通过联合使用母体和 MET 酪氨酸激酶抑制剂治疗转移性癌基因驱动 NSCLC 患者获得性 MET 抗药性的有效性和安全性

IF 3 Q2 ONCOLOGY
Tejas Patil MD , Alyse Staley MS , Yunan Nie MD , Mandy Sakamoto MD , Margaret Stalker MD , James M. Jurica MD, MBA , Kenna Koehler BA , Amanda Cass PharmD , Halle Kuykendall BA , Emily Schmitt MS , Emma Filar BA , Evelina Reventaite MS , Kurt D. Davies PhD , Hala Nijmeh PhD , Mary Haag PhD , Benjamin A. Yoder PharmD , Paul A. Bunn MD , Erin L. Schenk MD, PhD , Dara L. Aisner MD, PhD , Wade T. Iams MD , D. Ross Camidge MD, PhD
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The efficacy and safety of combining MET TKIs (such as crizotinib, capmatinib, or tepotinib) with parent TKIs to target acquired MET resistance are not well characterized.</p></div><div><h3>Methods</h3><p>Multi-institutional retrospective chart review identified 83 patients with metastatic oncogene-driven NSCLC that were separated into the following two pairwise matched cohorts: (1) MET cohort (n = 41)—patients with acquired MET resistance continuing their parent TKI with a MET TKI added or (2) Chemotherapy cohort (n = 42)—patients without any actionable resistance continuing their parent TKI with a platinum-pemetrexed added. Clinicopathologic features, radiographic response (by means of Response Evaluation Criteria in Solid Tumors version 1.1), survival outcomes, adverse events (AEs) (by means of Common Terminology Criteria for Adverse Events version 5.0), and genomic data were collected. Survival outcomes were assessed using Kaplan-Meier methods. 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Within the MET cohort, <em>MET</em> gene copy number (≥10 versus 6–10) did not affect radiographic response (54.5% versus 68.4%, <em>p</em> = 0.698). There was no difference in ORR on the basis of MET TKI used (F [2, 36] = 0.021, <em>p</em> = 0.978). There was no difference in progression-free survival (5 versus 6 mo; hazard ratio = 0.64; 95% confidence interval: 0.34–1.23, <em>p</em> = 0.18) or overall survival (13 versus 11 mo; hazard ratio = 0.75; 95% confidence interval: 0.42–1.35, <em>p</em> = 0.34) between the MET and chemotherapy cohorts. In the MET cohort, dose reductions for MET TKI-related toxicities were common (17 of 41, 41.4%) but less frequent for parent TKIs (two of 41, 5%). Grade 3 AEs were not significant between crizotinib, capmatinib, and tepotinib (<em>p</em> = 0.3). The discontinuation rate of MET TKIs was 17% with no significant differences between MET TKIs (<em>p</em> = 0.315). 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引用次数: 0

摘要

导言:获得性MET基因扩增、MET第14外显子跳越突变或MET融合可能成为肺癌患者对酪氨酸激酶抑制剂(TKIs)的耐药机制。将MET TKIs(如克唑替尼、卡马替尼或替泊替尼)与母体TKIs联合用于靶向获得性MET耐药的疗效和安全性还没有很好的定性:(1)MET队列(n = 41)--获得性MET耐药患者,继续使用原TKI,并添加MET TKI;或(2)化疗队列(n = 42)--无任何可作用耐药患者,继续使用原TKI,并添加铂-培美曲塞。研究人员收集了临床病理特征、放射学反应(采用实体瘤反应评估标准 1.1 版)、生存结果、不良事件(采用不良事件通用术语标准 5.0 版)和基因组数据。生存结果采用 Kaplan-Meier 方法进行评估。多变量模型对治疗方法、脑转移、TP53突变和少转移性疾病进行了调整。结果在MET队列中,中位年龄为56岁(范围:36-83岁)。大多数患者从不吸烟(41 人中有 28 人,占 68.3%)。基线脑转移很常见(41 例中有 21 例,占 51%)。MET队列中最常见的癌基因是表皮生长因子受体(41例中有30例,占73.2%)、ALK(41例中有7例,占17.1%)和ROS1(41例中有2例,占4.9%)。同时发生的 TP53 突变(41 例中有 32 例,占 78%)也很常见。获得性MET改变包括MET基因扩增(41例中有37例,占90%)、MET第14外显子突变(41例中有2例,占5%)和MET基因融合(41例中有2例,占5%)。经多变量调整后,MET队列的客观反应率(ORR)高于化疗队列(ORR:69.2%对20%,P< 0.001)。在 MET 队列中,MET 基因拷贝数(≥10 对 6-10)不影响放射学反应(54.5% 对 68.4%,p = 0.698)。所使用的 MET TKI 在 ORR 方面没有差异(F [2, 36] = 0.021,p = 0.978)。MET队列和化疗队列之间的无进展生存期(5个月对6个月;危险比=0.64;95%置信区间:0.34-1.23,p=0.18)或总生存期(13个月对11个月;危险比=0.75;95%置信区间:0.42-1.35,p=0.34)没有差异。在MET队列中,因MET TKI相关毒性而减少剂量的情况很常见(41例中有17例,占41.4%),但母体TKI相关毒性减少剂量的情况较少(41例中有2例,占5%)。克唑替尼、卡帕替尼和泰泊替尼之间的 3 级 AE 无显著差异(p = 0.3)。MET TKIs的停药率为17%,不同MET TKIs之间无显著差异(p = 0.315)。在 MET 队列的治疗前和治疗后活检(n = 17)中,最常见的新一代测序结果是 MET 基因扩增缺失(17 例中有 15 例,占 88.2%)、MET 靶向突变(17 例中有 7 例,占 41.结论将MET TKIs(克唑替尼、卡马替尼或替泊替尼)与母体TKIs联合治疗获得性MET耐药的疗效和安全性是有效的。所使用的基础 MET TKI 在放射学反应和 AEs 方面没有显著差异。MET基因扩增缺失、MET靶上突变、Ras-Raf-MAPK改变和表皮生长因子受体(EGFR)基因扩增是双亲TKI和MET TKI联合治疗进展时发现的分子模式。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
The Efficacy and Safety of Treating Acquired MET Resistance Through Combinations of Parent and MET Tyrosine Kinase Inhibitors in Patients With Metastatic Oncogene-Driven NSCLC

Introduction

Acquired MET gene amplification, MET exon 14 skip mutations, or MET fusions can emerge as resistance mechanisms to tyrosine kinase inhibitors (TKIs) in patients with lung cancer. The efficacy and safety of combining MET TKIs (such as crizotinib, capmatinib, or tepotinib) with parent TKIs to target acquired MET resistance are not well characterized.

Methods

Multi-institutional retrospective chart review identified 83 patients with metastatic oncogene-driven NSCLC that were separated into the following two pairwise matched cohorts: (1) MET cohort (n = 41)—patients with acquired MET resistance continuing their parent TKI with a MET TKI added or (2) Chemotherapy cohort (n = 42)—patients without any actionable resistance continuing their parent TKI with a platinum-pemetrexed added. Clinicopathologic features, radiographic response (by means of Response Evaluation Criteria in Solid Tumors version 1.1), survival outcomes, adverse events (AEs) (by means of Common Terminology Criteria for Adverse Events version 5.0), and genomic data were collected. Survival outcomes were assessed using Kaplan-Meier methods. Multivariate modeling adjusted for lines of therapy, brain metastases, TP53 mutations, and oligometastatic disease.

Results

Within the MET cohort, median age was 56 years (range: 36–83 y). Most patients were never smokers (28 of 41, 68.3%). Baseline brain metastases were common (21 of 41, 51%). The most common oncogenes in the MET cohort were EGFR (30 of 41, 73.2%), ALK (seven of 41, 17.1%), and ROS1 (two of 41, 4.9%). Co-occurring TP53 mutations (32 of 41, 78%) were frequent. Acquired MET alterations included MET gene amplification (37 of 41, 90%), MET exon 14 mutations (two of 41, 5%), and MET gene fusions (two of 41, 5%). After multivariate adjustment, the objective response rate (ORR) was higher in the MET cohort versus the chemotherapy cohort (ORR: 69.2% versus 20%, p < 0.001). Within the MET cohort, MET gene copy number (≥10 versus 6–10) did not affect radiographic response (54.5% versus 68.4%, p = 0.698). There was no difference in ORR on the basis of MET TKI used (F [2, 36] = 0.021, p = 0.978). There was no difference in progression-free survival (5 versus 6 mo; hazard ratio = 0.64; 95% confidence interval: 0.34–1.23, p = 0.18) or overall survival (13 versus 11 mo; hazard ratio = 0.75; 95% confidence interval: 0.42–1.35, p = 0.34) between the MET and chemotherapy cohorts. In the MET cohort, dose reductions for MET TKI-related toxicities were common (17 of 41, 41.4%) but less frequent for parent TKIs (two of 41, 5%). Grade 3 AEs were not significant between crizotinib, capmatinib, and tepotinib (p = 0.3). The discontinuation rate of MET TKIs was 17% with no significant differences between MET TKIs (p = 0.315). Among pre- and post-treatment biopsies (n = 17) in the MET cohort, the most common next-generation sequencing findings were loss of MET gene amplification (15 of 17, 88.2%), MET on-target mutations (seven of 17, 41.2%), new Ras-Raf-MAPK alterations (three of 17, 17.6%), and EGFR gene amplification (two of 17, 11.7%).

Conclusions

The efficacy and safety of combining MET TKIs (crizotinib, capmatinib, or tepotinib) with parent TKIs for acquired MET resistance are efficacious. Radiographic response and AEs did not differ significantly on the basis of the underlying MET TKI used. Loss of MET gene amplification, development of MET on-target mutations, Ras-Raf-MAPK alterations, and EGFR gene amplification were molecular patterns found on progression with dual parent and MET TKI combinations.

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