2025
Safety and efficacy of immune checkpoint therapy for the treatment of patients with cardiac metastasis: a multicenter international retrospective study
Nassar A, Alaiwi S, Zarif T, Denu R, Macaron W, Abdel-Wahab N, Freeman D, Vasbinder A, Hayeck S, Anderson E, Goodman R, Johnson D, Grynberg S, Shapira R, Kwan J, Woodford R, Long G, Haykal T, Dent S, Kojima Y, Yonemor K, Tandon A, Trevino A, Akhter N, Yang E, Hui G, Drakaki A, El-Am E, Kozaily E, Al-Hader A, Farhat E, Babu P, Mittra A, Li M, Jones N, Baena J, Herrera M, Foderaro S, Nana F, Kim C, Sackstein P, Parikh K, Desai A, Smith C, Cortellini A, Pinato D, Korolewicz J, Lopetegui-Lia N, Funchain P, Choudhary A, Asnani A, Navani V, Meyers D, Stukalin I, Gallegos J, Trent J, Nusrat S, Malvar C, McKay R, Neilan T, Choueiri T, Naqash A. Safety and efficacy of immune checkpoint therapy for the treatment of patients with cardiac metastasis: a multicenter international retrospective study. Journal For ImmunoTherapy Of Cancer 2025, 13: e009364. PMID: 40032601, PMCID: PMC11877189, DOI: 10.1136/jitc-2024-009364.Peer-Reviewed Original ResearchConceptsImmune checkpoint inhibitor initiationImmune checkpoint inhibitorsTreatment-related adverse eventsObjective response rateProgression-free survivalCardiac metastasisOverall survivalRetrospective studyAnti-cytotoxic T-lymphocyte antigen 4Dose of immune checkpoint inhibitorsEfficacy of immune checkpoint therapyAnti-programmed death-1International multicenter retrospective studyMulticenter international retrospective studyT-lymphocyte antigen-4Non-small cell lung cancerMedian follow-up timeClinical outcomes of patientsICI-based regimensMultiple cardiac metastasesSolid Tumors V.1.1Immune checkpoint therapyResponse Evaluation CriteriaInternational retrospective studyMulticenter retrospective study
2024
The Immune-Related 27-Gene Signature DetermaIO Predicts Response to Neoadjuvant Atezolizumab plus Chemotherapy in Triple-Negative Breast Cancer
Dugo M, Huang C, Egle D, Bermejo B, Zamagni C, Seitz R, Nielsen T, Thill M, Antón-Torres A, Russo S, Ciruelos E, Schweitzer B, Ross D, Galbardi B, Greil R, Semiglazov V, Gyorffy B, Colleoni M, Kelly C, Mariani G, Del Mastro L, Blasi O, Callari M, Pusztai L, Valagussa P, Viale G, Gianni L, Bianchini G. The Immune-Related 27-Gene Signature DetermaIO Predicts Response to Neoadjuvant Atezolizumab plus Chemotherapy in Triple-Negative Breast Cancer. Clinical Cancer Research 2024, 30: of1-of10. PMID: 39308141, PMCID: PMC11528202, DOI: 10.1158/1078-0432.ccr-24-0149.Peer-Reviewed Original ResearchPathologic complete response ratePathological complete responseTriple-negative breast cancerRNA-seqI-SPY2Immuno-oncologyBreast cancerPatients treated with pembrolizumabTumor-infiltrating lymphocyte countsPublicly available microarray dataPretreatment core biopsiesImmune checkpoint therapyRNA-seq dataPer-protocol populationAvailable microarray dataI-SPY2 trialPDL1 protein expressionNeoadjuvant atezolizumabNeoadjuvant immunotherapyPlus chemotherapyCheckpoint therapyComplete responseTriple-negativeCore biopsyRT-qPCR data
2023
Determinants of overall survival in patients with metastatic uveal melanoma
Demkowicz P, Pointdujour‐Lim R, Miguez S, Lee Y, Jones B, Barker C, Bosenberg M, Abramson D, Shoushtari A, Kluger H, Francis J, Sznol M, Bakhoum M. Determinants of overall survival in patients with metastatic uveal melanoma. Cancer 2023, 129: 3275-3286. PMID: 37382208, PMCID: PMC11149607, DOI: 10.1002/cncr.34927.Peer-Reviewed Original ResearchConceptsAnti-PD-1 therapyMetastatic uveal melanomaDeath hazard ratioImmune checkpoint inhibitorsOverall survivalHazard ratioUveal melanomaSurvival outcomesFemale sexCheckpoint inhibitorsECOG scoreValidation cohortEastern Cooperative Oncology Group performance status scaleGood baseline performance statusMetastatic uveal melanoma patientsMetastatic UM patientsImproved overall survivalMedian overall survivalBaseline performance statusBetter survival outcomesImproved survival outcomesPotential of immunotherapyWorse survival outcomesImmune checkpoint therapyKaplan-Meier analysis
2022
The Crossroads of Cancer Epigenetics and Immune Checkpoint Therapy.
Micevic G, Bosenberg M, Yan Q. The Crossroads of Cancer Epigenetics and Immune Checkpoint Therapy. Clinical Cancer Research 2022, 29: 1173-1182. PMID: 36449280, PMCID: PMC10073242, DOI: 10.1158/1078-0432.ccr-22-0784.Peer-Reviewed Reviews, Practice Guidelines, Standards, and Consensus StatementsConceptsImmune checkpoint inhibitorsImmune checkpoint therapyT cell exhaustionCheckpoint therapyAntitumor immune responseT cell populationsCell-intrinsic immunityTypes of cancerViral mimicry responseLow response rateCheckpoint inhibitorsCurrent immunotherapiesPancreatic cancerSustained responsePreclinical modelsTreatment outcomesImmune responseEndogenous antigensResponse rateTumor typesMultiple epigenetic regulatorsCritical mediatorLow immunogenicityTherapyCancer
2021
A mouse model for the study of anti-tumor T cell responses in Kras-driven lung adenocarcinoma
Fitzgerald B, Connolly KA, Cui C, Fagerberg E, Mariuzza DL, Hornick NI, Foster GG, William I, Cheung JF, Joshi NS. A mouse model for the study of anti-tumor T cell responses in Kras-driven lung adenocarcinoma. Cell Reports Methods 2021, 1: 100080. PMID: 34632444, PMCID: PMC8500377, DOI: 10.1016/j.crmeth.2021.100080.Peer-Reviewed Original ResearchConceptsLung adenocarcinomaNeoantigen expressionTumor-specific CD8 T cellsCD8 T cellsImmune checkpoint therapyInfection-induced inflammationExpression of neoantigensCommon lung cancerLUAD cell linesCheckpoint therapyLung cancerTherapeutic responseT cellsImmune responseMouse modelCell responsesTumor inductionTumorsAdenocarcinomaCell linesNeoantigensKrasFuture studiesExpressionImmunotherapyBlockade of the CD93 pathway normalizes tumor vasculature to facilitate drug delivery and immunotherapy
Sun Y, Chen W, Torphy RJ, Yao S, Zhu G, Lin R, Lugano R, Miller EN, Fujiwara Y, Bian L, Zheng L, Anand S, Gao F, Zhang W, Ferrara SE, Goodspeed AE, Dimberg A, Wang XJ, Edil BH, Barnett CC, Schulick RD, Chen L, Zhu Y. Blockade of the CD93 pathway normalizes tumor vasculature to facilitate drug delivery and immunotherapy. Science Translational Medicine 2021, 13 PMID: 34321321, PMCID: PMC8749958, DOI: 10.1126/scitranslmed.abc8922.Peer-Reviewed Original ResearchConceptsInsulin-like growth factor binding protein 7Vascular dysfunctionAnti-programmed death-1/Intratumoral effector T cellsTumor vasculatureTumor microenvironmentGrowth factor binding protein 7Tumor-associated endothelial cellsImproved antitumor responsesEffector T cellsDeath-1/Immune checkpoint therapyImmune cell infiltrationFavorable tumor microenvironmentMouse tumor modelsBinding protein 7Checkpoint therapyAntitumor responseCell infiltrationPoor responseT cellsHypoxic tumor microenvironmentTumor perfusionSolid tumorsTherapeutic interventionsIntracranial Complications From Immune Checkpoint Therapy in a Patient With NSCLC and Multiple Sclerosis: Case Report
Lu BY, Isitan C, Mahajan A, Chiang V, Huttner A, Mitzner JR, Wesley SF, Goldberg SB. Intracranial Complications From Immune Checkpoint Therapy in a Patient With NSCLC and Multiple Sclerosis: Case Report. JTO Clinical And Research Reports 2021, 2: 100183. PMID: 34590030, PMCID: PMC8474265, DOI: 10.1016/j.jtocrr.2021.100183.Peer-Reviewed Case Reports and Technical NotesImmune checkpoint inhibitorsMultiple sclerosisRadiation necrosisBrain lesionsWhole-brain radiation therapyImmune checkpoint therapyViable tumor cellsPaucity of dataBrain metastasesCheckpoint inhibitorsMetastatic NSCLCAdverse eventsCheckpoint therapyDurable responsesNeurologic declineRadiographic benefitIntracranial complicationsPathologic findingsAutoimmune disordersAutoimmune diseasesCase reportIntracranial diseaseRadiation therapyStereotactic radiosurgeryAnticancer benefitsDetection of differentially abundant cell subpopulations in scRNA-seq data
Zhao J, Jaffe A, Li H, Lindenbaum O, Sefik E, Jackson R, Cheng X, Flavell RA, Kluger Y. Detection of differentially abundant cell subpopulations in scRNA-seq data. Proceedings Of The National Academy Of Sciences Of The United States Of America 2021, 118: e2100293118. PMID: 34001664, PMCID: PMC8179149, DOI: 10.1073/pnas.2100293118.Peer-Reviewed Original ResearchMeSH KeywordsAgingB-LymphocytesBrainCell LineageCOVID-19CytokinesDatasets as TopicDendritic CellsGene Expression ProfilingGene Expression RegulationHigh-Throughput Nucleotide SequencingHumansMelanomaMonocytesPhenotypeRNA, Small CytoplasmicSARS-CoV-2Severity of Illness IndexSingle-Cell AnalysisSkin NeoplasmsT-LymphocytesTranscriptomeConceptsDA subpopulationsIll COVID-19 patientsImmune checkpoint therapyCOVID-19 patientsSingle-cell RNA sequencing analysisCheckpoint therapyBrain tissueCell subpopulationsRNA sequencing analysisTime pointsSubpopulationsDiseased individualsDistinct phenotypesOriginal studyCell typesAbundant subpopulationSequencing analysisCellsDA measuresPhenotypeImportant differencesNonrespondersPatientsTherapyThe Role of Immune Checkpoint Therapy in Propagating Neurologic Immune-Related Adverse Events: Inducing or "Unmasking" Autoimmunity?
Gardin T, Longbrake EE. The Role of Immune Checkpoint Therapy in Propagating Neurologic Immune-Related Adverse Events: Inducing or "Unmasking" Autoimmunity? Neurology 2021, 96: 733-734. PMID: 33727404, DOI: 10.1212/wnl.0000000000011812.Peer-Reviewed Original Research
2018
Safety and feasibility of immuno-cryotherapy.
Raja J, Ghodadra A, Gettinger S, Kluger H, Sznol M, Schalper K, "Kevin" Kim H. Safety and feasibility of immuno-cryotherapy. Journal Of Clinical Oncology 2018, 36: 34-34. DOI: 10.1200/jco.2018.36.5_suppl.34.Peer-Reviewed Original ResearchAdverse eventsImage-guided cryotherapyGrade 3Metastatic non-small cell lung cancerNon-small cell lung cancerImmune checkpoint inhibitor resistanceImmune checkpoint inhibitor therapyAdverse Events criteriaCheckpoint inhibitor resistanceCheckpoint inhibitor therapyCTLA-4 blockadeDisease control rateHigher adverse eventsImmune checkpoint inhibitionPrimary end pointImmune checkpoint therapyCell lung cancerTypes of malignanciesCases of diarrheaProgression of diseaseSystemic immunotherapyMetastatic NSCLCPeriprocedural periodSecondary endpointsSite hematoma
2016
Reply to timing and type of immune checkpoint therapy affect the early radiographic response of melanoma brain metastases to stereotactic radiosurgery
Yu JB, Chiang VL. Reply to timing and type of immune checkpoint therapy affect the early radiographic response of melanoma brain metastases to stereotactic radiosurgery. Cancer 2016, 122: 3577-3578. PMID: 27495789, DOI: 10.1002/cncr.30243.Peer-Reviewed Original ResearchStereotactic Ablative Radiation Therapy Combined With Immunotherapy for Solid Tumors
Brooks ED, Schoenhals JE, Tang C, Micevic G, Gomez DR, Chang JY, Welsh JW. Stereotactic Ablative Radiation Therapy Combined With Immunotherapy for Solid Tumors. The Cancer Journal 2016, 22: 257-266. PMID: 27441745, PMCID: PMC5812885, DOI: 10.1097/ppo.0000000000000210.Peer-Reviewed Original ResearchConceptsStereotactic ablative radiation therapyImmune checkpoint therapyAblative radiation therapyRadiation therapyNovel therapeuticsImmune checkpoint inhibitionImmune checkpoint inhibitorsLocal treatment optionsEncouraging clinical responsesClinical responseExperience relapseSystemic therapyTreatment optionsClinical studiesLocal irradiationSystemic effectsImmunogenic effectsImmunotherapySolid tumorsTherapyNumerous cancersTumorsTherapeuticsRelapsePatientsTiming and type of immune checkpoint therapy affect the early radiographic response of melanoma brain metastases to stereotactic radiosurgery
Qian JM, Yu JB, Kluger HM, Chiang VL. Timing and type of immune checkpoint therapy affect the early radiographic response of melanoma brain metastases to stereotactic radiosurgery. Cancer 2016, 122: 3051-3058. PMID: 27285122, PMCID: PMC5030143, DOI: 10.1002/cncr.30138.Peer-Reviewed Original ResearchConceptsMedian percent reductionImmune checkpoint therapyLesional responseStereotactic radiosurgeryCheckpoint therapyLesion volumeAnti-cytotoxic T-lymphocyte-associated protein 4Anti-programmed cell death protein 1T-lymphocyte-associated protein 4Anti-PD-1 therapyGreater median percent reductionsCell death protein 1Administration of immunotherapyWeeks of immunotherapyMelanoma brain metastasesDeath protein 1Type of immunotherapyWilcoxon rank sum testRank sum testNonconcurrent therapyBrain metastasesMelanoma patientsTreatment of cancerSingle institutionPercent reductionImmune checkpoint therapy for non-small-cell lung cancer: an update
Xia B, Herbst RS. Immune checkpoint therapy for non-small-cell lung cancer: an update. Immunotherapy 2016, 8: 279-298. PMID: 26860624, DOI: 10.2217/imt.15.123.Peer-Reviewed Original ResearchConceptsCell lung cancerImmune checkpointsLung cancerCo-inhibitory immune checkpointsRole of immunotherapyImmune checkpoint therapyImmune checkpoint pathwaysSynergistic antitumor activityCheckpoint inhibitorsInhibitory checkpointsCheckpoint therapyL1 antibodyImmune cellsNovel therapiesImmune activityAntagonist antibodyTumor growthTumor microenvironmentTumor cellsTherapyAntitumor activityAntibodiesCancerImmunotherapyCells
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