High-sensitive troponin T, suPAR and Beta-2-microglobulin changes in concentration during hemodialysis.

Hemodialysis (HD) patients are at high risk of cardiovascular disease and death. Reliable biomarkers for risk stratification and detection of acute myocardial infarction (AMI) are therefore pivotal. Cardiac troponins (cTn) are the preferred biomarkers for AMI. It remains unclear, if cTn concentrations changes as a consequence of HD treatment itself during dialysis. In this study, cTn was compared with soluble urokinase plasminogen activator receptor (suPAR) and Beta-2-microglobulin (B2M). We performed a prospective study including 17 HD patients measuring high-sensitive cardiac troponin t (hs-cTnT), suPAR and B2M before and after a dialysis session and verified the results in a random subgroup of eight patients from the group by repeating their measurements before and after a dialysis session 15 weeks later. Biomarker concentrations after dialysis were adjusted according to hemodilution or concentration according to the hemoglobin concentration. The average hs-cTnT concentration decreased significantly by -9.9% after dialysis (95% CI: -13.6% to -6.2%). The average (paired) difference were - 6.7 ng/L (p = 0.0104) after dialysis comparing 25 HD treatment occasions. SuPAR was not significantly influenced by dialysis. B2M decreased by -58% after HD as an expected result from the molecular size of the biomarker. The hs-cTnT in average decreased by -9.9% after dialysis. This is a diagnostic challenge since the current guidelines suggest a 20% change in hs-cTnT in patients with acute myocardial infarction. Larger prospective studies investigating the different factors influencing hs-cTnT after HD are warranted. Adjusting biomarker concentrations according to hemodilution or concentration using the hemoglobin concentration, should be considered in future studies to determine more exact changes in concentrations of cTnT and other relevant biomarkers.

RRP7A links primary microcephaly to dysfunction of ribosome biogenesis, resorption of primary cilia, and neurogenesis.

Primary microcephaly (MCPH) is characterized by reduced brain size and intellectual disability. The exact pathophysiological mechanism underlying MCPH remains to be elucidated, but dysfunction of neuronal progenitors in the developing neocortex plays a major role. We identified a homozygous missense mutation (p.W155C) in Ribosomal RNA Processing 7 Homolog A, RRP7A, segregating with MCPH in a consanguineous family with 10 affected individuals. RRP7A is highly expressed in neural stem cells in developing human forebrain, and targeted mutation of Rrp7a leads to defects in neurogenesis and proliferation in a mouse stem cell model. RRP7A localizes to centrosomes, cilia and nucleoli, and patient-derived fibroblasts display defects in ribosomal RNA processing, primary cilia resorption, and cell cycle progression. Analysis of zebrafish embryos supported that the patient mutation in RRP7A causes reduced brain size, impaired neurogenesis and cell proliferation, and defective ribosomal RNA processing. These findings provide novel insight into human brain development and MCPH.