Oncological Screening of Kidney Tumors After Renal Transplantation.

BACKGROUND: Among renal transplant recipients, renal cell carcinoma in the native kidneys represents the most common solid tumor. At the Department of Surgery, Transplantation and Gastroenterology of Semmelweis University annual control abdominal ultrasound examination is recommended for transplant patients. Our goal was to evaluate the effectiveness of the ultrasound screening program at our institute and to learn about the characteristics of shrunken kidney tumors. METHODS: Retrospectively, we processed the results of abdominal and pelvic ultrasound examinations of 1687 kidney transplant patients, which were performed at our institute between January 1, 2012 and December 31, 2016. RESULTS: A total of 26 tumors were detected during the abovementioned period of time, of which 18 were renal cancers. Renal cancer was significantly (P = 0.029) more common in men. Seventeen renal cancers were classified as stage I and one as stage IV disease. The mean time of dialysis was 37.73 ± 24.37 months. The mean time between kidney transplantation and tumor recognition was 7.9 ± 6.29 years. The 5-year survival was 66%; however, it should be noted that only 1 patient lost his life due to his tumor disease. The mean time between the last 2 ultrasound examinations was 27.8 ± 23.89 months. Only 57% of tumors were detected by screening. No significant differences in tumor size, stage, and survival could be detected between screened and nonscreened renal cancer patients. CONCLUSIONS: Ultrasound examination at least every 2 years is an effective tool for the early detection of renal cell carcinoma of the shrunken kidneys.

Functional cyclophilin D moderates platelet adhesion, but enhances the lytic resistance of fibrin.

In the course of thrombosis, platelets are exposed to a variety of activating stimuli classified as 'strong' (e.g. thrombin and collagen) or 'mild' (e.g. ADP). In response, activated platelets adhere to injured vasculature, aggregate, and stabilise the three-dimensional fibrin scaffold of the expanding thrombus. Since 'strong' stimuli also induce opening of the mitochondrial permeability transition pore (MPTP) in platelets, the MPTP-enhancer Cyclophilin D (CypD) has been suggested as a critical pharmacological target to influence thrombosis. However, it is poorly understood what role CypD plays in the platelet response to 'mild' stimuli which act independently of MPTP. Furthermore, it is unknown how CypD influences platelet-driven clot stabilisation against enzymatic breakdown (fibrinolysis). Here we show that treatment of human platelets with Cyclosporine A (a cyclophilin-inhibitor) boosts ADP-induced adhesion and aggregation, while genetic ablation of CypD in murine platelets enhances adhesion but not aggregation. We also report that platelets lacking CypD preserve their integrity in a fibrin environment, and lose their ability to render clots resistant against fibrinolysis. Our results indicate that CypD has opposing haemostatic roles depending on the stimulus and stage of platelet activation, warranting a careful design of any antithrombotic strategy targeting CypD.

DNA, histones and neutrophil extracellular traps exert anti-fibrinolytic effects in a plasma environment.

In response to various inflammatory stimuli, neutrophils secrete neutrophil extracellular traps (NETs), web-like meshworks of DNA, histones and granular components forming supplementary scaffolds in venous and arterial thrombi. Isolated DNA and histones are known to promote thrombus formation and render fibrin clots more resistant to mechanical forces and tissue-type plasminogen activator (tPA)-induced enzymatic digestion. The present study extends our earlier observations to a physiologically more relevant environment including plasma clots and NET-forming neutrophils. A range of techniques was employed including imaging (scanning electron microscopy (SEM), confocal laser microscopy, and photoscanning of macroscopic lysis fronts), clot permeability measurements, turbidimetric lysis and enzyme inactivation assays. Addition of DNA and histones increased the median fibre diameter of plasma clots formed with 16 nM thrombin from 108 to 121 and 119 nm, respectively, and decreased their permeability constant from 6.4 to 3.1 and 3.7×10(-9) cm(2). Histones effectively protected thrombin from antithrombin-induced inactivation, while DNA inhibited plasminogen activation on the surface of plasma clots and their plasmin-induced resolution by 20 and 40 %, respectively. DNA and histones, as well as NETs secreted by phorbol-myristate-acetate-activated neutrophils, slowed down the tPA-driven lysis of plasma clots and the latter effect could be reversed by the addition of DNase (streptodornase). SEM images taken after complete digestion of fibrin in NET-containing plasma clots evidenced retained NET scaffold that was absent in DNase-treated clots. Our results show that DNA and histones alter the fibrin architecture in plasma clots, while NETs contribute to a decreased lytic susceptibility that can be overcome by DNase.