2021
Clinical definition of acquired resistance to immunotherapy in patients with metastatic non-small-cell lung cancer
Schoenfeld A, Antonia S, Awad M, Felip E, Gainor J, Gettinger S, Hodi F, Johnson M, Leighl N, Lovly C, Mok T, Perol M, Reck M, Solomon B, Soria J, Tan D, Peters S, Hellmann M. Clinical definition of acquired resistance to immunotherapy in patients with metastatic non-small-cell lung cancer. Annals Of Oncology 2021, 32: 1597-1607. PMID: 34487855, DOI: 10.1016/j.annonc.2021.08.2151.Peer-Reviewed Original ResearchMeSH KeywordsB7-H1 AntigenCarcinoma, Non-Small-Cell LungHumansImmunotherapyLung NeoplasmsProgrammed Cell Death 1 ReceptorProspective StudiesConceptsCell lung cancerClinical definitionAcquired ResistanceLung cancerClinical trialsCell death protein 1/Death protein 1/Consistent clinical definitionPersistent antitumor immunityProspective clinical trialsInvestigational immunotherapiesAntitumor immunityObjective responseProgressive diseaseAntibody treatmentNSCLC biologyInitial respondersTreatment strategiesClinical reportsPatientsBlockadeImmunotherapyTherapeutic discoveryCancerUniform criteria
2020
Biomarkers Associated with Beneficial PD-1 Checkpoint Blockade in Non–Small Cell Lung Cancer (NSCLC) Identified Using High-Plex Digital Spatial Profiling
Zugazagoitia J, Gupta S, Liu Y, Fuhrman K, Gettinger S, Herbst RS, Schalper KA, Rimm DL. Biomarkers Associated with Beneficial PD-1 Checkpoint Blockade in Non–Small Cell Lung Cancer (NSCLC) Identified Using High-Plex Digital Spatial Profiling. Clinical Cancer Research 2020, 26: 4360-4368. PMID: 32253229, PMCID: PMC7442721, DOI: 10.1158/1078-0432.ccr-20-0175.Peer-Reviewed Original ResearchConceptsNon-small cell lung cancerPD-1 checkpoint blockadeCell lung cancerCheckpoint blockadeLung cancerAdvanced non-small cell lung cancerUnivariate unadjusted analysisProgression-free survivalImmune cell countsMinority of patientsRobust predictive biomarkersBiomarkers of responseLarge independent cohortsSpatial profiling technologyDigital spatial profilingDigital spatial profiling (DSP) technologyOverall survivalClinical outcomesImmune predictorsHigher CD56NSCLC casesPredictive biomarkersUnadjusted analysesImmune parametersTissue microarrayBempegaldesleukin (NKTR-214) plus Nivolumab in Patients with Advanced Solid Tumors: Phase I Dose-Escalation Study of Safety, Efficacy, and Immune Activation (PIVOT-02)
Diab A, Tannir NM, Bentebibel SE, Hwu P, Papadimitrakopoulou V, Haymaker C, Kluger HM, Gettinger SN, Sznol M, Tykodi SS, Curti BD, Tagliaferri MA, Zalevsky J, Hannah AL, Hoch U, Aung S, Fanton C, Rizwan A, Iacucci E, Liao Y, Bernatchez C, Hurwitz ME, Cho DC. Bempegaldesleukin (NKTR-214) plus Nivolumab in Patients with Advanced Solid Tumors: Phase I Dose-Escalation Study of Safety, Efficacy, and Immune Activation (PIVOT-02). Cancer Discovery 2020, 10: 1158-1173. PMID: 32439653, DOI: 10.1158/2159-8290.cd-19-1510.Peer-Reviewed Original ResearchMeSH KeywordsAdultAgedAntineoplastic Agents, ImmunologicalAntineoplastic Combined Chemotherapy ProtocolsCarcinoma, Non-Small-Cell LungCarcinoma, Renal CellFemaleGene Expression Regulation, NeoplasticHumansImmune Checkpoint InhibitorsImmunotherapyInterleukin-2Kidney NeoplasmsLung NeoplasmsLymphocyte CountLymphocytes, Tumor-InfiltratingMaleMelanomaMiddle AgedNivolumabPolyethylene GlycolsProgrammed Cell Death 1 ReceptorTreatment OutcomeYoung AdultConceptsTreatment-related adverse eventsAdvanced solid tumorsPD-L1 statusSolid tumorsGrade 3/4 treatment-related adverse eventsPD-1/PD-L1 blockadeCommon treatment-related adverse eventsPhase I dose-escalation trialPoor prognostic risk factorsTotal objective response rateI dose-escalation studyI dose-escalation trialLongitudinal tumor biopsiesPD-L1 blockadeT-cell enhancementTreatment-related deathsObjective response ratePhase II doseDose-escalation studyDose-escalation trialDose-limiting toxicityFlu-like symptomsPrognostic risk factorsTumor-infiltrating lymphocytesCytotoxicity of CD8Differential effects of PD-L1 versus PD-1 blockade on myeloid inflammation in human cancer
Bar N, Costa F, Das R, Duffy A, Samur M, McCachren S, Gettinger S, Neparidze N, Parker TL, Bailur JK, Pendleton K, Bajpai R, Zhang L, Xu ML, Anderson T, Giuliani N, Nooka A, Cho HJ, Raval A, Shanmugam M, Dhodapkar KM, Dhodapkar M. Differential effects of PD-L1 versus PD-1 blockade on myeloid inflammation in human cancer. JCI Insight 2020, 5 PMID: 32427579, PMCID: PMC7406262, DOI: 10.1172/jci.insight.129353.Peer-Reviewed Original ResearchMeSH KeywordsAntibodies, MonoclonalAntibodies, Monoclonal, HumanizedAntigen-Presenting CellsB7-H1 AntigenHumansImmunotherapyInflammationLung NeoplasmsMultiple MyelomaProgrammed Cell Death 1 ReceptorConceptsPD-L1 blockadePD-1 blockadeAsymptomatic multiple myelomaMonocyte-derived DCsPD-L1Immunologic effectsT cellsMyeloid cellsAntigen-specific T cell expansionAnti-PD-1 therapyMyeloid antigen-presenting cellsDistinct inflammatory signatureSystemic immunologic effectsLung cancer patientsT cell expansionAntigen-presenting cellsMyeloid activationMyeloid inflammationInflammatory signatureNIH/NCICheckpoint blockadeDC maturationL1 therapyCombination therapyInflammatory phenotypePhase 1 Trial of Pembrolizumab Administered Concurrently With Chemoradiotherapy for Locally Advanced Non–Small Cell Lung Cancer
Jabbour SK, Berman AT, Decker RH, Lin Y, Feigenberg SJ, Gettinger SN, Aggarwal C, Langer CJ, Simone CB, Bradley JD, Aisner J, Malhotra J. Phase 1 Trial of Pembrolizumab Administered Concurrently With Chemoradiotherapy for Locally Advanced Non–Small Cell Lung Cancer. JAMA Oncology 2020, 6: 848-855. PMID: 32077891, PMCID: PMC7042914, DOI: 10.1001/jamaoncol.2019.6731.Peer-Reviewed Original ResearchMeSH KeywordsAgedAged, 80 and overAntibodies, Monoclonal, HumanizedAntineoplastic Agents, ImmunologicalCarboplatinCarcinoma, Non-Small-Cell LungChemoradiotherapyFemaleHumansImmune Checkpoint InhibitorsLung NeoplasmsMaleMiddle AgedNeoplasm StagingPaclitaxelProgrammed Cell Death 1 ReceptorTreatment OutcomeConceptsNon-small cell lung cancerProgression-free survivalStage III non-small cell lung cancerMedian progression-free survivalDose of pembrolizumabSafety expansion cohortPD-1 inhibitionCell lung cancerExpansion cohortLung cancerDay 29Eastern Cooperative Oncology Group performance status 0Advanced non-small cell lung cancerDay 1Cell death 1 (PD-1) inhibitionDeath ligand 1 (PD-L1) inhibitionDose-limiting toxic effectDeath-1 (PD-1) inhibitionDoses of pembrolizumabGrade 5 pneumonitisLeast grade 4Performance status 0PD-1 inhibitorsPhase 1 trialLeast grade 3Immune Cell PD-L1 Colocalizes with Macrophages and Is Associated with Outcome in PD-1 Pathway Blockade Therapy
Liu Y, Zugazagoitia J, Ahmed FS, Henick BS, Gettinger S, Herbst RS, Schalper KA, Rimm DL. Immune Cell PD-L1 Colocalizes with Macrophages and Is Associated with Outcome in PD-1 Pathway Blockade Therapy. Clinical Cancer Research 2020, 26: 970-977. PMID: 31615933, PMCID: PMC7024671, DOI: 10.1158/1078-0432.ccr-19-1040.Peer-Reviewed Original ResearchConceptsPD-L1 expressionHigh PD-L1 expressionPD-L1 levelsPD-L1Immune cellsTumor cellsT cellsHigh PD-L1 levelsPredominant immune cell typeNon-small cell lung cancer (NSCLC) casesDifferent immune cell subsetsCell lung cancer casesElevated PD-L1High PD-L1Better overall survivalDeath ligand 1Natural killer cellsImmune cell subsetsMultiple immune cellsCytotoxic T cellsLung cancer casesImmune cell typesCD68 levelsCell typesBlockade therapy
2019
Expression Analysis and Significance of PD-1, LAG-3, and TIM-3 in Human Non–Small Cell Lung Cancer Using Spatially Resolved and Multiparametric Single-Cell Analysis
Datar I, Sanmamed MF, Wang J, Henick BS, Choi J, Badri T, Dong W, Mani N, Toki M, Mejías L, Lozano MD, Perez-Gracia JL, Velcheti V, Hellmann MD, Gainor JF, McEachern K, Jenkins D, Syrigos K, Politi K, Gettinger S, Rimm DL, Herbst RS, Melero I, Chen L, Schalper KA. Expression Analysis and Significance of PD-1, LAG-3, and TIM-3 in Human Non–Small Cell Lung Cancer Using Spatially Resolved and Multiparametric Single-Cell Analysis. Clinical Cancer Research 2019, 25: 4663-4673. PMID: 31053602, PMCID: PMC7444693, DOI: 10.1158/1078-0432.ccr-18-4142.Peer-Reviewed Original ResearchMeSH KeywordsAntigens, CDBiomarkers, TumorCarcinoma, Non-Small-Cell LungGene Expression Regulation, NeoplasticHepatitis A Virus Cellular Receptor 2HumansLung NeoplasmsLymphocyte ActivationLymphocyte Activation Gene 3 ProteinLymphocytes, Tumor-InfiltratingPrognosisProgrammed Cell Death 1 ReceptorRetrospective StudiesSingle-Cell AnalysisSurvival RateConceptsNon-small cell lung cancerHuman non-small cell lung cancerTumor-infiltrating lymphocytesAdvanced non-small cell lung cancerTim-3PD-1Cell lung cancerLAG-3Lung cancerPD-1 axis blockadeShorter progression-free survivalBaseline samplesTim-3 protein expressionMajor clinicopathologic variablesMultiplexed quantitative immunofluorescencePD-1 expressionProgression-free survivalTim-3 expressionLAG-3 expressionT-cell phenotypeTumor mutational burdenImmune inhibitory receptorsImmune evasion pathwaysTIM-3 proteinMass cytometry analysisEGFR mutation subtypes and response to immune checkpoint blockade treatment in non-small-cell lung cancer
Hastings K, Yu HA, Wei W, Sanchez-Vega F, DeVeaux M, Choi J, Rizvi H, Lisberg A, Truini A, Lydon CA, Liu Z, Henick BS, Wurtz A, Cai G, Plodkowski AJ, Long NM, Halpenny DF, Killam J, Oliva I, Schultz N, Riely GJ, Arcila ME, Ladanyi M, Zelterman D, Herbst RS, Goldberg SB, Awad MM, Garon EB, Gettinger S, Hellmann MD, Politi K. EGFR mutation subtypes and response to immune checkpoint blockade treatment in non-small-cell lung cancer. Annals Of Oncology 2019, 30: 1311-1320. PMID: 31086949, PMCID: PMC6683857, DOI: 10.1093/annonc/mdz141.Peer-Reviewed Original ResearchMeSH KeywordsAgedAllelesAntineoplastic Agents, ImmunologicalB7-H1 AntigenBiomarkers, TumorCarcinoma, Non-Small-Cell LungDrug Resistance, NeoplasmErbB ReceptorsFemaleGenetic HeterogeneityHumansLungLung NeoplasmsMaleMiddle AgedMutationProgrammed Cell Death 1 ReceptorProgression-Free SurvivalRetrospective StudiesTobacco SmokingConceptsEGFR-mutant tumorsMemorial Sloan-Kettering Cancer CenterYale Cancer CenterImmune checkpoint inhibitorsPD-L1 expressionImmune checkpoint blockadeTumor mutation burdenCancer CenterLung tumorsCheckpoint blockadeEGFR mutant lung tumorsMutant tumorsCheckpoint inhibitorsLung cancerMutation burdenImmune checkpoint blockade treatmentLow tumor mutation burdenDana-Farber Cancer InstituteEGFR wild-type lung cancersCheckpoint blockade treatmentCell lung cancerEGFR mutation subtypesSimilar smoking historyCell death 1Lung cancer cases
2018
A dormant TIL phenotype defines non-small cell lung carcinomas sensitive to immune checkpoint blockers
Gettinger SN, Choi J, Mani N, Sanmamed MF, Datar I, Sowell R, Du VY, Kaftan E, Goldberg S, Dong W, Zelterman D, Politi K, Kavathas P, Kaech S, Yu X, Zhao H, Schlessinger J, Lifton R, Rimm DL, Chen L, Herbst RS, Schalper KA. A dormant TIL phenotype defines non-small cell lung carcinomas sensitive to immune checkpoint blockers. Nature Communications 2018, 9: 3196. PMID: 30097571, PMCID: PMC6086912, DOI: 10.1038/s41467-018-05032-8.Peer-Reviewed Original ResearchMeSH KeywordsAmino Acid SequenceAnimalsAntibodies, BlockingCarcinogenesisCarcinoma, Non-Small-Cell LungCell ProliferationCytotoxicity, ImmunologicHistocompatibility Antigens Class IHumansLung NeoplasmsLymphocyte ActivationLymphocytes, Tumor-InfiltratingMaleMice, Inbred NODMice, SCIDMutant ProteinsMutationPeptidesPhenotypeProgrammed Cell Death 1 ReceptorReproducibility of ResultsSurvival AnalysisTobaccoConceptsImmune checkpoint blockersCheckpoint blockersQuantitative immunofluorescenceNon-small cell lung carcinoma patientsCell lung carcinoma patientsNon-small cell lung carcinomaPatient-derived xenograft modelsIntratumoral T cellsMultiplexed quantitative immunofluorescencePD-1 blockadeLevels of CD3Lung carcinoma patientsCell lung carcinomaT cell proliferationPre-treatment samplesTIL phenotypeSurvival benefitCarcinoma patientsEffector capacityLung carcinomaT cellsWhole-exome DNA sequencingXenograft modelFavorable responseBlockersCollateral Damage: Insulin-Dependent Diabetes Induced With Checkpoint Inhibitors
Stamatouli AM, Quandt Z, Perdigoto AL, Clark PL, Kluger H, Weiss SA, Gettinger S, Sznol M, Young A, Rushakoff R, Lee J, Bluestone JA, Anderson M, Herold KC. Collateral Damage: Insulin-Dependent Diabetes Induced With Checkpoint Inhibitors. Diabetes 2018, 67: dbi180002. PMID: 29937434, PMCID: PMC6054443, DOI: 10.2337/dbi18-0002.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsAntineoplastic Agents, ImmunologicalAutoimmune DiseasesB7-H1 AntigenDiabetes Mellitus, Type 1Genetic Predisposition to DiseaseGenotypeHLA-DR4 AntigenHumansHypoglycemic AgentsInsulinInsulin SecretionIsoantibodiesKetosisModels, ImmunologicalNeoplasmsPancreasPancreatitisProgrammed Cell Death 1 ReceptorConceptsInsulin-dependent diabetesCheckpoint inhibitorsAdverse eventsHLA-DR4Classic type 1 diabetesPD-L1 checkpoint inhibitorsEvidence of pancreatitisImmune adverse eventsSolid organ cancersType 1 diabetesPeridiagnosis periodPositive autoantibodiesL1 antibodyInsulin-DependentHigh riskPatientsDiabetesCancerInhibitorsKetoacidosisAutoimmuneAutoantibodiesPancreatitisComplicationsSyndromeEarly Assessment of Lung Cancer Immunotherapy Response via Circulating Tumor DNA
Goldberg SB, Narayan A, Kole AJ, Decker RH, Teysir J, Carriero NJ, Lee A, Nemati R, Nath SK, Mane SM, Deng Y, Sukumar N, Zelterman D, Boffa DJ, Politi K, Gettinger S, Wilson LD, Herbst RS, Patel AA. Early Assessment of Lung Cancer Immunotherapy Response via Circulating Tumor DNA. Clinical Cancer Research 2018, 24: 1872-1880. PMID: 29330207, PMCID: PMC5899677, DOI: 10.1158/1078-0432.ccr-17-1341.Peer-Reviewed Original ResearchConceptsNon-small cell lung cancerImmune checkpoint inhibitorsCtDNA responseCheckpoint inhibitorsCtDNA levelsMetastatic non-small cell lung cancerImmune checkpoint inhibitor therapySuperior progression-free survivalRadiographic tumor sizeCheckpoint inhibitor therapyProgression-free survivalSuperior overall survivalTumor DNA levelsCell lung cancerAllele fractionClin Cancer ResMultigene next-generation sequencingMutant allele fractionTumor cell deathInhibitor therapyOverall survivalRadiographic responseImmunotherapy efficacyImmunotherapy responseMedian time
2016
Clinical and Histologic Features of Lichenoid Mucocutaneous Eruptions Due to Anti–Programmed Cell Death 1 and Anti–Programmed Cell Death Ligand 1 Immunotherapy
Shi VJ, Rodic N, Gettinger S, Leventhal JS, Neckman JP, Girardi M, Bosenberg M, Choi JN. Clinical and Histologic Features of Lichenoid Mucocutaneous Eruptions Due to Anti–Programmed Cell Death 1 and Anti–Programmed Cell Death Ligand 1 Immunotherapy. JAMA Dermatology 2016, 152: 1128-1136. PMID: 27411054, PMCID: PMC6108080, DOI: 10.1001/jamadermatol.2016.2226.Peer-Reviewed Original ResearchConceptsAnti-PD-1/PD-L1 therapyCutaneous adverse effectsPD-L1 therapyCell death 1Concurrent medicationsDeath-1Adverse effectsClinical morphologyAnti-PD-1/PD-L1 treatmentAnti-programmed cell death ligand-1 (PD-L1) immunotherapiesAnti-programmed cell death 1Non-small cell lung cancerDeath ligand 1 (PD-L1) immunotherapyPD-L1 antibody therapyCell death ligand 1Yale-New Haven HospitalMucocutaneous adverse effectsPD-L1 treatmentTreatment of rashTertiary care hospitalDeath ligand 1Lichenoid drug eruptionCell lung cancerSkin biopsy specimensRecent US FoodPD-1 Axis Inhibitors in EGFR- and ALK-Driven Lung Cancer: Lost Cause?
Gettinger S, Politi K. PD-1 Axis Inhibitors in EGFR- and ALK-Driven Lung Cancer: Lost Cause? Clinical Cancer Research 2016, 22: 4539-4541. PMID: 27470969, PMCID: PMC5653962, DOI: 10.1158/1078-0432.ccr-16-1401.Peer-Reviewed Original ResearchPossible Interaction of Anti–PD-1 Therapy with the Effects of Radiosurgery on Brain Metastases
Alomari AK, Cohen J, Vortmeyer AO, Chiang A, Gettinger S, Goldberg S, Kluger HM, Chiang VL. Possible Interaction of Anti–PD-1 Therapy with the Effects of Radiosurgery on Brain Metastases. Cancer Immunology Research 2016, 4: 481-487. PMID: 26994250, DOI: 10.1158/2326-6066.cir-15-0238.Peer-Reviewed Original ResearchConceptsStereotactic radiosurgeryBrain metastasesInitiation of immunotherapyPD-1 mAbImmune-modulating therapyModalities of treatmentRadiologic progressionSurgical resectionSystemic therapyDeath-1Radiologic findingsMetastatic malignancyReactive astrocytosisPathologic examinationTreatment regimensHistopathologic examinationWall infiltrationT lymphocytesPatientsTumor progressionMonoclonal antibodiesBiologic interactionsRadiation-induced changesImmunotherapyMalignancy
2015
Overall Survival and Long-Term Safety of Nivolumab (Anti–Programmed Death 1 Antibody, BMS-936558, ONO-4538) in Patients With Previously Treated Advanced Non–Small-Cell Lung Cancer
Gettinger SN, Horn L, Gandhi L, Spigel DR, Antonia SJ, Rizvi NA, Powderly JD, Heist RS, Carvajal RD, Jackman DM, Sequist LV, Smith DC, Leming P, Carbone DP, Pinder-Schenck MC, Topalian SL, Hodi FS, Sosman JA, Sznol M, McDermott DF, Pardoll DM, Sankar V, Ahlers CM, Salvati M, Wigginton JM, Hellmann MD, Kollia GD, Gupta AK, Brahmer JR. Overall Survival and Long-Term Safety of Nivolumab (Anti–Programmed Death 1 Antibody, BMS-936558, ONO-4538) in Patients With Previously Treated Advanced Non–Small-Cell Lung Cancer. Journal Of Clinical Oncology 2015, 33: 2004-2012. PMID: 25897158, PMCID: PMC4672027, DOI: 10.1200/jco.2014.58.3708.Peer-Reviewed Original ResearchConceptsOverall survivalLong-term safetyAdvanced NSCLCLung cancerDeath-1 immune checkpoint inhibitor antibodyAdvanced non-small cell lung cancerNon-small cell lung cancerImmune checkpoint inhibitor antibodyTreatment-related adverse eventsCheckpoint inhibitor antibodyTreatment-related deathsMedian overall survivalMedian response durationAdvanced solid tumorsPhase I trialCell lung cancerRandomized clinical trialsFurther clinical developmentHuman immunoglobulin G4Nivolumab 1Nivolumab monotherapyExpansion cohortLast doseNonsquamous NSCLCAdverse eventsPrecipitation of Autoimmune Diabetes With Anti-PD-1 Immunotherapy
Hughes J, Vudattu N, Sznol M, Gettinger S, Kluger H, Lupsa B, Herold KC. Precipitation of Autoimmune Diabetes With Anti-PD-1 Immunotherapy. Diabetes Care 2015, 38: e55-e57. PMID: 25805871, PMCID: PMC4370325, DOI: 10.2337/dc14-2349.Peer-Reviewed Reviews, Practice Guidelines, Standards, and Consensus StatementsCombination Therapy with Anti–CTLA-4 and Anti–PD-1 Leads to Distinct Immunologic Changes In Vivo
Das R, Verma R, Sznol M, Boddupalli CS, Gettinger SN, Kluger H, Callahan M, Wolchok JD, Halaban R, Dhodapkar MV, Dhodapkar KM. Combination Therapy with Anti–CTLA-4 and Anti–PD-1 Leads to Distinct Immunologic Changes In Vivo. The Journal Of Immunology 2015, 194: 950-959. PMID: 25539810, PMCID: PMC4380504, DOI: 10.4049/jimmunol.1401686.Peer-Reviewed Original ResearchMeSH KeywordsAntibodies, MonoclonalAntigens, SurfaceAntineoplastic Combined Chemotherapy ProtocolsCTLA-4 AntigenCytokinesGene Expression ProfilingGene Expression Regulation, NeoplasticHumansImmunophenotypingIpilimumabLymphocytes, Tumor-InfiltratingNeoplasmsNivolumabProgrammed Cell Death 1 ReceptorSignal TransductionT-Lymphocyte SubsetsConceptsPD-1T cellsCTLA-4Checkpoint blockadeCombination therapyReceptor occupancyCombination immune checkpoint blockadeCTLA-4 immune checkpointsPD-1 receptor occupancyTransitional memory T cellsAnti-PD-1 therapyAnti CTLA-4Immune-based combinationsPD-1 blockadeSoluble IL-2RImmune checkpoint blockadeNK cell functionMemory T cellsTherapy-induced changesT cell activationTumor T cellsHuman T cellsRemarkable antitumor effectImmunologic changesImmunologic effects
2014
B7-H1/PD-1 Blockade Therapy in Non–Small Cell Lung Cancer
Gettinger S, Herbst RS. B7-H1/PD-1 Blockade Therapy in Non–Small Cell Lung Cancer. The Cancer Journal 2014, 20: 281-289. PMID: 25098289, DOI: 10.1097/ppo.0000000000000063.Peer-Reviewed Original ResearchMeSH KeywordsAntineoplastic AgentsB7-H1 AntigenCarcinoma, Non-Small-Cell LungClinical Trials as TopicHumansImmunotherapyLung NeoplasmsProgrammed Cell Death 1 ReceptorRandomized Controlled Trials as TopicConceptsNon-small cell lung cancerAdvanced non-small cell lung cancerPhase III trialsCell lung cancerIII trialsPD-1Lung cancerClinical trialsPD-1/PD-L1 inhibitorsB7-H1/PDTumor PD-L1 expressionSevere autoimmune toxicityChemotherapy-naive patientsPD-L1 expressionPotential of immunotherapyPD-L1 inhibitorsDeath ligand 1Future clinical trialsNumber of antibodiesAutoimmune toxicityExpansion cohortBlockade therapyDurable responsesNSCLC patientsStandard therapy
2012
Safety, Activity, and Immune Correlates of Anti–PD-1 Antibody in Cancer
Topalian SL, Hodi FS, Brahmer JR, Gettinger SN, Smith DC, McDermott DF, Powderly JD, Carvajal RD, Sosman JA, Atkins MB, Leming PD, Spigel DR, Antonia SJ, Horn L, Drake CG, Pardoll DM, Chen L, Sharfman WH, Anders RA, Taube JM, McMiller TL, Xu H, Korman AJ, Jure-Kunkel M, Agrawal S, McDonald D, Kollia GD, Gupta A, Wigginton JM, Sznol M. Safety, Activity, and Immune Correlates of Anti–PD-1 Antibody in Cancer. New England Journal Of Medicine 2012, 366: 2443-2454. PMID: 22658127, PMCID: PMC3544539, DOI: 10.1056/nejmoa1200690.Peer-Reviewed Original ResearchConceptsAnti-PD-1 antibodyCell lung cancerRenal cell cancerObjective responseLung cancerAdverse eventsPD-L1Drug-related adverse eventsPD-1 ligand expressionCastration-resistant prostate cancerImmune-related causesPretreatment tumor specimensAdverse event profilePD-L1 expressionPD-1-PDCumulative response rateBMS-936558Immune correlatesL1 pathwayAdvanced melanomaComplete responseDeath-1PD-1Negative tumorsPositive tumors