Urinary protein excretion rate is the best independent predictor of ESRF in non-diabetic proteinuric chronic nephropathies

Urinary protein excretion rate is the best independent predictor of ESRF in non-diabetic proteinuric chronic nephropathies. We investigated the predictors of the rate of glomerular filtration rate decline (ΔGFR) and progression to end-stage renal failure (ESRF) in the 352 patients with proteinuric non-diabetic chronic nephropathies [urinary protein excretion rate (UProt) ≥ 1g/24hr, creatinine clearance 20 to 70 ml/min/1.73m2] enrolled in the Ramipril Efficacy In Nephropathy (REIN) study. Overall the GFR declined linearly by 0.46 ± 0.05 ml/min/1.73m2/month (mean rate ± sem) over a median follow-up of 23months (range 3 to 64months), and progression to ESRF was 17.3%. Using multivariate analysis, higher UProt and mean arterial pressure (MAP) independently correlated with a faster ΔGFR (P = 0.0001 and P = 0.0002, respectively) and progression to ESRF (P = 0.0001 and P = 0.003, respectively). Mean UProt and systolic blood pressure during follow-up were the only time-dependent covariates that significantly correlated with ΔGFR (P = 0.005 and P = 0.003, respectively) and ESRF (P = 0.006 and P = 0.0001, respectively). After stratification for baseline UProt, patients in the lowest tertile (UProt < 1.9g/24hr) had the slowest ΔGFR (0.16 ± 0.07 ml/min/1.73m2/month) and progression to ESRF (4.3%) as compared with patients in the middle tertile (UProt 2.0 to 3.8g/24hr; ΔGFR, 0.55 ± 0.09 ml/min/1.73m2/month, P = 0.0002; ESRF, 15.3%, P = 0.0001) and in the highest tertile (UProt 3.9 to 18.8g/24hr; ΔGFR, 0.70 ± 0.11 ml/min/1.73m2/month, P = 0.0001; ESRF, 32.5%, P = 0.0001). Both ΔGFR (P = 0.01) and progression to ESRF (P = 0.01) significantly differed even between the middle and the highest tertiles. On the contrary, stratification in tertiles of baseline MAP failed to segregate subgroups of patients into different risk levels. Patients with the highest proteinuria and blood pressure were those with the fastest progression (ΔGFR, 0.91 ± 0.23; ESRF 34.7%). Of interest, at each level of baseline MAP, a higher proteinuria was associated with a faster ΔGFR and progression to ESRF. On the other hand, at each level of proteinuria, a faster ΔGFR was associated with MAP only in the highest tertile (> 112mm Hg) and the risk of ESRF was independent of the MAP. Thus, in chronic nephropathies proteinuria is the best independent predictor of both disease progression and ESRF. Arterial hypertension may contribute to the acceleration of renal injury associated with enhanced traffic of plasma proteins. Antihypertensive drugs that most effectively limit protein traffic at comparable levels of blood pressure are those that most effectively slow disease progression and delay or prevent ESRF in proteinuric chronic nephropathies

Kidney disease in nail–patella syndrome

Nail–patella syndrome (NPS) is a pleiotropic autosomal-dominant disorder due to mutations in the gene LMX1B. It has traditionally been characterized by a tetrad of dermatologic and musculoskeletal abnormalities. However, one of the most serious manifestations of NPS is kidney disease, which may be present in up to 40% of affected individuals. Although LMX1B is a developmental LIM-homeodomain transcription factor, it is expressed in post-natal life in the glomerular podocyte, suggesting a regulatory role in that cell. Kidney disease in NPS seems to occur more often in some families with NPS, but it does not segregate with any particular mutation type or location. Two patterns of NPS nephropathy may be distinguished. Most affected individuals manifest only an accelerated age-related loss of filtration function in comparison with unaffected individuals. Development of symptomatic kidney failure is rare in this group, and proteinuria (present in approximately one-third) does not appear to be progressive. A small minority (5–10%) of individuals with NPS develop nephrotic-range proteinuria as early as childhood or young adulthood and progress to end-stage kidney failure over variable periods of time. It is proposed that this latter group reflects the effects of more global podocyte dysfunction, possibly due to the combination of a mutation in LMX1B along with an otherwise innocuous polymorphism or mutation involving any of several genes expressed in podocytes (e.g. NPHS2, CD2AP), the transription of which is regulated by LMX1B

Hypertension in children with chronic kidney disease: pathophysiology and management

Arterial hypertension is very common in children with all stages of chronic kidney disease (CKD). While fluid overload and activation of the renin–angiotensin system have long been recognized as crucial pathophysiological pathways, sympathetic hyperactivation, endothelial dysfunction and chronic hyperparathyroidism have more recently been identified as important factors contributing to CKD-associated hypertension. Moreover, several drugs commonly administered in CKD, such as erythropoietin, glucocorticoids and cyclosporine A, independently raise blood pressure in a dose-dependent fashion. Because of the deleterious consequences of hypertension on the progression of renal disease and cardiovascular outcomes, an active screening approach should be adapted in patients with all stages of CKD. Before one starts antihypertensive treatment, non-pharmacological options should be explored. In hemodialysis patients a low salt diet, low dialysate sodium and stricter dialysis towards dry weight can often achieve adequate blood pressure control. Angiotensin-converting enzyme (ACE) inhibitors and angiotensin receptor blockers are first-line therapy for patients with proteinuria, due to their additional anti-proteinuric properties. Diuretics are a useful alternative for non-proteinuric patients or as an add-on to renin–angiotensin system blockade. Multiple drug therapy is often needed to maintain blood pressure below the 90th percentile target, but adequate blood pressure control is essential for better renal and cardiovascular long-term outcomes

Complement in glomerular injury

In recent years, research into the role of complement in the immunopathogenesis of renal disease has broadened our understanding of the fragile balance between the protective and harmful functions of the complement system. Interventions into the complement system in various models of immune-mediated renal disease have resulted in both favourable and unfavourable effects and will allow us to precisely define the level of the complement cascade at which a therapeutic intervention will result in an optimal effect. The discovery of mutations of complement regulatory molecules has established a role of complement in the haemolytic uremic syndrome and membranoproliferative glomerulonephritis, and genotyping for mutations of the complement system are already leaving the research laboratory and have entered clinical practice. These clinical discoveries have resulted in the creation of relevant animal models which may provide crucial information for the development of highly specific therapeutic agents. Research into the role of complement in proteinuria has helped to understand pathways of inflammation which ultimately lead to renal failure irrespective of the underlying renal disease and is of major importance for the majority of renal patients. Complement science is a highly exciting area of translational research and hopefully will result in meaningful therapeutic advances in the near future

Therapeutic strategies to slow chronic kidney disease progression

Childhood chronic kidney disease commonly progresses toward end-stage renal failure, largely independent of the underlying disorder, once a critical impairment of renal function has occurred. Hypertension and proteinuria are the most important independent risk factors for renal disease progression. Therefore, current therapeutic strategies to prevent progression aim at controlling blood pressure and reducing urinary protein excretion. Renin-angiotensin-system (RAS) antagonists preserve kidney function not only by lowering blood pressure but also by their antiproteinuric, antifibrotic, and anti-inflammatory properties. Intensified blood pressure control, probably aiming for a target blood pressure below the 75th percentile, may exert additional renoprotective effects. Other factors contributing in a multifactorial manner to renal disease progression include dyslipidemia, anemia, and disorders of mineral metabolism. Measures to preserve renal function should therefore also comprise the maintenance of hemoglobin, serum lipid, and calcium-phosphorus ion product levels in the normal range