The remission clinic approach to halt the progression of kidney disease

Randomized multicenter studies in diabetic and nondiabetic patients with chronic proteinuric nephropathies have clearly demonstrated that renin-angiotensin system (RAS) inhibitors, such as angiotensin-converting enzyme (ACE) inhibitors and angiotensin II receptor blockers (ARBs) used alone or in combination, effectively retard renal disease progression. Proteinuria reduction, in addition to arterial blood pressure control, largely mediates the nephroprotective effect of RAS inhibitor therapy. Despite RAS inhibition, however, most patients with chronic kidney disease (CKD) progress to end-stage renal disease (ESRD). This highlights the importance of innovative therapies to halt or revert CKD progression in those at risk. Along this line, a multimodal strategy (Remission Clinic) targeting urinary proteins by dual RAS inhibition with ACE inhibitors and ARBs up-titrated to maximum tolerated doses, by intensified blood pressure control, amelioration of dyslipidemia by statins, smoking cessation and healthy lifestyle implementation was safely and effectively applied at our outpatient clinic to normalize urinary proteins and prevent renal function loss in patients otherwise predicted to rapidly progress to ESRD because of nephrotic-range proteinuria refractory to standard antihypertensive dosages of an ACE inhibitor. This approach achieved remission or regression of proteinuria and stabilized kidney function in most cases, and almost fully prevented progression to ESRD. Provided patients are closely monitored and treatment is cautiously up-titrated according to tolerability, this approach might be safely applied in day-by-day hospital practice. Effective prevention of ESRD would reduce costs of renal replacement therapy by dialysis or transplantation and would be life-saving where these are not available for all patients in need

Effects of Sevelamer Carbonate in Patients With CKD and Proteinuria: The ANSWER Randomized Trial

Rationale & Objective: Hyperphosphatemia is associated with increased risk for chronic kidney disease (CKD) progression and reduced antiproteinuric effects of renin-angiotensin system (RAS) blockers. We investigated whether the phosphate binder sevelamer carbonate may enhance the antiproteinuric effect of RAS inhibitors in patients with CKD. Study Design: Phase 2, randomized, controlled, open-label, crossover trial. Setting & Participants: Between November 2013 and December 2014, we enrolled 53 patients with CKD with estimated glomerular filtration rates (eGFRs) > 15 mL/min/1.73 m 2 and residual proteinuria with protein excretion 65 0.5 g/24 h despite maximal tolerated ramipril and/or irbesartan therapy from 2 nephrology units in Italy. Intervention: After stratification by serum phosphate level, 644 or >4 mg/dL, patients were randomly assigned to 3 months of sevelamer (1,600 mg thrice daily) treatment followed by 3 months without sevelamer separated by a 1-month washout period or 3 months without sevelamer followed by 3 months with sevelamer, also separated by a 1-month washout period. Outcomes: The primary outcome was 24-hour proteinuria (n = 49 patients). Secondary outcomes included measured GFR (using iohexol plasma clearance), office blood pressure (BP), serum lipid levels, levels of inflammation and bone metabolism biomarkers, urinary electrolyte levels, and arterial stiffness. Results: Changes in proteinuria during the 3-month treatment with (from 1.36 [IQR, 0.77-2.51] to 1.36 [IQR, 0.77-2.60] g/24 h) or without (from 1.36 [IQR, 0.99-2.38] to 1.48 [IQR, 0.81-2.77] g/24 h) sevelamer were similar (P = 0.1). Sevelamer reduced urinary phosphate excretion without affecting serum phosphate levels. Sevelamer reduced C-reactive protein (CRP), glycated hemoglobin, and total and low-density lipoprotein cholesterol levels and increased high-density lipoprotein cholesterol levels without affecting levels of office BP, measured GFR, fibroblast growth factor 23, klotho, intact parathyroid hormone, serum vitamin D, or other urinary electrolytes. Results were similar in the low- and high-phosphate groups. Sevelamer was well tolerated. Adverse events were comparable between treatment periods. One case of transient hypophosphatemia was observed during treatment with sevelamer. Limitations: Short treatment duration, lower pretreatment proteinuria than expected. Conclusions: 3-month sevelamer treatment did not reduce proteinuria in patients with CKD on maximal RAS blockade. Amelioration of inflammation and dyslipidemia with sevelamer treatment raises the possibility that it may confer benefit in patients with CKD beyond reduction of proteinuria. Funding: Sanofi (Milan, Italy). Trial Registration: Registered at ClinicalTrials.gov with study number NCT01968759

Effects of sevelamer carbonate in patients with ckd and proteinuria. the answer randomized trial

Rationale & Objective: Hyperphosphatemia is associated with increased risk for chronic kidney disease (CKD) progression and reduced antiproteinuric effects of renin-angiotensin system (RAS) blockers. We investigated whether the phosphate binder sevelamer carbonate may enhance the antiproteinuric effect of RAS inhibitors in patients with CKD. Study Design: Phase 2, randomized, controlled, open-label, crossover trial. Setting & Participants: Between November 2013 and December 2014, we enrolled 53 patients with CKD with estimated glomerular filtration rates (eGFRs) > 15 mL/min/1.73 m2 and residual proteinuria with protein excretion ≥ 0.5 g/24 h despite maximal tolerated ramipril and/or irbesartan therapy from 2 nephrology units in Italy. Intervention: After stratification by serum phosphate level, ≤4 or >4 mg/dL, patients were randomly assigned to 3 months of sevelamer (1,600 mg thrice daily) treatment followed by 3 months without sevelamer separated by a 1-month washout period or 3 months without sevelamer followed by 3 months with sevelamer, also separated by a 1-month washout period. Outcomes: The primary outcome was 24-hour proteinuria (n = 49 patients). Secondary outcomes included measured GFR (using iohexol plasma clearance), office blood pressure (BP), serum lipid levels, levels of inflammation and bone metabolism biomarkers, urinary electrolyte levels, and arterial stiffness. Results: Changes in proteinuria during the 3-month treatment with (from 1.36 [IQR, 0.77-2.51] to 1.36 [IQR, 0.77-2.60] g/24 h) or without (from 1.36 [IQR, 0.99-2.38] to 1.48 [IQR, 0.81-2.77] g/24 h) sevelamer were similar (P = 0.1). Sevelamer reduced urinary phosphate excretion without affecting serum phosphate levels. Sevelamer reduced C-reactive protein (CRP), glycated hemoglobin, and total and low-density lipoprotein cholesterol levels and increased high-density lipoprotein cholesterol levels without affecting levels of office BP, measured GFR, fibroblast growth factor 23, klotho, intact parathyroid hormone, serum vitamin D, or other urinary electrolytes. Results were similar in the low- and high-phosphate groups. Sevelamer was well tolerated. Adverse events were comparable between treatment periods. One case of transient hypophosphatemia was observed during treatment with sevelamer. Limitations: Short treatment duration, lower pretreatment proteinuria than expected. Conclusions: 3-month sevelamer treatment did not reduce proteinuria in patients with CKD on maximal RAS blockade. Amelioration of inflammation and dyslipidemia with sevelamer treatment raises the possibility that it may confer benefit in patients with CKD beyond reduction of proteinuria. Funding: Sanofi (Milan, Italy). Trial Registration: Registered at ClinicalTrials.gov with study number NCT01968759

Cluster Analysis Identifies Distinct Pathogenetic Patterns in C3 Glomerulopathies/Immune Complex-Mediated Membranoproliferative GN

Membranoproliferative GN (MPGN) was recently reclassified as alternative pathway complement-mediated C3 glomerulopathy (C3G) and immune complex-mediated membranoproliferative GN (IC-MPGN). However, genetic and acquired alternative pathway abnormalities are also observed in IC-MPGN. Here, we explored the presence of distinct disease entities characterized by specific pathophysiologic mechanisms. We performed unsupervised hierarchical clustering, a data-driven statistical approach, on histologic, genetic, and clinical data and data regarding serum/plasma complement parameters from 173 patients with C3G/IC-MPGN. This approach divided patients into four clusters, indicating the existence of four different pathogenetic patterns. Specifically, this analysis separated patients with fluid-phase complement activation (clusters 1-3) who had low serum C3 levels and a high prevalence of genetic and acquired alternative pathway abnormalities from patients with solid-phase complement activation (cluster 4) who had normal or mildly altered serum C3, late disease onset, and poor renal survival. In patients with fluid-phase complement activation, those in clusters 1 and 2 had massive activation of the alternative pathway, including activation of the terminal pathway, and the highest prevalence of subendothelial deposits, but those in cluster 2 had additional activation of the classic pathway and the highest prevalence of nephrotic syndrome at disease onset. Patients in cluster 3 had prevalent activation of C3 convertase and highly electron-dense intramembranous deposits. In addition, we provide a simple algorithm to assign patients with C3G/IC-MPGN to specific clusters. These distinct clusters may facilitate clarification of disease etiology, improve risk assessment for ESRD, and pave the way for personalized treatment

Effects of different membranes and dialysis technologies on patient treatment tolerance and nutritional parameters

There is increasing evidence that the biochemical and cellular phenomena induced by blood/membrane/dialysate interactions contribute to dialysis-related intradialytic and long-term complications. However, there is a lack of large, prospective, randomized trials comparing biocompatible and bioincompatible membranes, and convective and diffusive treatment modalities. The primary aim of this prospective, randomized trial was to evaluate whether the use of polysulfone membrane with bicarbonate dialysate offers any advantages (in terms of treatment tolerance, nutritional parameters and pre-treatment beta(2)-microglobulin levels) over a traditional membrane (Cu-prophan(R)). A secondary aim was to assess whether the use of more sophisticated methods consisting of a biocompatible synthetic membrane with different hydraulic permeability at different ultrafiltration rate (high-flux hemodialysis and hemodiafiltration) offers any further advantages. Seventy-one Centers were involved and stratified according to the availability of only the first two or all four of the following techniques: Cuprophan(R) hemodialysis (Cu-HD), low flux polysulfone hemodialysis (LfPS-HD), high-flux polysulfone high-flux hemodialysis (HfPS-HD), and high-flux polysulfone hemodiafiltration (HfPS-HDF). The 380 eligible patients were randomized to one of the two or four treatments (132 to Cu-HD, 147 to LfPS-HD, 51 to HfPS-HD and 50 to HfPS-HDF). The follow-up was 24 months. No statistical difference was observed in the algebraic sum of the end points between bicarbonate dialysis with Cuprophan(R) or with low-flux polysulfone, or among the four dialysis methods under evaluation. There was a significant decrease in pre-dialysis plasma beta(2)-microglobulin levels in high-flux dialysis of 9.04+/-10.46 mg/liter (23%) and in hemodiafiltration of 6.35+/-12.28 mg/liter (16%), both using high-flux polysulfone membrane in comparison with Cuprophan(R) and low-flux polysulfone membranes (P=0.032). The significant decrease in pre-dialysis plasma beta(2)-microglobulin levels could have a clinical impact when one considers that beta(2)-microglobulin accumulation and amyloidosis are important long-term dialysis-related complications