Description

Kidney transplantation remains the standard treatment for patients with end-stage renal disease. It provides the patient with a better quality of life1 and a better chance of survival, for a reduced cost of care compared to dialysis. While more than 3,000 kidney transplants are carried out each year in France, more than 20,000 candidates are registered on the transplant waiting list, revealing a severe shortage of grafts. Limiting the degradation of the kidney graft would make it possible to avoid the return of patients to dialysis and limit the shortage of grafts.

At the diagnostic level, routine monitoring of graft functionality after kidney transplantation is based on the use of non-specific markers, such as serum creatinine (allowing the estimation of glomerular filtration rate or GFR) and proteinuria. Definitive diagnosis of renal allograft dysfunction still requires invasive allograft biopsy, which remains the gold standard for evaluating graft status. The anatomopathological diagnosis of renal graft dysfunction is based on the Banff classification, and makes it possible to examine the immune infiltrate and cellular lesions of the graft in order to make a diagnosis on: 1-the presence of graft rejection or other attacks and 2- the anatomical compartment affected by the pathology: tubular, vascular, interstitial or glomerular.

The start-up CGenetix offers an original approach to predict and characterize renal graft rejection/dysfunction based on the quantification of epigenetic signatures present on donor-cell-free DNA. In 2018, Moss et al. are developing a deconvolution model capable of identifying the tissue origin of circulating DNA by taking advantage of its epigenetic properties. The study confirmed that the free DNA circulating in healthy subjects comes mainly from blood cells and endothelial cells, but not from kidney cells.

In this protocol, 319 kidney transplant patients will be recruited from the Renal Transplantation departments of Pitié-Salpêtrière and Necker. Patients will be recruited into the study at the time of their hospitalization for renal biopsy for cause/indication (inclusion visit). Urine and blood samples will be taken within 24 hours before the kidney biopsy is performed.

The quantities of circulating DNA of renal origin (total kidney biomarkers (x2), specific tubules (x2), specific glomeruli (x2), specific peritubular capillaries (x2) and specific arteriolar capillaries (x2)) will be determined by digital PCR and expressed in copy/ml in blood and urine samples.

The main evaluation criterion of the research is the area under the ROC curve of the ABMR type rejection prediction models according to renal biopsy and with as covariates of interest the quantities of circulating DNA of renal origin (kidney biomarkers total (x2), specific tubules (x2), specific glomeruli (x2), specific peritubular capillaries (x2) and specific arteriolar capillaries (x2)) determined by digital PCR and expressed in copy/ml in blood and urine The final objective of this study protocol consists of i) prospectively validating the performance of the diagnostic test proposed by CGenetix and its partners INSERM 1155 and 1151 and urinary chemokines to non-invasively diagnose acute renal graft rejection and ii ) study its ability to diagnose the different types of renal transplant rejection (ABMR, TCMR, Mixed, Without rejection) The research hypotheses are: i) an AUC ≥ 0.80 / Sensitivity and specificity ≥ 80% for each biomarker taken individually; ii) an AUC ≥ 0.85 / Sensitivity and specificity ≥ 85% for the multimodal prediction model.