventional study in adult patients with Type 2 Diabetes Mellitus on Peritoneal Dialysis in its Automated modality who present high and high average peritoneal transport type. As inclusion criteria, participants over 40 years of age, of any sex, diagnosed with Diabetic Nephropathy, and who are insulin-dependent for metabolic control, with at least three months of PD treatment. The project will consist of evaluating the patient's glycemic control continuously, with an automatic scan and data recording every six hours during the infusion time of Automated Peritoneal Dialysis. For this, 110 patients are required according to the sample size. The Guardian TM 3 Sensor will be placed using the One PressTM Grafter subcutaneously in the upper posterior region of the patient's non-dominant arm, it is a minimally invasive procedure that does not require surgical protocols. This sensor will be connected to the Guardian Connect Transmitter for continuous communication with the Guardian™ Connect (App). The sensor has an approximate life of 7 days (time that lasts the enzymatic reaction and that allows an adequate measurement) the data will be transmitted every five minutes 24 hours a day, for 7 consecutive days. The patient will be scheduled at the end of these days to place a second sensor and complete the 14 days of follow-up. On day seven, the patient will be scheduled for sensor removal, and a new one will be placed to complete 14 days of follow-up. On day 14, the total 24-hour PD drainage volume will be recovered for a glucose, urea and creatinine measurement and peritoneal glucose absorption, D/P creatinine and Kt/V will be calculated. The dietary information will be obtained for the calculation of calorie intake and meal time; it is together with the subcutaneous application of insulin will be recorded within the same GuardianTM Connect (App). Statistical analysis: The databases will be audited in monthly periods by random sampling in blocks of 5% of their content. Semi-annual reports will be integrated with the monitoring of the records achieved and the outcomes to date of the reports. The reports will contain the basic descriptive information (central tendency and dispersion) according to the characteristics of the variables. Patients will be classified according to the time of glucose measurements within the pre-established ranges (70-180 mg / dL), the goal is that 70% of the time they are in that range and will be called "Adequate" and those who do not reach the goal will be called "Not Adequate". The results will be reported with measures of central tendency and dispersion appropriate to the characteristics of the variables. For the detection of difference between the appropriate and inappropriate group, the Chi square statistic or the Student's T or Mann-Whitney U will be used according to the type of variables. For the association analysis that allows detecting the variables of greatest influence on glycemic control in the recommended ranges with continuous glucose monitoring, logistic regression analysis will be used. In a first stage, analysis will be done by independent variable and in a second stage, a multivariate analysis will be made, where the type of insulin, the route of administration, the dose and the schedules will be considered. At this stage, confounding variables will also be included, such as; obesity, adherence to treatment and diet and physical activity prescribed by the treating physician.