BACKGROUND:Tranexamic acid (TXA) effectively reduces blood loss and transfusion requirements during craniofacial surgery. The pharmacokinetics of TXA have not been fully characterized in paediatric patients and dosing regimens remain diverse in practice. A mixed-effects population analysis would characterize patient variability and guide dosing practices. OBJECTIVE: The objective of this study was to conduct a population pharmacokinetic analysis and develop a model to predict an effective TXA dosing regimen for children with craniosynostosis undergoing cranial remodelling procedures. METHODS: The treatment arm of a previously reported placebo-controlled efficacy trial was analysed. Twenty-three patients with a mean age 23 ± 19 months received a TXA loading dose of 50 mg/kg over 15 min at a constant rate, followed by a 5 mg/kg/h maintenance infusion during surgery. TXA plasma concentrations were measured and modelled with a non-linear mixed-effects strategy using Monolix 4.1 and NONMEM(®) 7.2. RESULTS:TXA pharmacokinetics were adequately described by a two-compartment open model with systemic clearance (CL) depending on bodyweight (WT) and age. The apparent volume of distribution of the central compartment (V1) was also dependent on bodyweight. Both the inter-compartmental clearance (Q) and the apparent volume of distribution of the peripheral compartment (V2) were independent of any covariate. The final model may be summarized as: CL (L/h) = [2.3 × (WT/12)(1.59) × AGE(-0.0934)] × e(η1), V1 (L) = [2.34 × (WT/12)(1.4)] × e(η2), Q (L/h) = 2.77 × e(η3) and V2 (L) = 1.53 × e(η4), where each η corresponds to the inter-patient variability for each parameter. No significant correlation was found between blood volume loss and steady-state TXA concentrations. Based on this model and simulations, lower loading doses than used in the clinical study should produce significantly lower peak concentrations while maintaining similar steady-state concentrations. CONCLUSIONS: A two-compartment model with covariates bodyweight and age adequately characterized the disposition of TXA. A loading dose of 10 mg/kg over 15 min followed by a 5 mg/kg/h maintenance infusion was simulated to produce steady-state TXA plasma concentrations above the 16 μg/mL threshold. This dosing scheme reduces the initial high peaks observed with the larger dose of 50 mg/kg over 15 min used in our previous clinical study.
RCT Entities:
BACKGROUND:Tranexamic acid (TXA) effectively reduces blood loss and transfusion requirements during craniofacial surgery. The pharmacokinetics of TXA have not been fully characterized in paediatric patients and dosing regimens remain diverse in practice. A mixed-effects population analysis would characterize patient variability and guide dosing practices. OBJECTIVE: The objective of this study was to conduct a population pharmacokinetic analysis and develop a model to predict an effective TXA dosing regimen for children with craniosynostosis undergoing cranial remodelling procedures. METHODS: The treatment arm of a previously reported placebo-controlled efficacy trial was analysed. Twenty-three patients with a mean age 23 ± 19 months received a TXA loading dose of 50 mg/kg over 15 min at a constant rate, followed by a 5 mg/kg/h maintenance infusion during surgery. TXA plasma concentrations were measured and modelled with a non-linear mixed-effects strategy using Monolix 4.1 and NONMEM(®) 7.2. RESULTS:TXA pharmacokinetics were adequately described by a two-compartment open model with systemic clearance (CL) depending on bodyweight (WT) and age. The apparent volume of distribution of the central compartment (V1) was also dependent on bodyweight. Both the inter-compartmental clearance (Q) and the apparent volume of distribution of the peripheral compartment (V2) were independent of any covariate. The final model may be summarized as: CL (L/h) = [2.3 × (WT/12)(1.59) × AGE(-0.0934)] × e(η1), V1 (L) = [2.34 × (WT/12)(1.4)] × e(η2), Q (L/h) = 2.77 × e(η3) and V2 (L) = 1.53 × e(η4), where each η corresponds to the inter-patient variability for each parameter. No significant correlation was found between blood volume loss and steady-state TXA concentrations. Based on this model and simulations, lower loading doses than used in the clinical study should produce significantly lower peak concentrations while maintaining similar steady-state concentrations. CONCLUSIONS: A two-compartment model with covariates bodyweight and age adequately characterized the disposition of TXA. A loading dose of 10 mg/kg over 15 min followed by a 5 mg/kg/h maintenance infusion was simulated to produce steady-state TXA plasma concentrations above the 16 μg/mL threshold. This dosing scheme reduces the initial high peaks observed with the larger dose of 50 mg/kg over 15 min used in our previous clinical study.
Authors: Noreen P Dowd; Jacek M Karski; Davy C Cheng; Jo A Carroll; Yonggu Lin; Robert L James; John Butterworth Journal: Anesthesiology Date: 2002-08 Impact factor: 7.892
Authors: Amy B Beethe; Rachel A Spitznagel; Jane A Kugler; Jessica K Goeller; Marcellene H Franzen; Ryan J Hamlin; Thomas J Lockhart; Elizabeth R Lyden; Kimberly R Glogowski; Michelle M LeRiger Journal: Pediatr Qual Saf Date: 2020-07-10
Authors: Shuhui Li; Homa K Ahmadzia; Dong Guo; Elyes Dahmane; Adam Miszta; Naomi L C Luban; Jeffrey S Berger; Andra H James; Alisa S Wolberg; John N van den Anker; Jogarao V S Gobburu Journal: Br J Clin Pharmacol Date: 2021-03-08 Impact factor: 4.335
Authors: Homa K Ahmadzia; Naomi L C Luban; Shuhui Li; Dong Guo; Adam Miszta; Jogarao V S Gobburu; Jeffrey S Berger; Andra H James; Alisa S Wolberg; John van den Anker Journal: Am J Obstet Gynecol Date: 2020-11-26 Impact factor: 10.693