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A combination of tyrosine kinase inhibitors (TKIs) is likely to be a therapeutic option for numerous oncological situations due to high frequency of oncogenic addiction and progress in precision oncology. Non-small cell lung cancer (NSCLC) represents a subtype of tumors for which oncogenic drivers are frequently involved. To the best of our knowledge, we report the first case of a patient treated with three different TKIs. Osimertinib and crizotinib were administered concurrently for an epidermal growth factor receptor (EGFR)-mutated NSCLC developing a MET amplification as a resistance mechanism to osimertinib. Simultaneously, imatinib was administered for a metastatic gastrointestinal stromal tumor. The progression-free survival was 7 months for both tumors with this tritherapy. The use of therapeutic drug monitoring to assess plasma concentrations of each TKI was a powerful tool to manage the toxicity profile of this combination (creatine phosphokinase elevation) while preserving an optimal exposure to each TKI and treatment efficacy. We observed an imatinib over-exposition related to crizotinib introduction, probably explained by drug–drug interaction mediated by crizotinib enzymatic inhibition on cytochrome P-450 3A4. Posology adjustment due to therapeutic drug monitoring was probably involved in the good survival outcome of the patient. This tool should be used more routinely for patients treated by TKIs to prevent co-treatment interactions and, in particular, for patients receiving TKI combinations to obtain optimal therapeutic exposure and efficacy while reducing possible side-effects.

In an interim analysis of a trial involving 296 patients with ALK -positive non–small-cell lung cancer, lorlatinib, an anaplastic lymphoma kinase inhibitor, was superior to crizotinib in response (in 76% vs. 58%), 12-month progression-free survival (78% vs. 39%), and intracranial disease response (82% vs. 23%). Altered lipid levels were the major toxic effect associated with lorlatinib.

MET exon 14 alterations are oncogenic drivers of non-small-cell lung cancers (NSCLCs) 1 . These alterations are associated with increased MET activity and preclinical sensitivity to MET inhibition 2 . Crizotinib is a multikinase inhibitor with potent activity against MET 3 . The antitumor activity and safety of crizotinib were assessed in 69 patients with advanced NSCLCs harboring MET exon 14 alterations. Objective response rate was 32% (95% confidence interval (CI), 21–45) among 65 response-evaluable patients. Objective responses were observed independent of the molecular heterogeneity that characterizes these cancers and did not vary by splice-site region and mutation type of the MET exon 14 alteration, concurrent increased MET copy number or the detection of a MET exon 14 alteration in circulating tumor DNA. The median duration of response was 9.1 months (95% CI, 6.4–12.7). The median progression-free survival was 7.3 months (95% CI, 5.4–9.1). MET exon 14 alteration defines a molecular subgroup of NSCLCs for which MET inhibition with crizotinib is active. These results address an unmet need for targeted therapy in people with lung cancers with MET exon 14 alterations and adds to an expanding list of genomically driven therapies for oncogenic subsets of NSCLC. Results from an expansion cohort of the PROFILE 1001 trial describe the anti-tumor activity of crizotinib in people with non-small-cell lung cancer harboring a MET exon 14 alteration.

In a randomized trial involving patients with ALK -rearranged lung cancer, brigatinib was associated with longer progression-free survival and more activity against central nervous system disease than crizotinib.

ALK gene rearrangement was observed in 3%–5% of non-small cell lung cancer patients, and multiple ALK-tyrosine kinase inhibitors (TKIs) have been sequentially used. Multiple ALK-TKI resistance mutations have been identified from the patients, and several compound mutations, such as I1171N + F1174I or I1171N + L1198H are resistant to all the approved ALK-TKIs. In this study, we found that gilteritinib has an inhibitory effect on ALK-TKI–resistant single mutants and I1171N compound mutants in vitro and in vivo. Surprisingly, EML4-ALK I1171N + F1174I compound mutant-expressing tumors were not completely shrunk but regrew within a short period of time after alectinib or lorlatinib treatment. However, the relapsed tumor was markedly shrunk after switching to the gilteritinib in vivo model. In addition, gilteritinib was effective against NTRK -rearranged cancers including entrectinib-resistant NTRK1 G667C-mutant and ROS1 fusion-positive cancer. Resistance to ALK inhibitors such as lorlatinib often arise due to on-target mutations. Here, the authors show the multi-kinase inhibitor gilteritinib is effective against different mutations that arise during lorlatinib in ALK fusion positive lung cancer to cause resistance.

Anaplastic lymphoma kinase (ALK) gene activation is involved in the carcinogenesis process of several human cancers such as anaplastic large cell lymphoma, lung cancer, inflammatory myofibroblastic tumors and neuroblastoma, as a consequence of fusion with other oncogenes (NPM, EML4, TIM, etc) or gene amplification, mutation or protein overexpression. ALK is a transmembrane tyrosine kinase receptor that, upon ligand binding to its extracellular domain, undergoes dimerization and subsequent autophosphorylation of the intracellular kinase domain. When activated in cancer it represents a target for specific inhibitors, such as crizotinib, ceritinib, alectinib etc. which use has demonstrated significant effectiveness in ALK-positive patients, in particular ALK-positive non- small cell lung cancer. Several mechanisms of resistance to these inhibitors have been described and new strategies are underway to overcome the limitations of current ALK inhibitors.

Molecular agents targeting the epidermal growth factor receptor (EGFR)‐, anaplastic lymphoma kinase (ALK)‐ or c‐ros oncogene 1 (ROS1) alterations have revolutionized the treatment of oncogene‐driven non‐small‐cell lung cancer (NSCLC). However, the emergence of acquired resistance remains a significant challenge, limiting the wider clinical success of these molecular targeted therapies. In this study, we investigated the efficacy of various molecular targeted agents, including erlotinib, alectinib, and crizotinib, combined with anti‐vascular endothelial growth factor receptor (VEGFR) 2 therapy. The combination of VEGFR2 blockade with molecular targeted agents enhanced the anti‐tumor effects of these agents in xenograft mouse models of EGFR‐, ALK‐, or ROS1‐altered NSCLC. The numbers of CD31‐positive blood vessels were significantly lower in the tumors of mice treated with an anti‐VEGFR2 antibody combined with molecular targeted agents compared with in those of mice treated with molecular targeted agents alone, implying the antiangiogenic effects of VEGFR2 blockade. Additionally, the combination therapies exerted more potent antiproliferative effects in vitro in EGFR‐, ALK‐, or ROS1‐altered NSCLC cells, implying that VEGFR2 inhibition also has direct anti‐tumor effects on cancer cells. Furthermore, VEGFR2 expression was induced following exposure to molecular targeted agents, implying the importance of VEGFR2 signaling in NSCLC patients undergoing molecular targeted therapy. In conclusion, VEGFR2 inhibition enhanced the anti‐tumor effects of molecular targeted agents in various oncogene‐driven NSCLC models, not only by inhibiting tumor angiogenesis but also by exerting direct antiproliferative effects on cancer cells. Hence, combination therapy with anti‐VEGFR2 antibodies and molecular targeted agents could serve as a promising treatment strategy for oncogene‐driven NSCLC. We found that VEGFR2 blockade augmented the anti‐tumor effects of molecular targeted agents in oncogene‐driven NSCLC, particularly in EGFR/ALK/ROS1‐driven NSCLC. We also identified 2 mechanisms underlying the synergistic effects of anti‐VEGFR2 therapy with molecular targeted agents. VEGFR2 blockade not only inhibited tumor angiogenesis but also exerted direct antiproliferative effects on cancer cells.

Abstract Background Intrahepatic cholangiocarcinoma is a malignant tumor that starts from the epithelium of the bile duct and has a poor prognosis. They are characterized by poor response to chemotherapy and lack of effective targeted therapies; thus, therapeutic options are limited. Case Presentation A 59-year-old man was admitted to the hospital for a workup of abnormal CA19-9 levels. He was diagnosed with ICC, underwent surgery and was found to have pT1bNx disease. He developed rapid disease recurrence on adjuvant gemcitabine + capecitabine. Following recurrence, he received first-line systemic pembrolizumab + lenvatinib and second-line pembrolizumab + lenvatinib + chemotherapy and had mild tumor regression followed by progression. Next-generation sequencing was performed on the baseline surgical sample. This revealed a novel RBPMS-MET fusion, and based on the literature, crizotinib 250 mg twice a day was administered. After 3 months of crizotinib treatment, magnetic resonance imaging revealed a significant reduction in liver lesions, and 4 months after initiating treatment, scans demonstrated a partial response. Conclusion Our case report strengthens the evidence that crizotinib may be a viable treatment option for patients with ICC with a c-MET tyrosine kinase fusion, necessitating additional clinical investigation.

The treatment for anaplastic lymphoma kinase (ALK)‐positive lung cancer has been rapidly evolving since the introduction of several ALK tyrosine kinase inhibitors (ALK‐TKI) in clinical practice. However, the acquired resistance to these drugs has become an important issue. In this study, we collected a total of 112 serial biopsy samples from 32 patients with ALK‐positive lung cancer during multiple ALK‐TKI treatments to reveal the resistance mechanisms to ALK‐TKI. Among 32 patients, 24 patients received more than two ALK‐TKI. Secondary mutations were observed in 8 of 12 specimens after crizotinib failure (G1202R, G1269A, I1171T, L1196M, C1156Y and F1245V). After alectinib failure, G1202R and I1171N mutations were detected in 7 of 15 specimens. G1202R, F1174V and G1202R, and P‐gp overexpression were observed in 3 of 7 samples after ceritinib treatment. L1196M + G1202R, a compound mutation, was detected in 1 specimen after lorlatinib treatment. ALK‐TKI treatment duration was longer in the on‐target treatment group than that in the off‐target group (13.0 vs 1.2 months). In conclusion, resistance to ALK‐TKI based on secondary mutation in this study was similar to that in previous reports, except for crizotinib resistance. Understanding the appropriate treatment matching resistance mechanisms contributes to the efficacy of multiple ALK‐TKI treatment strategies. Anaplastic lymphoma kinase (ALK)‐positive lung cancer accounts for 3%–5% of all non–small cell lung cancer cases. The use of ALK tyrosine kinase inhibitors (ALK‐TKI) is highly effective and four ALK‐TKI have been approved in Japan. However, ALK‐TKI lose their efficacy because of acquired resistance. In this study, we analyzed “real world” resistance mechanisms using serial tumor biopsies during sequential treatment with ALK‐TKI in Japanese patients with ALK‐positive lung cancer and revealed the sequential transition of resistance mechanisms. The identification of resistance mechanisms revealed that the precise utilization of ALK‐TKI based on resistance mechanisms will have potential benefits in patients with ALK‐positive lung cancer in clinical settings.

Abstract With the widespread use of next-generation sequencing (NGS) for solid tumors, mesenchymal-to-epithelial transition factor (MET) rearrangement/fusion has been confirmed in multiple cancer types. MET amplification and MET exon 14 skipping mutations induce protein autophosphorylation; however, the pathogenic mechanism and drug sensitivity of MET fusion remain unclear. The following report describes the clinical case of a patient diagnosed with squamous lung cancer bearing a TFG-MET gene fusion. In vitro assays demonstrated MET phosphorylation and oncogenic capacity due to the TFG-MET rearrangement, both of which were inhibited by crizotinib treatment. The patient was treated with crizotinib, which resulted in sustained partial remission for more than 17 months. Collectively, cellular analyses and our case report emphasize the potential of MET fusion as a predictive biomarker for personalized target therapy for solid tumors. The following report describes the clinical case of a patient diagnosed with squamous lung cancer bearing a TFG-MET gene fusion, emphasizing the potential of MET fusion as a predictive biomarker for personalized target therapy for solid tumors.