Oxalate (dys)Metabolism: Person-to-Person Variability, Kidney and Cardiometabolic Toxicity.

Oxalate is a metabolic end-product whose systemic concentrations are highly variable among individuals. Genetic (primary hyperoxaluria) and non-genetic (e.g., diet, microbiota, renal and metabolic disease) reasons underlie elevated plasma concentrations and tissue accumulation of oxalate, which is toxic to the body. A classic example is the triad of primary hyperoxaluria, nephrolithiasis, and kidney injury. Lessons learned from this example suggest further investigation of other putative factors associated with oxalate dysmetabolism, namely the identification of precursors (glyoxylate, aromatic amino acids, glyoxal and vitamin C), the regulation of the endogenous pathways that produce oxalate, or the microbiota's contribution to oxalate systemic availability. The association between secondary nephrolithiasis and cardiovascular and metabolic diseases (hypertension, type 2 diabetes, and obesity) inspired the authors to perform this comprehensive review about oxalate dysmetabolism and its relation to cardiometabolic toxicity. This perspective may offer something substantial that helps advance understanding of effective management and draws attention to the novel class of treatments available in clinical practice.

Fibrosis of Peritoneal Membrane, Molecular Indicators of Aging and Frailty Unveil Vulnerable Patients in Long-Term Peritoneal Dialysis.

Peritoneal membrane status, clinical data and aging-related molecules were investigated as predictors of long-term peritoneal dialysis (PD) outcomes. A 5-year prospective study was conducted with the following endpoints: (a) PD failure and time until PD failure, (b) major cardiovascular event (MACE) and time until MACE. A total of 58 incident patients with peritoneal biopsy at study baseline were included. Peritoneal membrane histomorphology and aging-related indicators were assessed before the start of PD and investigated as predictors of study endpoints. Fibrosis of the peritoneal membrane was associated with MACE occurrence and earlier MACE, but not with the patient or membrane survival. Serum α-Klotho bellow 742 pg/mL was related to the submesothelial thickness of the peritoneal membrane. This cutoff stratified the patients according to the risk of MACE and time until MACE. Uremic levels of galectin-3 were associated with PD failure and time until PD failure. This work unveils peritoneal membrane fibrosis as a window to the vulnerability of the cardiovascular system, whose mechanisms and links to biological aging need to be better investigated. Galectin-3 and α-Klotho are putative tools to tailor patient management in this home-based renal replacement therapy.

Low and high doses of oxandrolone promote pathological cardiac remodeling in young male rats.

Oxandrolone (OXA) used in clinical practice, however, its misuse is frequent, including by adolescents pursuing an aesthetic goal. However, the impacts of noxious doses on the cardiovascular system remain unknown. AIM: To investigate cardiac effects of OXA in low (LD) and high (HD) doses. METHODS: Male Wistar prepubescent rats were separated into 3 experimental groups: control (CON), LD, and HD. Only the CON group received the carrier (carboxymethylcellulose, 0.5%), while the LD and HD groups received, respectively, 2.5 and 37.5 mg/kg/day of OXA via gavage for 4 weeks. The hemodynamic parameters (+dP/dtmax, -dP/dtmin, and Tau) and cardiac autonomic tonus were assessed. Hearts were retrieved for histological analyses and oxidative stress evaluation. Expression levels of calcium-handling proteins were measured by western blot. RESULTS: The OXA treatment changed neither the cardiac contractility nor the cardiac autonomic tonus. However, cardiac hypertrophy, collagen deposition, and increased angiotensin-converting enzyme (ACE) expression were observed in a dose-dependent way. Also, the p-phospholamban (p-PLB)/PLB ratio was observed to decrease and increase, respectively, in the LD and HD groups; the sarcoplasmic/endoplasmic reticulum calcium ATPase 2a (SERCA2a)/PLB ratio being higher in both groups. OXA increased SOD1 expression and decreased catalase expression only in the LD group, and protein oxidation was increased in HD. CONCLUSION: Both doses of OXA could promote pathological cardiac remodeling, probably via increased ACE, and these effects were exacerbated in the HD treatment, but cardiac contractility was not affected regardless of the dose.