Effects of rare kidney diseases on kidney failure: a longitudinal analysis of the UK National Registry of Rare Kidney Diseases (RaDaR) cohort

\ua9 2024 The Author(s). Published by Elsevier Ltd. This is an Open Access article under the CC BY 4.0 licenseBackground: Individuals with rare kidney diseases account for 5–10% of people with chronic kidney disease, but constitute more than 25% of patients receiving kidney replacement therapy. The National Registry of Rare Kidney Diseases (RaDaR) gathers longitudinal data from patients with these conditions, which we used to study disease progression and outcomes of death and kidney failure. Methods: People aged 0–96 years living with 28 types of rare kidney diseases were recruited from 108 UK renal care facilities. The primary outcomes were cumulative incidence of mortality and kidney failure in individuals with rare kidney diseases, which were calculated and compared with that of unselected patients with chronic kidney disease. Cumulative incidence and Kaplan–Meier survival estimates were calculated for the following outcomes: median age at kidney failure; median age at death; time from start of dialysis to death; and time from diagnosis to estimated glomerular filtration rate (eGFR) thresholds, allowing calculation of time from last eGFR of 75 mL/min per 1\ub773 m2 or more to first eGFR of less than 30 mL/min per 1\ub773 m2 (the therapeutic trial window). Findings: Between Jan 18, 2010, and July 25, 2022, 27 285 participants were recruited to RaDaR. Median follow-up time from diagnosis was 9\ub76 years (IQR 5\ub79–16\ub77). RaDaR participants had significantly higher 5-year cumulative incidence of kidney failure than 2\ub781 million UK patients with all-cause chronic kidney disease (28% vs 1%; p<0\ub70001), but better survival rates (standardised mortality ratio 0\ub742 [95% CI 0\ub732–0\ub752]; p<0\ub70001). Median age at kidney failure, median age at death, time from start of dialysis to death, time from diagnosis to eGFR thresholds, and therapeutic trial window all varied substantially between rare diseases. Interpretation: Patients with rare kidney diseases differ from the general population of individuals with chronic kidney disease: they have higher 5-year rates of kidney failure but higher survival than other patients with chronic kidney disease stages 3–5, and so are over-represented in the cohort of patients requiring kidney replacement therapy. Addressing unmet therapeutic need for patients with rare kidney diseases could have a large beneficial effect on long-term kidney replacement therapy demand. Funding: RaDaR is funded by the Medical Research Council, Kidney Research UK, Kidney Care UK, and the Polycystic Kidney Disease Charity

Failing mouse hearts utilize energy inefficiently and benefit from improved coupling of glycolysis and glucose oxidation.

AIMS: To determine whether post-infarction LV dysfunction is due to low energy availability or inefficient energy utilization, we compared energy metabolism in normal and failing hearts. We also studied whether improved coupling of glycolysis and glucose oxidation by knockout of malonyl CoA decarboxylase (MCD-KO) would have beneficial effects on LV function and efficiency. METHODS AND RESULTS: Male C57BL/6 mice were subjected to coronary artery ligation (CAL) or sham operation (SHAM) procedure. After 4 weeks and echocardiographic evaluation, hearts were perfused (working mode) to measure LV function and rates of energy metabolism. Similar protocols using MCD-KO mice and wild-type (WT) littermates were used to assess consequences of MCD deficiency. Relative to SHAM, CAL hearts had impaired LV function [lower % ejection fraction (%EF, 49%) and LV work (46%)]. CAL hearts had higher rates (expressed per LV work) of glycolysis, glucose oxidation, and proton production. LV work per ATP production from exogenous sources was lower in CAL hearts, indicative of inefficient exogenous energy substrate utilization. Fatty acid oxidation rates, ATP, creatine, and creatine phosphate contents were unaffected. Utilization of endogenous substrates, triacylglycerol and glycogen, was similar in CAL and SHAM hearts. MCD-KO CAL hearts had 31% higher %EF compared with that of WT-CAL, and lower rates of glycolysis, glucose oxidation, proton production, and ATP production, indicative of improved efficiency. CONCLUSION: CAL hearts are inefficient in utilizing energy for mechanical function, possibly due to higher proton production arising from mismatched glycolysis and glucose oxidation. MCD deficiency lessens proton production, LV dysfunction, and inefficiency of exogenous energy substrate utilization