The Association Between Serum Vancomycin Level and Clinical Outcome in Patients With Peritoneal Dialysis Associated Peritonitis.

Introduction: Intraperitoneal (IP) vancomycin is often first-line empiric therapy and then maintenance therapy for peritoneal dialysis (PD) peritonitis. However, how vancomycin serum levels correlate with clinical outcomes remains unclear. Methods: We conducted a retrospective single-center adult cohort study of 98 patients with PD peritonitis treated with IP vancomycin between January 2016 and May 2022. The association between nadir vancomycin level and cure was evaluated in a logistic regression model, first unadjusted and then adjusted for age, sex, weight, glomerular filtration rate (GFR), and total number of days on PD. Vancomycin was assessed both as a continuous exposure (per 1 mg/l increase) and as a categorical exposure (<15 mg/l vs. ≥15 mg/l). A receiver operating characteristic curve (ROC) was created to explore nadir vancomycin level thresholds in an attempt to identify an optimal target level during treatment. Results: Of the patients, 81% achieved cure, and patients with nadir vancomycin level ≥15 mg/l were 7.5 times more likely to experience cure compared to those with a nadir level <15 mg/l (odds ratio [OR] 7.58, 95% confidence interval [CI] 1.71-33.57, P = 0.008). Weight, GFR, days on PD, sex, and age were not independently associated with outcome. The vancomycin level with the greatest discriminatory capacity for cure on the ROC analysis was 14.4 mg/l. Conclusion: Increasing IP vancomycin serum levels are associated with increased odds of cure; and maintaining vancomycin serum levels above 14-15 mg/l throughout the course of PD peritonitis treatment is likely to improve clinical outcomes.

ß-Catenin in the kidney stroma modulates pathways and genes to regulate kidney development.

BACKGROUND: Kidney development is regulated by cellular interactions between the ureteric epithelium, mesenchyme, and stroma. Previous studies demonstrate essential roles for stromal ß-catenin in kidney development. However, how stromal ß-catenin regulates kidney development is not known. We hypothesize that stromal ß-catenin modulates pathways and genes that facilitate communications with neighboring cell populations to regulate kidney development. RESULTS: We isolated purified stromal cells with wild type, deficient, and overexpressed ß-catenin by fluorescence-activated cell sorting and conducted RNA Sequencing. A Gene Ontology network analysis demonstrated that stromal ß-catenin modulates key kidney developmental processes, including branching morphogenesis, nephrogenesis and vascular formation. Specific stromal ß-catenin candidate target genes that may mediate these effects included secreted, cell-surface and transcriptional factors that regulate branching morphogenesis and nephrogenesis (Wnts, Bmp, Fgfr, Tcf/Lef) and secreted vascular guidance cues (Angpt1, VEGF, Sema3a). We validated established ß-catenin targets including Lef1 and novel candidate ß-catenin targets including Sema3e which have unknown roles in kidney development. CONCLUSIONS: These studies advance our understanding of gene and biological pathway dysregulation in the context of stromal ß-catenin misexpression during kidney development. Our findings suggest that during normal kidney development, stromal ß-catenin may regulate secreted and cell-surface proteins to communicate with adjacent cell populations.

Predictors of serum vancomycin levels in peritoneal dialysis-associated peritonitis.

BACKGROUND: Intraperitoneal (IP) vancomycin is often first-line empiric therapy for peritoneal dialysis (PD) peritonitis; however, whether dosing should be adjusted for patient-specific characteristics remains unclear. We sought to identify factors associated with the day 3 vancomycin serum level in patients receiving vancomycin for PD peritonitis. METHODS: Retrospective single-centre adult cohort of 58 patients with PD peritonitis treated with IP vancomycin between January 2016 and May 2022. Linear regression was used to examine the association between day 3 vancomycin level and candidate predictors including age, sex, weight, glomerular filtration rate (GFR), urea and creatinine clearance (total, residual, dialysate), PD modality, peritoneal solute transfer rate and initial vancomycin dose. Logistic regression was used to evaluate the likelihood of achieving a level (≥15 mg/L) associated with these predictor variables. RESULTS: A 2-g loading dose was given in 51 cases, and 38 patients (66%) had a therapeutic day 3 level. Each 5 mg/kg increase in initial vancomycin dose was associated with a 1.38 mg/L (95% confidence interval 0.52, 2.23) increase in day 3 level. Each 1 mL/min increase in GFR was associated with a 0.29 mg/L decrease (95% confidence interval 0.05, 0.52) in day 3 level. The likelihood of achieving a therapeutic level was approximately four times higher with an initial dose of ≥25 mg/kg compared to <25 mg/kg (odds ratio 3.75, 95% confidence interval 1.05, 13.46). CONCLUSIONS: Following an average 2-g vancomycin loading dose for suspected PD peritonitis, one-third of patients were subtherapeutic on day 3. GFR and weight-based dosing were independently associated with day 3 vancomycin level, and their consideration could improve the likelihood of achieving an early therapeutic level.

Quercetin treatment reduces the severity of renal dysplasia in a beta-catenin dependent manner.

Renal dysplasia, the major cause of childhood renal failure, is characterized by defective branching morphogenesis and nephrogenesis. Beta-catenin, a transcription factor and cell adhesion molecule, is markedly increased in the nucleus of kidney cells in human renal dysplasia and contributes to its pathogenesis by altering target genes that are essential for kidney development. Quercetin, a naturally occurring flavonoid, reduces nuclear beta-catenin levels and reduces beta-catenin transcriptional activity. In this study, we utilized wild type and dysplastic mouse kidney organ explants to determine if quercetin reduces beta-catenin activity during kidney development and whether it improves the severity of renal dysplasia. In wild type kidney explants, quercetin treatment resulted in abnormal branching morphogenesis and nephrogenesis in a dose dependent manner. In wild type embryonic kidneys, quercetin reduced nuclear beta-catenin expression and decreased expression of beta-catenin target genes Pax2, Six2, and Gdnf, which are essential for kidney development. Our RDB mouse model of renal dysplasia recapitulates the overexpression of beta-catenin and histopathological changes observed in human renal dysplasia. RDB kidneys treated with quercetin resulted in improvements in the overall histopathology, tissue organization, ureteric branching morphogenesis, and nephrogenesis. Quercetin treatment also resulted in reduced nuclear beta-catenin and reduced Pax2 expression. These improvements were associated with the proper organization of vimentin, NCAM, and E-cadherin, and a 45% increase in the number of developing and maturing nephrons. Further, our results show that in human renal dysplasia, beta-catenin, vimentin, and e-cadherin also have abnormal expression patterns. Taken together, these data demonstrate that quercetin treatment reduces nuclear beta-catenin and this is associated with improved epithelial organization of developing nephrons, resulting in increased developing nephrons and a partial rescue of renal dysplasia.