2015
Role of Chitinase 3–like-1 and Semaphorin 7a in Pulmonary Melanoma Metastasis
Ma B, Herzog EL, Lee CG, Peng X, Lee CM, Chen X, Rockwell S, Koo JS, Kluger H, Herbst RS, Sznol M, Elias JA. Role of Chitinase 3–like-1 and Semaphorin 7a in Pulmonary Melanoma Metastasis. Cancer Research 2015, 75: 487-496. PMID: 25511377, PMCID: PMC4321965, DOI: 10.1158/0008-5472.can-13-3339.Peer-Reviewed Original ResearchConceptsMelanoma lung metastasisPulmonary melanoma metastasesPulmonary metastasesLung metastasesMelanoma metastasesGenetic deletionBreast cancer cellsPlexin C1 receptorsPulmonary microenvironmentPoor prognosisSemaphorin 7AMelanoma spreadChitinase 3MetastasisCHI3L1Cancer progressionSema7AInhibitory wayCancer cellsReceptorsSignificant reductionΒ1 integrinNovel pathwayCritical roleIL13Rα2
2009
Targeted drug delivery strategies to treat lung metastasis
Bar J, Herbst RS, Onn A. Targeted drug delivery strategies to treat lung metastasis. Expert Opinion On Drug Delivery 2009, 6: 1003-1016. PMID: 19663628, DOI: 10.1517/17425240903167926.Peer-Reviewed Original ResearchConceptsLung metastasesStandard clinical useMetastatic diseaseClinical trialsClinical useMost cancer patientsEarly clinical studiesCancer-specific antibodiesDrug delivery strategiesMain tumorTargeted drug delivery strategiesCancer patientsClinical studiesIntravascular devicesSolid tumorsMetastasisPreclinical developmentVascular fieldTreatmentTherapyTumorsAnticancer toolDiseaseDelivery strategiesTrials
2002
Targeted therapy against human lung cancer in nude mice by high-affinity recombinant antimesothelin single-chain Fv immunotoxin.
Fan D, Yano S, Shinohara H, Solorzano C, Van Arsdall M, Bucana CD, Pathak S, Kruzel E, Herbst RS, Onn A, Roach JS, Onda M, Wang QC, Pastan I, Fidler IJ. Targeted therapy against human lung cancer in nude mice by high-affinity recombinant antimesothelin single-chain Fv immunotoxin. Molecular Cancer Therapeutics 2002, 1: 595-600. PMID: 12479219.Peer-Reviewed Original ResearchMeSH KeywordsADP Ribose TransferasesAnimalsBacterial ToxinsDose-Response Relationship, DrugExotoxinsFlow CytometryHumansImmunoglobulin FragmentsImmunotherapyKineticsLung NeoplasmsMesothelinMiceMice, NudeMicroscopy, FluorescenceMutationNeoplasm TransplantationPseudomonasRecombinant ProteinsTumor Cells, CulturedVirulence FactorsConceptsTargeted therapyNude miceHuman non-small cell lung cancer cellsNon-small cell lung cancer cellsNCI-H226 cellsHuman lung cancer cell linesCell lung cancer cellsSquamous cell carcinomaLung cancer cell linesHuman lung cancerExperimental lung metastasisLung cancer cellsPC14PE6 cellsCancer cell linesLung metastasesCell carcinomaCancer patientsLung cancerOvarian cancerNontoxic doseMesothelinDay 7Recombinant immunotoxinCertain cancersCancer
1998
Paclitaxel/carboplatin administration along with antiangiogenic therapy in non-small-cell lung and breast carcinoma models
Herbst R, Takeuchi H, Teicher B. Paclitaxel/carboplatin administration along with antiangiogenic therapy in non-small-cell lung and breast carcinoma models. Cancer Chemotherapy And Pharmacology 1998, 41: 497-504. PMID: 9554595, DOI: 10.1007/s002800050773.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsAntineoplastic Combined Chemotherapy ProtocolsBone Marrow CellsCarboplatinCarcinoma, Lewis LungCell SurvivalColony-Forming Units AssayCyclohexanesDrug SynergismDrug Therapy, CombinationFemaleMaleMammary Neoplasms, ExperimentalMiceMice, Inbred BALB CMice, Inbred C57BLMinocyclineNeovascularization, PathologicO-(Chloroacetylcarbamoyl)fumagillolPaclitaxelSesquiterpenesConceptsTNP-470/minocyclineEMT-6 mammary carcinomaBone marrow CFU-GMLewis lung carcinomaMarrow CFU-GMEMT-6 tumor cellsLung carcinomaMammary carcinomaCFU-GMNormal tissuesTumor cellsHigh-dose paclitaxelCell lung cancerCombination of paclitaxelToxicity of carboplatinEfficacy of chemotherapyTumor growth delayBreast carcinoma modelCytotoxicity of carboplatinEarly time pointsAgent regimenAntiangiogenic regimenCarboplatin administrationLung metastasesCell lungPotential of the aminosterol, squalamine in combination therapy in the rat 13,762 mammary carcinoma and the murine Lewis lung carcinoma.
Teicher BA, Williams JI, Takeuchi H, Ara G, Herbst RS, Buxton D. Potential of the aminosterol, squalamine in combination therapy in the rat 13,762 mammary carcinoma and the murine Lewis lung carcinoma. Anticancer Research 1998, 18: 2567-73. PMID: 9703911.Peer-Reviewed Original ResearchMeSH Keywords9,10-Dimethyl-1,2-benzanthraceneAnimalsAnticarcinogenic AgentsAntineoplastic AgentsCarcinoma, Lewis LungCell DivisionCholestanolsCisplatinCombined Modality TherapyCyclophosphamideDoxorubicinDrug Therapy, CombinationFemaleFluorouracilMammary Neoplasms, ExperimentalMiceOxygenOxygen ConsumptionPaclitaxelPartial PressureRatsRats, Inbred F344ConceptsLewis lung carcinomaTumor growth delayPost-tumor implantationLung carcinomaGrowth delayLung metastasesTumor implantationMammary carcinomaTumor oxygenationDay 4Chemotherapeutic agentsPrimary Lewis lung tumorMurine Lewis lung carcinomaDaily subcutaneous injectionsLewis lung tumorTumor-bearing animalsModest effectCombination therapyContinuous infusionCytotoxic therapySystemic diseaseSubcutaneous injectionLung tumorsAntiangiogenic agentsHypoxic fraction
1997
PEG-hemoglobin: effects on tumor oxygenation and response to chemotherapy.
Teicher B, Ara G, Herbst R, Takeuchi H, Keyes S, Northey D. PEG-hemoglobin: effects on tumor oxygenation and response to chemotherapy. In Vivo 1997, 11: 301-11. PMID: 9292296.Peer-Reviewed Original ResearchConceptsPEG-hemoglobinTumor growth delayMammary carcinomaTumor cell killingSolid tumorsTumor oxygenationGrowth delayDose of chemotherapyEMT-6 murine mammary carcinomaBone marrow CFU-GMEfficacy of chemotherapyEMT-6 tumorsMurine mammary carcinomaTumor-bearing miceCFU-GM survivalMarrow CFU-GMCell killingOxygen delivery agentEMT-6 tumor-bearing miceChemotherapy administrationLung metastasesMultiple dosesSingle dosesChemotherapyCFU-GM