Hambrick H Rhodes, Fei Lin, Pavia Kathryn, Kaplan Jennifer, Mizuno Tomoyuki, Tang Peter, Schuler Erin, Benoit Stefanie, Girdwood Sonya Tang
Division of Nephrology and Hypertension, Cincinnati Children's Hospital Medical Center, Cincinnati, OH; Division of Translational and Clinical Pharmacology, Cincinnati Children's Hospital Medical Center, Cincinnati, OH.
Department of Pediatrics, University of Cincinnati College of Medicine, Cincinnati, OH; Division of Biostatistics and Epidemiology, Cincinnati Children's Hospital Medical Center, Cincinnati, OH.
Transplant Cell Ther. 2024 Jun;30(6):614.e1-614.e11. doi: 10.1016/j.jtct.2024.03.021. Epub 2024 Mar 22.
Pediatric hematopoietic stem cell transplant (HSCT) patients are at risk of developing both sepsis and altered kidney function. Cefepime is used for empiric coverage post-HSCT and requires dose adjustment based on kidney function. Since cefepime's antimicrobial efficacy is determined by the time free concentrations exceed bacterial minimum inhibitory concentration (MIC), it is important to assess kidney function accurately to ensure adequate concentrations. Serum creatinine (SCr) is routinely used to estimate glomerular filtration rate (eGFR) but varies with muscle mass, which can be significantly lower in HSCT patients, making SCr an inaccurate kidney function biomarker. Cystatin C (CysC) eGFR is independent of muscle mass, though steroid use increases CysC. Objectives of this study were to describe how eGFR impacts cefepime pharmacokinetic/pharmacodynamic (PK/PD) target attainment in pediatric HSCT patients, to investigate which method of estimating GFR (SCr, CysC, combined) best predicts cefepime clearance, and to explore additional predictors of cefepime clearance. Patients admitted to the pediatric HSCT unit who received ≥2 cefepime doses were prospectively enrolled. We measured total cefepime peak/trough concentrations between the second and fourth cefepime doses and measured SCr and CysC if not already obtained clinically within 24h of cefepime samples. eGFRs were calculated with Chronic Kidney Disease in Children U25 equations. Bayesian estimates of cefepime clearance were determined with a pediatric cefepime PK model and PK software MwPharm++. Simple linear regression was used to compare cefepime clearance normalized to body surface area (BSA) to BSA-normalized SCr-, CysC-, and SCr-/CysC-eGFRs, while multiple linear regression was used to account for additional predictors of cefepime clearance. For target attainment, we assessed the percentage of time free cefepime concentrations exceeded 1x MIC (%fT>1x MIC) and 4x MIC (%fT>4x MIC) using a susceptibility breakpoint of 8 mg/L for Pseudomonas aeruginosa. We enrolled 53 patients (ages 1 to 30 years, median 8.9 years). SCr- and CysC-eGFRs were lower in patients who attained 100% fT>1xMIC compared to those who did not attain this target: 115 versus 156 mL/min/1.73m (p = .01) for SCr-eGFR and 73.5 versus 107 mL/min/1.73m (p < .001) for CysC-eGFR. SCr-eGFR was weakly positively correlated with cefepime clearance (adjusted [a]r= 0.14), while CysC-eGFR and SCr-/CysC-eGFR had stronger positive correlations (ar = 0.30 CysC, ar = 0.28 combo. There was a weak, significant linear association between increasing CysC-eGFR and decreased %fT>1xMIC (ar = 0.32) and %fT>4xMIC (ar = 0.14). No patients with a CysC-eGFR >120 mL/min/1.73 m achieved 100% fT>1xMIC or 50% fT>4x MIC. In multiple regression models, underlying diagnosis of hemoglobinopathy (in all models) and being pretransplant (in SCr and combined models) were associated with increased cefepime clearance, while concomitant use of calcineurin inhibitors was associated with decreased cefepime clearance in all models. Overall, the combo-eGFR model with timing pretransplant, hemoglobinopathy, and use of calcineurin inhibitors had the best performance (ar = 0.63). CysC-based eGFRs (CysC alone and combined) predicted cefepime clearance better than SCr-eGFR, even after considering steroid use. Increasing CysC eGFR correlated with decreased probability of PD target attainment, raising concerns for underdosing at high eGFRs. CysC should be included when estimating kidney function to provide adequate dosing of cefepime in pediatric HSCT patients.
儿科造血干细胞移植(HSCT)患者有发生败血症和肾功能改变的风险。头孢吡肟用于HSCT后的经验性抗感染治疗,且需要根据肾功能调整剂量。由于头孢吡肟的抗菌疗效取决于游离浓度超过细菌最低抑菌浓度(MIC)的时间,准确评估肾功能以确保足够的浓度很重要。血清肌酐(SCr)通常用于估算肾小球滤过率(eGFR),但会因肌肉量而变化,HSCT患者的肌肉量可能显著较低,这使得SCr成为不准确的肾功能生物标志物。胱抑素C(CysC)eGFR独立于肌肉量,尽管使用类固醇会增加CysC。本研究的目的是描述eGFR如何影响儿科HSCT患者头孢吡肟的药代动力学/药效学(PK/PD)目标达成情况,研究哪种估算肾小球滤过率的方法(SCr、CysC、联合法)能最好地预测头孢吡肟清除率,并探索头孢吡肟清除率的其他预测因素。前瞻性纳入儿科HSCT病房中接受≥2剂头孢吡肟治疗的患者。我们在第二剂和第四剂头孢吡肟之间测量了头孢吡肟的总峰浓度/谷浓度,并在采集头孢吡肟样本后24小时内若未临床获取则测量SCr和CysC。使用儿童慢性肾脏病U25方程计算eGFR。用儿科头孢吡肟PK模型和PK软件MwPharm++确定头孢吡肟清除率的贝叶斯估计值。使用简单线性回归比较经体表面积(BSA)标准化的头孢吡肟清除率与经BSA标准化的SCr-、CysC-和SCr-/CysC-eGFR,同时使用多元线性回归分析头孢吡肟清除率的其他预测因素。对于目标达成情况,我们使用铜绿假单胞菌8 mg/L的药敏断点评估游离头孢吡肟浓度超过1倍MIC(%fT>1x MIC)和4倍MIC(%fT>4x MIC)的时间百分比。我们纳入了53例患者(年龄1至30岁,中位年龄8.9岁)。与未达到该目标的患者相比,达到100% fT>1xMIC的患者的SCr-和CysC-eGFR较低:SCr-eGFR为115对156 mL/min/1.73m²(p = 0.01),CysC-eGFR为73.5对107 mL/min/1.73m²(p < 0.001)。SCr-eGFR与头孢吡肟清除率呈弱正相关(调整后[a]r = 0.14),而CysC-eGFR和SCr-/CysC-eGFR具有更强的正相关(ar = 0.30 CysC,ar = 0.28联合法)。CysC-eGFR升高与%fT>1xMIC降低(ar = 0.32)和%fT>4xMIC降低(ar = 0.14)之间存在弱的显著线性关联。没有CysC-eGFR >120 mL/min/1.73 m²的患者达到100% fT>1xMIC或50% fT>4x MIC。在多元回归模型中,血红蛋白病的基础诊断(在所有模型中)和移植前状态(在SCr和联合模型中)与头孢吡肟清除率增加相关,而在所有模型中同时使用钙调神经磷酸酶抑制剂与头孢吡肟清除率降低相关。总体而言,包含移植前时间、血红蛋白病和钙调神经磷酸酶抑制剂使用情况评估指标的联合eGFR模型表现最佳(ar = 0.63)。即使考虑类固醇使用情况,基于CysC的eGFR(单独的CysC和联合法)预测头孢吡肟清除率比SCr-eGFR更好。CysC eGFR升高与PD目标达成概率降低相关,这引发了对高eGFR时剂量不足的担忧。在估算儿科HSCT患者肾功能时应纳入CysC,以确保头孢吡肟的剂量充足。
