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Ji-Youn Han



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    GR 02 - Management of Immunotherapy-Related Adverse Events (ID 521)

    • Event: WCLC 2017
    • Type: Grand Rounds
    • Track: Immunology and Immunotherapy
    • Presentations: 1
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      GR 02.03 - Pathophysiology of Immunotherapy-related Toxicity (ID 7631)

      11:00 - 12:30  |  Presenting Author(s): Ji-Youn Han

      • Abstract
      • Presentation
      • Slides

      Abstract:
      Clinical development and approval of immune-checkpoint inhibitors have transformed the treatment of many types of tumors. In recent years, three anti-PD-1 or –PD-L1 antibodies have been approved for advanced NSCLC, including nivolumab, pembrolizumab, and atezolizumab. These antibodies have entered into the routine practice of treatment for patients with advanced NSCLC. In addition, all clinical trials, which compared the efficacy of anti-PD-1 or PD-L1 antibodies with chemotherapy, demonstrated that these antibodies are less toxic than chemotherapy (1-4). However, these immunomodulatory antibodies have led to the emergence of unusual autoimmune toxicities, also called immune-related adverse events (IrAEs). IrAEs management is challenging because they may concern many organ systems, including the skin, hepatic, gastrointestinal, endocrine, and pulmonary systems. Furthermore, given the recent success of immunotherapy, the incidence of immunotoxicity will likely continue to rise as these therapies become more widely used not only in advanced diseases but also in early stage diseases (5). Treatment-related toxicities have correlated with better response in some cases, and it is probable that serious adverse events from immune-mediated reaction will increase as immunotherapeutic approaches become more effective (6). Adding more complexity, the natural history of certain irAEs is unpredictable. The onset of clinical disease manifestation can vary from weeks to decades after the appearance of autoantibodies (7). Thus understanding irAEs is critical for early detection and appropriate management of patients. We will discuss the mechanisms that might be related with the induction of anutoimmunity from immunotherapy. References: Lancet. 2016; 387(10027):1540-50. N Engl J Med. 2015;373(2):123-35. N Engl J Med. 2015; 373(17):1627-39. Lancet. 2016;387(10030):1837-46. Eur J Cancer. 2016 ;54:139-48. Blood. 2011;118(3):499-509. Nat Med. 2017 ;23(5):540-547.

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    MA 10 - Immunotherapy I (ID 664)

    • Event: WCLC 2017
    • Type: Mini Oral
    • Track: Immunology and Immunotherapy
    • Presentations: 1
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      MA 10.03 - 3-Year Survival and Duration of Response in Randomized Phase II Study of Atezolizumab vs Docetaxel in 2L/3L NSCLC (POPLAR) (ID 8703)

      11:00 - 12:30  |  Author(s): Ji-Youn Han

      • Abstract
      • Presentation
      • Slides

      Background:
      Atezolizumab (anti–PD-L1) has demonstrated OS benefit over docetaxel in a randomized Phase II study, POPLAR, in patients with advanced NSCLC. This benefit has been confirmed in the randomized Phase III study OAK (Rittmeyer, 2017). The 3-year survival analysis of the POPLAR study presented here describes the longest survival follow-up reported to date of an all-comer randomized PD-L1/PD-1 immunotherapy trial in 2L+ NSCLC.

      Method:
      Patients were randomized 1:1 to receive atezolizumab (1200 mg) or docetaxel (75 mg/m[2]) IV q3w. Tumors were prospectively evaluated for tumor cell (TC) or tumor-infiltrating immune cell (IC) PD-L1 expression using the VENTANA SP142 IHC assay. Landmark OS was estimated using the Kaplan-Meier method. Data cutoff, April 7, 2017; minimum follow-up, 3 years.

      Result:
      The 2-year and 3-year survival with atezolizumab vs docetaxel were 32.2% vs 16.6% and 18.7% vs 10.0%, respectively. The long-term OS benefit of atezolizumab vs docetaxel was observed across histology and PD-L1 expression subgroups (Table). While the TC3 or IC3 subgroup derived the greatest OS benefit, the TC0 and IC0 subgroup also had improved long-term OS with atezolizumab vs docetaxel. The ITT ORR was 15% in both atezolizumab and docetaxel arms, but the median duration of response was 3 times longer with atezolizumab (22.3 months [95% CI: 11.6, 31.1] vs 7.2 months [95% CI: 5.8, 12.2] with docetaxel). Seven of the 11 docetaxel-arm 3-year survivors received subsequent non-protocol therapy with anti–PD-L1/PD-1 agents. Atezolizumab had a favorable safety profile compared with docetaxel that was consistent with previous reports.

      Conclusion:
      Atezolizumab demonstrates superior 2-year and 3-year OS benefit compared with docetaxel, and this benefit is observed across histology and PD-L1 expression subgroups (including TC0 and IC0). Atezolizumab is well tolerated, and responses are highly durable. These results are consistent with long-term OS results from OAK, presented separately.

      Table. Landmark OS in the ITT, PD-L1 expression, and histology subgroups in POPLAR
      Population (n, atezolizumab vs docetaxel) 2-year OS rate, % 3-year OS rate, %
      Atezolizumab Docetaxel P value[a] Atezolizumab Docetaxel P value[a]
      ITT (144 vs 143) 32.2% 16.6% 0.0027 18.7% 10.0% 0.0419
      PD-L1 Expression Subgroups
      TC3 or IC3 (24 vs 23) 41.7% 19.9% 0.1003 37.5% 14.9% 0.0724
      TC2/3 or IC2/3 (50 vs 55) 36.1% 13.8% 0.0082 21.2% 9.9% 0.1166
      TC1/2/3 or IC1/2/3 (93 vs 102) 36.0% 19.8% 0.0124 18.0% 11.0% 0.1759
      TC0 and IC0 (51 vs 41) 25.0% 6.8% 0.0202 20.5% 6.8% 0.0693
      Histology Subgroups
      Non-squamous (95 vs 95) 32.2% 21.1% 0.0960 23.3% 12.4% 0.0585
      Squamous (49 vs 48) 32.7% 7.8% 0.0020 9.4% 5.2% 0.4603
      [a ]For descriptive purpose only. TC3 or IC3 = PD-L1 ≥ 50% TC or 10% IC; TC2/3 or IC2/3 = PD-L1 ≥ 5% TC or IC; TC1/2/3 or IC1/2/3 = PD-L1 ≥ 1% on TC or IC; TC0 and IC0 = PD-L1 < 1% on TC and IC. NCT01903993.


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    OA 09 - EGFR TKI Resistance (ID 663)

    • Event: WCLC 2017
    • Type: Oral
    • Track: Advanced NSCLC
    • Presentations: 1
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      OA 09.03 - TATTON Ph Ib Expansion Cohort: Osimertinib plus Savolitinib for Pts with EGFR-Mutant MET-Amplified NSCLC after Progression on Prior EGFR-TKI (ID 8985)

      11:00 - 12:30  |  Author(s): Ji-Youn Han

      • Abstract
      • Presentation
      • Slides

      Background:
      MET amplification is a well described mechanism of acquired resistance to EGFR inhibition in EGFR-mutant NSCLC, making combined MET/EGFR inhibition a compelling therapeutic approach. We previously reported tolerability of the oral, CNS active, third-generation EGFR-TKI osimertinib, which is selective for both EGFR-TKI sensitizing and EGFR T790M resistance mutations, combined with the highly selective MET-TKI savolitinib (volitinib, HMPL-504, AZD6094). Here we assess safety and preliminary activity of this combination in a cohort of patients (pts) with EGFR-mutant NSCLC and MET-positive acquired resistance in the multi-arm, Phase Ib TATTON study (NCT02143466).

      Method:
      Eligible pts were aged ≥18 years (WHO performance status 0/1) with locally advanced or metastatic EGFR-mutant NSCLC who progressed on at least one prior EGFR-TKI with centrally confirmed MET-amplification (fluorescence in-situ hybridisation, MET gene copy ≥5 or MET/CEP7 ratio ≥2). Pts received osimertinib 80 mg QD plus savolitinib 600 mg QD. Primary objective was safety and tolerability; secondary objectives included preliminary assessment of anti-tumour activity and pharmacokinetics.

      Result:
      As of data-cut off (15 April 2017), 45 pts with centrally confirmed MET-amplification (FISH) were enrolled and received treatment, including 25 pts previously treated with a third-generation EGFR-TKI and 20 without prior third-generation EGFR-TKI treatment (T790M negative n=13; T790M positive n=7). At baseline, median age was 58 years (range 38–76), 24 (53%) were female, 36 (80%) were Asian. The most frequent adverse events (AEs) were nausea (n=21, 47%), decreased appetite (n=15, 33%), fatigue (n=13, 29%) vomiting (n=13, 29%), rash (n=11, 24%), myalgia (n=8, 18%), pyrexia (n=7, 16%), ALT/AST increased (n=6, 13%), and WBC decreased (n=6, 13%), consistent with the known safety profiles. Serious AEs were reported in 15 (33%) pts; events reported in >1 patient were pneumonia, dyspnoea, acute kidney injury and pyrexia (all n=2). Four pts died due to AEs, none were considered related to study drugs. At data cut-off, confirmed partial responses were reported in 5/25 (20%) pts previously treated with a third-generation EGFR-TKI; 5/12 (42%) T790M negative pts without prior third-generation EGFR-TKI and 3/7 (43%) T790M positive pts without prior third-generation EGFR‑TKI. Twenty-eight (62%) pts are ongoing treatment. Preliminary steady-state exposures and pharmacokinetic parameters of savolitinib and osimertinib were consistent with historical data.

      Conclusion:
      These findings demonstrate promising safety, tolerability, and preliminary activity of osimertinib plus savolitinib and support further investigation of this combination for the treatment of pts with locally advanced or metastatic EGFR-mutant NSCLC and MET-amplification. Updated data will be presented.

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    OA 10 - Liquid Biopsy for Genomic Alterations (ID 678)

    • Event: WCLC 2017
    • Type: Oral
    • Track: Advanced NSCLC
    • Presentations: 1
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      OA 10.01 - Detection of EGFR mutations from plasma ctDNA in the osimertinib Phase III trial (AURA3): comparison of three plasma assays (ID 8984)

      11:00 - 12:30  |  Author(s): Ji-Youn Han

      • Abstract
      • Presentation
      • Slides

      Background:
      AURA3 (NCT02151981) showed osimertinib, a third-generation EGFR-TKI, significantly prolongs progression‑free survival and improves response rate vs platinum‑pemetrexed in patients with T790M-positive advanced NSCLC, whose tumors had progressed on first-line EGFR-TKI therapy. Using patient baseline samples, we report concordance between plasma circulating tumor DNA (ctDNA) and tissue for the detection of EGFR mutations (T790M, exon 19 deletions [Ex19Del], L858R) using three distinct plasma detection technologies.

      Method:
      Tumor tissue biopsy samples were taken following progression on first-line EGFR‑TKI treatment. Baseline central confirmation of EGFR mutation status was by cobas[®] EGFR Mutation Test (Roche Molecular Systems). Where possible, baseline blood samples for plasma ctDNA screening were collected from patients in the osimertinib treatment group and analyzed using allele specific (AS)‑PCR (cobas[®] EGFR Mutation Test v2), ddPCR (Biodesix) and next generation sequencing (NGS, Guardant Health).

      Result:
      Figure 1 ctDNA was undetectable (negative for all three EGFR mutations [T790M, Ex19Del, L858R]) in 51/228 (22%) patients by AS-PCR, 58/211 (27%) by ddPCR, and 54/230 (23%) by NGS. Robust correlations (Spearman’s Rank) were observed for EGFR mutant allelic fractions (AFs) between ddPCR and NGS assays: T790M R[2] 0.9129 (n=201), Ex19Del R[2] 0.9384 (n=201), L858R R[2] 0.8090 (n=200). Discordant results between ddPCR and NGS were observed in 24/201 (12%) samples for T790M, 17/201 (8%) Ex19Del and 11/200 (6%) L858R. All discordant samples had AFs ≤1% by both assays.



      Conclusion:
      Using cobas tissue test as a reference, sensitivity for the detection of plasma T790M appeared higher for ddPCR and NGS assays compared with AS-PCR. Robust correlations were observed between quantitative ddPCR and NGS assays for determination of AFs across all three mutations. About 25% of AURA3 patients did not appear to shed ctDNA, as evidenced by absence of all three EGFR mutations across the three platforms.

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    OA 17 - Immunotherapy II (ID 683)

    • Event: WCLC 2017
    • Type: Oral
    • Track: Immunology and Immunotherapy
    • Presentations: 1
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      OA 17.07 - Long-Term Survival in Atezolizumab-Treated Patients with 2L+ NSCLC from Ph III Randomized OAK Study (ID 8663)

      14:30 - 16:15  |  Author(s): Ji-Youn Han

      • Abstract
      • Presentation
      • Slides

      Background:
      Atezolizumab (anti–PD-L1) inhibits PD-L1 binding to PD-1 and B7.1, restoring anti-cancer immunity. OAK, a Phase III study of atezolizumab vs docetaxel demonstrated superior OS of atezolizumab. The characteristics of the long-term survivors (LTS) in the OAK primary population (n = 850) are evaluated and describe the largest cohort of cancer immunotherapy-treated NSCLC LTS yet reported.

      Method:
      Patients received IV q3w atezolizumab (1200 mg) until PD / loss of clinical benefit or docetaxel (75 mg/m[2]) until PD / unacceptable toxicity. No crossover was allowed. LTS were defined as patients with OS ≥ 24 months and non-LTS as those who died within 24 months of randomization. Patients with OS censored prior to 24 months were not included. Data cutoff, January 23, 2017.

      Result:
      A higher 2-year survival rate was observed for the atezolizumab-arm (31%) vs docetaxel-arm (21%). After a minimum follow-up of 26 months, there were 119 LTS vs 279 non-LTS in the atezolizumab-arm and 77 LTS vs 299 non-LTS in the docetaxel-arm. Characteristics of atezolizumab-arm LTS and non-LTS are shown (Table). Atezolizumab-arm LTS were enriched for non-squamous histology and high PD-L1–expressing tumors, but also included low/no PD-L1–expressing tumors (40.3%). Atezolizumab-arm LTS had higher ORR (39.5%) than non-LTS (5.0%) but included LTS subjects with PD. 52.9% atezolizumab-arm vs 71.4% docetaxel-arm LTS received anti-cancer non-protocol therapy (NPT) after discontinuation of protocol-defined therapy. 51.9% of docetaxel-arm LTS vs 12.7% non-LTS received non-protocol immunotherapy. Median treatment exposure in atezolizumab-arm LTS was 18.0 months. Atezolizumab-arm LTS had a comparable safety profile to all atezolizumab-treated population.

      Conclusion:
      Atezolizumab provides superior 2-year OS benefit vs docetaxel and is well tolerated. The majority of docetaxel-arm LTS received a checkpoint inhibitor as NPT. Atezolizumab LTS appeared to have favorable prognostic factors, including non-squamous histology, but notably were not limited to patients with RECIST v1.1 response or with PD-L1 expression.

      Table. Characteristics of Atezolizumab-Arm Long-Term Survivors (LTS) vs Non-Long Term Survivors (Non-LTS)
      Atezolizumab LTS (n = 119) n (%) Atezolizumab Non-LTS (n = 279) n (%)
      Sex
      Male 61 (51.3) 183 (65.6)
      Female 58 (48.7) 96 (34.4)
      Tobacco use history
      Never smoker 29 (24.4) 47 (16.8)
      Current/previous smoker 90 (75.6) 232 (83.2)
      Histology
      Non-squamous 101 (84.9) 195 (69.9)
      Squamous 18 (15.1) 84 (30.1)
      No. of prior therapies, 1 89 (74.8) 209 (74.9)
      ECOG performance status at baseline
      0 60 (50.4) 89 (31.9)
      1 59 (49.6) 190 (68.1)
      EGFR mutation status, positive 11 (9.2) 26 (9.3)
      PD-L1 IHC subgroup
      TC3 or IC3 28 (23.5) 39 (14.0)
      TC1/2/3 or IC1/2/3 71 (59.7) 156 (55.9)
      TC0 and IC0 48 (40.3) 119 (42.7)
      Best overall response
      Complete response 5 (4.2) 0 (0)
      Partial response 42 (35.3) 14 (5.0)
      Stable disease 47 (39.5) 97 (34.8)
      Progressive disease 25 (21.0) 142 (50.9)
      IC, tumor-infiltrating immune cell; TC, tumor cell. TC3 or IC3 = PD-L1 ≥ 50% TC or 10% IC; TC1/2/3 or IC1/2/3 = PD-L1 ≥ 1% on TC or IC; TC0 and IC0 = PD-L1 < 1% on TC and IC. NCT02008227.


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    P2.04 - Clinical Design, Statistics and Clinical Trials (ID 705)

    • Event: WCLC 2017
    • Type: Poster Session with Presenters Present
    • Track: Clinical Design, Statistics and Clinical Trials
    • Presentations: 1
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      P2.04-005 - GEOMETRY Mono-1: Phase II, Multicenter Study of MET Inhibitor Capmatinib (INC280) in EGFR Wt, MET-Dysregulated Advanced NSCLC (ID 8961)

      09:30 - 16:00  |  Author(s): Ji-Youn Han

      • Abstract
      • Slides

      Background:
      Amplification of MET leading to oncogenic signaling occurs in 3‒5% of newly diagnosed EGFR wild type (wt) non-small cell lung cancer (NSCLC) cases with decreasing incidence at higher levels of amplification. Mutations in MET leading to exon 14 deletion (METΔ[ex14]) also occur in 2–4% of adenocarcinoma and 1–2% of other NSCLC subsets. Capmatinib (INC280) is a potent and selective MET inhibitor that has shown strong evidence of antitumor activity in a phase I study in patients with EGFR wt advanced NSCLC harboring MET amplification and METΔ[ex14].

      Method:
      This phase II, multicenter study (NCT02414139) was designed to confirm the clinical activity of capmatinib in patients with advanced NSCLC by MET amplification and METΔ[ex14] status. Eligible patients (≥18 years of age, Eastern Cooperative Oncology Group Performance Status 0–1) must have ALK-negative, EGFR wt, stage IIIB/IV NSCLC (any histology). Centrally assessed MET amplification (gene copy number [GCN]) and mutation status is used to assign patients to one of the below cohorts: Pretreated with 1–2 prior systemic lines of therapy for advanced setting (cohorts 1–4): 1a: MET amplification GCN ≥10 (n=69) 1b: MET amplification GCN ≥6 and <10 (n=69) 2: MET amplification GCN ≥4 and <6 (n=69) 3: MET amplification GCN <4 (n=69) 4: METΔ[ex14] mutation regardless of MET GCN (n=69) Treatment naïve (cohorts 5a and 5b): 5a: MET amplification GCN ≥10 and no METΔ[ex14] mutation (n=27) 5b: METΔ[ex14] mutation regardless of MET GCN (n=27) Capmatinib 400 mg tablets are orally administered twice daily on a continuous dosing schedule 12 hours apart. Primary and key secondary endpoints are overall response rate (ORR) and duration of response (DOR), respectively (blinded independent review assessment). Other secondary endpoints include investigator-assessed ORR, DOR, time to response, disease control rate, progression-free survival (independent and investigator assessment), safety, and pharmacokinetics. Enrollment is ongoing in 25 countries. Cohorts 1b, 2, and 3 are now closed to enrollment; cohorts 1a and 4 continue to enroll patients who have received 1–2 prior lines of therapy in the advanced setting, and cohorts 5a and 5b are open for enrollment of treatment-naïve patients. Responses have been seen in both MET-amplified and MET-mutated patients irrespective of the line of therapy.

      Result:
      Section not applicable

      Conclusion:
      Section not applicable

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