Objective <p>Augmented renal clearance is increasingly recognized in pediatric patients with febrile neutropenia (FN), leading to enhanced elimination of renally cleared antimicrobials including vancomycin (VCM). Although fever‑associated hemodynamic changes may accelerate VCM clearance, their quantitative impact in the hospital-based general pediatric cohort remains unclear. The primary objective of this study was to quantify the effects of FN and infection-associated fever on VCM clearance in pediatric patients and to identify optimal dosing regimens across age and renal function strata.</p> Methods <p>This retrospective study included inpatients aged &lt; 18 years receiving VCM with therapeutic drug monitoring. Population pharmacokinetic analysis was performed using a two‑compartment model with allometric scaling and maturation functions. Monte Carlo simulations were conducted to evaluate the probability of attaining a target area under the concentration–time curve (AUC<sub>48–72h</sub>) of 400–600 μg*h/mL across dosing regimens.</p> Results <p>A total of 129 patients and 214 VCM concentrations were analyzed. Estimated glomerular filtration rate and daily maximum body temperature (BT) ≥ 38°C were independently associated with increased VCM clearance. BT ≥ 38°C increased VCM clearance by 27%, and the final model showed robust predictive performance. Simulation analyses demonstrated that febrile patients required approximately 1.2–1.3‑fold higher daily VCM doses than those of afebrile patients across all age groups and renal function categories.</p> Conclusion <p>Renal function and BT ≥ 38°C significantly increase VCM clearance in pediatric patients. Standard dosing may be insufficient in febrile patients, and higher initial doses should be considered. Incorporating body temperature and renal function into dosing decisions may improve target exposure attainment.</p>

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Impact of Febrile State on Vancomycin Clearance in Pediatric Patients: Insights From Population Pharmacokinetic Modeling

  • Ryota Tanaka,
  • Ayato Sawaguchi,
  • Tomoyuki Mizuno,
  • Kei Irie,
  • Hiroyuki Ono,
  • Erino Amano,
  • Hironori Goto,
  • Sho Tashiro,
  • Ryosuke Tatsuta,
  • Naoki Yoshikawa,
  • Naoki Hirano,
  • Kenji Ihara,
  • Hiroki Itoh

摘要

Objective

Augmented renal clearance is increasingly recognized in pediatric patients with febrile neutropenia (FN), leading to enhanced elimination of renally cleared antimicrobials including vancomycin (VCM). Although fever‑associated hemodynamic changes may accelerate VCM clearance, their quantitative impact in the hospital-based general pediatric cohort remains unclear. The primary objective of this study was to quantify the effects of FN and infection-associated fever on VCM clearance in pediatric patients and to identify optimal dosing regimens across age and renal function strata.

Methods

This retrospective study included inpatients aged < 18 years receiving VCM with therapeutic drug monitoring. Population pharmacokinetic analysis was performed using a two‑compartment model with allometric scaling and maturation functions. Monte Carlo simulations were conducted to evaluate the probability of attaining a target area under the concentration–time curve (AUC48–72h) of 400–600 μg*h/mL across dosing regimens.

Results

A total of 129 patients and 214 VCM concentrations were analyzed. Estimated glomerular filtration rate and daily maximum body temperature (BT) ≥ 38°C were independently associated with increased VCM clearance. BT ≥ 38°C increased VCM clearance by 27%, and the final model showed robust predictive performance. Simulation analyses demonstrated that febrile patients required approximately 1.2–1.3‑fold higher daily VCM doses than those of afebrile patients across all age groups and renal function categories.

Conclusion

Renal function and BT ≥ 38°C significantly increase VCM clearance in pediatric patients. Standard dosing may be insufficient in febrile patients, and higher initial doses should be considered. Incorporating body temperature and renal function into dosing decisions may improve target exposure attainment.