View clinical trials related to Haemodialysis Complication.
Filter by:Chronic kidney disease (CKD) is a long-term condition where the kidneys do not work as well as they should. End-stage kidney failure (ESKD) is the final, irreparable stage of chronic kidney disease (CKD), where kidney function has worsened, so the kidneys can no longer function independently. At this stage, dialysis is required to remove waste products and excess fluid from the blood. There are two types of dialysis. In haemodialysis (HD), blood is pumped out of the body to an artificial kidney machine and returned to the body by tubes that connect a person to the machine. In peritoneal dialysis (PD), the inside lining of the belly acts as a natural filter. PD has the advantage of being gentler on the heart. HD causes significant stress to the heart by reducing the blood flow to the heart muscle, resulting in heart failure, irregular rhythms, and eventually sudden heart death. A large observational study showed that HD patients had 48% worse survival in the first two years than PD patients. Several molecules ('biomarkers') can be detected in blood and inform doctors of heart damage. Studying the form and function of proteins (Proteomics), including how they work and interact with each other inside cells in patients, could help identify the onset of heart problems. HD patients are also prone to body fat changes (cholesterol/lipids). Due to high cholesterol, there is build-up on the walls of arteries, causing their hardening. In HD patients, this process is faster due to abnormalities in lipid structure. Therefore, studying the heart biomarkers, protein, and lipid makeup of HD patients may help to find people at substantial risk of heart and vascular problems and if they are likely to become unwell due to these heart problems.
Around 60,000 patients in the UK are being treated for severe kidney failure. The most common treatment is haemodialysis (HD). An important part of HD is removing extra fluid from the body which the kidneys normally remove in urine. Deciding how much fluid to remove is not easy. It is normally based on clinical signs, such as blood pressure or tissue swollen with fluid, but there is a need for better tests to help guide these decisions. Bioimpedance tests are one way of measuring fluid status. They involve passing a small electric current through tissue using stickers on the skin. The test is portable, cheap, simple, painless and harmless. One bioimpedance device, the Body Composition Monitor (BCM), has been designed particularly for kidney patients. However the BCM measures fluid in the whole body and cannot tell us how much fluid is in the blood (the blood volume), which has the biggest effect on patients' health. The aim of this study is to see whether blood volume measurements can help to make fluid management more individualised. This could reduce the impact of dialysis on patients' health and improve patients' experience of the treatment. Objective 1: To demonstrate whether the addition of blood volume measurements can help to tailor fluid management to HD patients' individual needs. In particular we will look at how body size, nutritional state, age and localised fluid can affect patients' blood volume. Objective 2: To see if there is a simple way of making blood volume measurements with no need for expertise or extra equipment. It is planned to recruit 40 patients into 4 clinically different groups and compare results between them. The results will be compared between groups to help us understand how decisions about fluid management can be tailored to keep blood volume at the optimal level.
Sodium (Na+) hemostasis is abnormal in CKD patients, and this element can be deposited in the skin, muscle, and skeleton - to cope with long term sodium loading. It is known that sodium stored in this non-osmotically active way, is profoundly inflammatory. Furthermore, inflammation has been associated with several uremic symptoms. The investigators will use novel Na+ MRI imaging to examine the Na+ deposition in the skin, muscle, and skeleton of five groups:1) chronic in-center hemodialysis patients, 2) chronic peritoneal dialysis patients, 3) adult and paediatric patients with CKD stage 1-5 and 4) heart failure patients with and without renal dysfunction 5) sex and age-matched healthy adult and paediatric controls. Additionally, they will investigate the association between sodium deposition in these tissues with uremic symptomatology and biochemical markers of metabolism.
Having hemodialysis affects the blood supply to various organs in the body including the heart and the brain. With time, these effects build up and can affect the way these organs function. The investigators have previously shown that the liver (a key organ which works to help clean the blood, make proteins and turn all your food into energy) is also affected. One of the ways to help protect organs from injury due to dialysis has been cooling during dialysis. The investigators want to examine whether cooling during dialysis protects the blood supply to the liver. CT imaging will be used to measure this blood supply during hemodialysis with standard and cooler settings.
In this observational study, the investigators evaluated the Treg number and function in a population of patients undergoing hemodialysis (HD). In particular, the investigators considered the relationship of Treg cell status with the different HD modalities and clinical parameters.