Department of Radiology and Biomedical Imaging, Division of Interventional Radiology, Yale School of Medicine, 333 Cedar Street, New Haven, CT, 06520, USA.
Institute of Radiology, Charité - Universitätsmedizin Berlin, Freie Universität Berlin, Humboldt-Universität, and Berlin Institute of Health, Berlin, Germany.
Eur Radiol. 2021 May;31(5):3002-3014. doi: 10.1007/s00330-020-07380-w. Epub 2020 Oct 15.
To evaluate the prognostic potential of Lipiodol distribution for the pharmacokinetic (PK) profiles of doxorubicin (DOX) and doxorubicinol (DOXOL) after conventional transarterial chemoembolization (cTACE).
This prospective clinical trial ( ClinicalTrials.gov : NCT02753881) included 30 consecutive participants with liver malignancies treated with cTACE (5/2016-10/2018) using 50 mg DOX/10 mg mitomycin C emulsified 1:2 with ethiodized oil (Lipiodol). Peripheral blood was sampled at 10 timepoints for standard non-compartmental analysis of peak concentrations (C) and area under the curve (AUC) with dose normalization (DN). Imaging markers included Lipiodol distribution on post-cTACE CT for patient stratification into 1 segment (n = 10), ≥ 2 segments (n = 10), and lobar cTACE (n = 10), and baseline enhancing tumor volume (ETV). Adverse events (AEs) and tumor response on MRI were recorded 3-4 weeks post-cTACE. Statistics included repeated measurement ANOVA (RM-ANOVA), Mann-Whitney, Kruskal-Wallis, Fisher's exact test, and Pearson correlation.
Hepatocellular (n = 26), cholangiocarcinoma (n = 1), and neuroendocrine metastases (n = 3) were included. Stratified according to Lipiodol distribution, DOX-C increased from 1 segment (DOX-C, 83.94 ± 75.09 ng/mL; DN-DOX-C, 2.67 ± 2.02 ng/mL/mg) to ≥ 2 segments (DOX-C, 139.66 ± 117.73 ng/mL; DN-DOX-C, 3.68 ± 4.20 ng/mL/mg) to lobar distribution (DOX-C, 334.35 ± 215.18 ng/mL; DN-DOX-C, 7.11 ± 4.24 ng/mL/mg; p = 0.036). While differences in DN-DOX-AUC remained insignificant, RM-ANOVA revealed significant separation of time concentration curves for DOX (p = 0.023) and DOXOL (p = 0.041) comparing 1, ≥ 2 segments, and lobar cTACE. Additional indicators of higher DN-DOX-C were high ETV (p = 0.047) and Child-Pugh B (p = 0.009). High ETV and tumoral Lipiodol coverage also correlated with tumor response. AE occurred less frequently after segmental cTACE.
This prospective clinical trial provides updated PK data revealing Lipiodol distribution as an imaging marker predictive of DOX-C and tumor response after cTACE in liver cancer.
• Prospective pharmacokinetic analysis after conventional TACE revealed Lipiodol distribution (1 vs. ≥ 2 segments vs. lobar) as an imaging marker predictive of doxorubicin peak concentrations (C). • Child-Pugh B class and tumor hypervascularization, measurable as enhancing tumor volume (ETV) at baseline, were identified as additional predictors for higher dose-normalized doxorubicin C after conventional TACE. • ETV at baseline and tumoral Lipiodol coverage can serve as predictors of volumetric tumor response after conventional TACE according to quantitative European Association for the Study of the Liver (qEASL) criteria.
评估常规经动脉化疗栓塞术(cTACE)后碘化油分布对多柔比星(DOX)和多柔比星醇(DOXOL)药代动力学(PK)特征的预后潜力。
本前瞻性临床试验(ClinicalTrials.gov:NCT02753881)纳入了 30 例连续的接受 cTACE(2016 年 5 月至 2018 年 10 月)治疗的肝癌患者,采用 50mg DOX/10mg丝裂霉素 C 与乙碘油(Lipiodol)乳化 1:2。在给药后 10 个时间点采集外周血,进行标准非房室分析,计算峰浓度(C)和药时曲线下面积(AUC),并进行剂量归一化(DN)。影像学标志物包括 cTACE 后 CT 上的 Lipiodol 分布,用于将患者分为 1 个节段(n=10)、≥2 个节段(n=10)和叶状 cTACE(n=10),以及基线增强肿瘤体积(ETV)。记录 cTACE 后 3-4 周的不良反应(AE)和肿瘤反应。统计学分析包括重复测量方差分析(RM-ANOVA)、Mann-Whitney、Kruskal-Wallis、Fisher 确切检验和 Pearson 相关性分析。
纳入了肝细胞癌(n=26)、胆管细胞癌(n=1)和神经内分泌转移瘤(n=3)。根据 Lipiodol 分布分层,DOX-C 从 1 个节段(DOX-C,83.94±75.09ng/mL;DN-DOX-C,2.67±2.02ng/mL/mg)增加到≥2 个节段(DOX-C,139.66±117.73ng/mL;DN-DOX-C,3.68±4.20ng/mL/mg)和叶状分布(DOX-C,334.35±215.18ng/mL;DN-DOX-C,7.11±4.24ng/mL/mg;p=0.036)。尽管 DN-DOX-AUC 的差异仍无统计学意义,但 RM-ANOVA 显示 DOX(p=0.023)和 DOXOL(p=0.041)的时间浓度曲线存在显著分离,比较了 1 个节段、≥2 个节段和叶状 cTACE。DN-DOX-C 较高的其他指标是高 ETV(p=0.047)和 Child-Pugh B 级(p=0.009)。高 ETV 和肿瘤 Lipiodol 覆盖率也与肿瘤反应相关。节段性 cTACE 后 AE 发生频率较低。
本前瞻性临床试验提供了更新的 PK 数据,表明 Lipiodol 分布作为影像学标志物,可预测肝癌 cTACE 后的 DOX-C 和肿瘤反应。
常规 TACE 后前瞻性 PK 分析显示,Lipiodol 分布(1 个 vs. ≥2 个节段 vs. 叶状)可作为预测多柔比星峰浓度(C)的影像学标志物。
Child-Pugh B 级和肿瘤高血管化,以基线时增强肿瘤体积(ETV)为衡量标准,被确定为常规 TACE 后更高剂量归一化多柔比星 C 的额外预测因素。
根据欧洲肝脏研究协会(EASL)的定量标准(qEASL),基线 ETV 和肿瘤 Lipiodol 覆盖率可作为常规 TACE 后肿瘤体积反应的预测指标。
