Physiologically based pharmacokinetic evaluation of cefuroxime in perioperative antibiotic prophylaxis.

AIMS: Adequate plasma concentrations of antibiotics during surgery are essential for the prevention of surgical site infections. We examined the pharmacokinetics of 1.5 g cefuroxime administered during induction of anaesthesia with follow-up doses every 2.5 hours until the end of surgery. We built a physiologically based pharmacokinetic model with the aim to ensure adequate antibiotic plasma concentrations in a heterogeneous population. METHODS: A physiologically based pharmacokinetic model (PK-Sim® /MoBi® ) was developed to investigate unbound plasma concentrations of cefuroxime. Blood samples from 25 thoracic surgical patients were analysed with high-performance liquid chromatography. To evaluate optimized dosing regimens, physiologically based pharmacokinetic model simulations were conducted. RESULTS: Dosing simulations revealed that a standard dosing regimen of 1.5 g every 2.5 hours reached the pharmacokinetic/pharmacodynamic target for Staphylococcus aureus. However, for Escherichia coli, >50% of the study participants did not reach predefined targets. Effectiveness of cefuroxime against E. coli can be improved by administering a 1.5 g bolus immediately followed by a continuous infusion of 3 g cefuroxime over 3 hours. CONCLUSION: The use of cefuroxime for perioperative antibiotic prophylaxis to prevent staphylococcal surgical site infections appears to be effective with standard dosing of 1.5 g preoperatively and follow-up doses every 2.5 hours. In contrast, if E. coli is relevant in surgeries, this dosing regimen appears insufficient. With our derived dose recommendations, we provide a solution for this issue.

Pharmacokinetic characteristics and microbiologic appropriateness of cefazolin for perioperative antibiotic prophylaxis in elective cardiac surgery.

OBJECTIVE: Adequate levels of perioperative antibiotic prophylaxis are essential for prevention of surgical site infections. We examined pharmacokinetic details of 2 g cefazolin administered during induction of anesthesia with repeat dosing shortly after initiation of cardiopulmonary bypass (CPB) in cardiac surgery. METHODS: To identify the microbiologic flora targeted with prophylaxis, pre-, and postoperative swabs were taken from sternal skin. Blood samples for measurement of cefazolin were obtained in 24 patients. Drug levels were used for population pharmacokinetic modeling using Nonmem software (Icon Development Solutions, San Antonio, Tex). RESULTS: More than 90% of bacteria on sternal skin were sensitive to cefazolin, indicating minimal inhibitory concentrations <8 mg/L. All serum levels of cefazolin were above 8 mg/L and might thus effectively prevent infection. Pharmacokinetic modeling in a 1-compartment model predicted a population mean clearance (CL) of 5.23 L/h and a volume of distribution (Vd) of 15.8 L. CPB increased Vd from 14.4 L to 22.1 L with a consecutive reduction to 18 L after the end of extracorporeal circulation. The final model implemented interindividual variability on CL and Vd, incorporating the covariates CPB and albumin on Vd and creatinine clearance on CL. Goodness-of-fit calculations showed that this model adequately describes the data derived from our clinical cohort. CONCLUSIONS: Two grams of cefazolin at induction of anesthesia with a repeat dose after initiation of CPB ensures adequate drug levels to target a majority of pathogens of surgical site infections. Pharmacokinetic modeling demonstrated a significant influence of CPB on the volume of distribution and elimination of cefazolin. Other influences on pharmacokinetic parameters were albumin, protein, and creatinine clearance.