Population Pharmacokinetics of Remdesivir and GS-441524 in Hospitalized COVID-19 Patients.

The objective of this study was to describe the population pharmacokinetics of remdesivir and GS-441524 in hospitalized coronavirus disease 2019 (COVID-19) patients. A prospective observational pharmacokinetic study was performed in non-critically ill hospitalized COVID-19 patients with hypoxemia. For evaluation of the plasma concentrations of remdesivir and its metabolite GS-441524, samples were collected on the first day of therapy. A nonlinear mixed-effects model was developed to describe the pharmacokinetics and identify potential covariates that explain variability. Alternative dosing regimens were evaluated using Monte Carlo simulations. Seventeen patients were included. Remdesivir and GS-441524 pharmacokinetics were best described by a one-compartment model. The estimated glomerular filtration rate (eGFR) on GS-441524 clearance was identified as a clinically relevant covariate. The interindividual variability in clearance and volume of distribution for both remdesivir and GS-441524 was high (remdesivir, 38.9% and 47.9%, respectively; GS-441525, 47.4% and 42.9%, respectively). The estimated elimination half-life for remdesivir was 0.48 h, and that for GS-441524 was 26.6 h. The probability of target attainment (PTA) of the in vitro 50% effective concentration (EC50) for GS-441524 in plasma can be improved by shortening the dose interval of remdesivir and thereby increasing the total daily dose (PTA, 51.4% versus 94.7%). In patients with reduced renal function, the metabolite GS-441524 accumulates. A population pharmacokinetic model for remdesivir and GS-441524 in COVID-19 patients was developed. Remdesivir showed highly variable pharmacokinetics. The elimination half-life of remdesivir in COVID-19 patients is short, and the clearance of GS-441524 is dependent on the eGFR. Alternative dosing regimens aimed at optimizing the remdesivir and GS-441524 concentrations may improve the effectiveness of remdesivir treatment in COVID-19 patients.

Evaluating imipenem + cilastatin + relebactam for the treatment of complicated urinary tract infections.

INTRODUCTION: The addition of the ß-lactamase inhibitor relebactam to imipenem restores the antibacterial activity against the majority of multidrug resistant Gram-negative bacteria. Complicated urinary tract infections (UTIs) are predominantly caused by Gram-negative uropathogens. The rise in antibiotic resistance, including to carbapenems, is an increasing challenge in daily practice. AREAS COVERED: In the current review, the use of imipenem/relebactam in complicated UTI is evaluated by discussing its chemistry, pharmacokinetics/dynamics, microbiology, safety, and clinical efficacy. The authors also provide their expert perspectives onto its use and its future place in the treatment armamentarium. EXPERT OPINION: With respect to complicated UTI, it should be noted that, to our knowledge, there are no data yet upon the clinical efficacy of imipenem/relebactam in patients with severe urosepsis or men with suspected prostatitis. Further studies upon these specific groups of UTI patients are needed including additional pharmacokinetic studies upon its tissue penetration of the prostate which is currently unknown. However, in our opinion, imipenem/relebactam can be used in complicated UTI when other treatment options are limited.

Population pharmacokinetics of ceftriaxone administered as continuous or intermittent infusion in critically ill patients.

OBJECTIVES: To describe the population pharmacokinetics and protein-binding characteristics of unbound ceftriaxone administered as continuous or intermittent infusion. Additionally, to determine the optimal dosing regimen in critically ill patients. METHODS: A pharmacokinetic study was performed in the ICU of a tertiary teaching hospital. Patients were treated with ceftriaxone as continuous or intermittent infusion. A population pharmacokinetic model was developed with non-linear mixed-effects analysis. Subsequently, the PTA of a 100% T>MIC was assessed for influential patient characteristics using Monte Carlo simulation. RESULTS: Fifty-five patients were included. The pharmacokinetics of ceftriaxone was best described by a one-compartment model with non-linear saturable protein binding including the following covariates: body weight, estimated CLCR, serum albumin concentration and mode of administration. For pathogens with an MIC of 1 mg/L, the simulation demonstrated that intermittent infusion of 2 g/24 h only resulted in a ≥90% PTA in patients with a reduced CLCR (0-60 mL/min). Intermittent infusion of 2 g/12 h led to sufficient exposure if CLCR was 0-90 mL/min and continuous infusion of 2 g/24 h led to a ≥90% PTA in all simulations (CLCR 0-180 mL/min). CONCLUSIONS: In the critically ill, the clearance of unbound ceftriaxone is closely related to CLCR. Furthermore, ceftriaxone protein binding is saturable, variable and dependent on serum albumin concentration. Intermittent dosing of 2 g/24 h ceftriaxone leads to subtherapeutic exposure in patients with a normal or increased CLCR. Treating these patients with continuous infusion of 2 g/24 h is more effective than an intermittent dosing regimen of 2 g/12 h.