8 Clinical Trials for Various Conditions
The primary goal of this Multicenter Study is to develop and to evaluate a method for measuring donor-specific cell free DNA in blood samples from transplant recipients as markers of rejection. Blood samples obtained periodically from heart transplant recipients are assessed for cell free DNA relative to clinical data in order to determine whether changes in the level of cell free DNA indicate rejection. This research study proposes testing a blood sample obtained from the heart transplant recipient. The research seeks to establish whether this blood test will show when the patient is beginning to or already rejecting the transplanted heart. BACKGROUND Identifying if a transplant patient is beginning to or already rejecting the heart is necessary, so that appropriate treatment can be started to halt the rejection. Heart catheterization with biopsy is the usual method used for assessing whether a patient may be rejecting the heart. There are also a number of other methods that transplant physicians will use to look for signs of rejection including other blood tests, echocardiograms, obtaining pressure readings during heart catheterization, and micro-array testing of blood obtained during biopsy. These technologies are limited in ability to consistently and accurately identify the presence of rejection. The usual method of checking for rejection involves obtaining a sample of the heart tissue (heart biopsy); biopsy can only be accomplished through heart catheterization which is an invasive procedure that has risks associated with disturbing the heart such as puncturing the heart or causing the heart rate to change or damaging tissue in the heart. Overtime, repeating this invasive procedure can diminish the ease of the procedure because the veins can become scarred and more difficult to access. For these reasons, researchers believe that it would be good to have a blood test that gives information about the possibility of rejection so that it may not be necessary to do as many heart biopsies. Also, a blood test may be able to provide information about the heart or about rejection that is currently not available at all.
Heart transplantation is a life saving therapy for people with end stage heart failure. Acute rejection, a process where the immune system recognizes the transplanted heart as foreign and mounts a response against it, remains a clinical problem despite improvements in immunosuppressive drugs. Acute rejection occurs in 20-30% of patients within the first 3 months post-transplant, and is currently detected by highly invasive heart tissue biopsies that happen 12-15 times in the first year post-transplant. Replacing the biopsy with a simple blood test is of utmost value to patients and will reduce healthcare costs. The goal of our project is to develop a new blood test to monitor heart transplant rejection. Advances in biotechnology have enabled simultaneous measurement of many molecules (e.g., proteins, nucleic acids) in blood, driving the development of new diagnostics. Our team is a leader in using computational tools to combine information from numerous biological molecules and clinical data to generate "biomarker panels" that are more powerful than existing diagnostic tests. Our sophisticated analytic methods has recently derived HEARTBiT, a promising test of acute rejection comprising 9 RNA biomarkers, from the measurement of 30,000 blood molecules in 150 Canadian heart transplant patients. Our objective is to study a custom-built HEARTBiT test in a setting and on a technology that enable clinical adoption. We will evaluate the new test on 400 new patients from 5 North American transplant centres. We will also track patients' HEARTBiT scores over time to help predict future rejection, and explore use of proteins and micoRNAs to improve HEARTBiT. Our work will provide the basis for a future clinical trial. The significance of this work rests in that it will provide a tool to identify acute cardiac rejection in a fast, accurate, cost-effective and minimally invasive manner, allowing for facile long-term monitoring and therapy tailoring for heart transplant patients.
The primary objective of this proposal is to show the efficacy of contrast enhanced ultrasonography in detecting heart transplant rejection in humans. The secondary objective is to demonstrate the efficacy of this technique in generating data which allow for the assessment of short and long term outcomes.
This trial was to examine the impact of everolimus and reduced dose of cyclosporine on efficacy and safety compared to mycophenolate mofetil and a standard dose of cyclosporine in heart transplant recipients.
The investigators will evaluate for early evidence of cardiac allograft dysfunction by cardiac MRI and single cell sequencing to determine underlying molecular and macroscopic causes.
Magnetic Resonance Elastography (MRE) for cardiac transplant patients.
All individuals who receive a heart transplant are at risk for developing antibody-mediated rejection (AMR). An antibody is a protein produced by the body's immune system when it detects a foreign substance, called an antigen. The mechanism of an antibody is to attack an antigen. In antibody mediated rejection, antibodies will attack the transplanted heart, causing injury to the heart. The purpose of this investigation is to determine if a study drug, called eculizumab (Soliris), is safe to use in heart transplant recipients, and determine if it reduces risk of antibody-mediated rejection.
The investigators will use cardiac MRI to measure the myocardial perfusion reserve and amount of myocardial edema and fibrosis in heart-transplant patients with nonspecific allograft dysfunction in contrast to those with normal graft function. The investigators hypothesize that patients with nonspecific allograft dysfunction will demonstrate decreased myocardial perfusion reserve, related to microvascular allograft vasculopathy, compared to those with normal graft function.