2019
Rapid Production of Physiologic Dendritic Cells (phDC) for Immunotherapy
Hanlon D, Sobolev O, Han P, Ventura A, Vassall A, Kibbi N, Yurter A, Robinson E, Filler R, Tatsuno K, Edelson RL. Rapid Production of Physiologic Dendritic Cells (phDC) for Immunotherapy. Methods In Molecular Biology 2019, 2097: 173-195. PMID: 31776926, DOI: 10.1007/978-1-0716-0203-4_11.Peer-Reviewed Original ResearchConceptsPeripheral blood mononuclear cellsAntigen-presenting cellsDendritic cellsTumor-associated antigensBlood monocytesDC populationsExtracorporeal photochemotherapyCytokine-derived DCsSource of DCDendritic antigen-presenting cellsHuman peripheral blood mononuclear cellsFunctional antigen-presenting cellsVivo T cell stimulationBlood mononuclear cellsMurine bone marrow precursorsApoptotic tumor cellsT cell stimulationBone marrow precursorsCancer immunotherapyDC differentiationMononuclear cellsIL-4Clinical vaccinationMonocyte activationSupraphysiologic concentrationsNovel Protocol for Generating Physiologic Immunogenic Dendritic Cells.
Ventura A, Vassall A, Yurter A, Robinson E, Filler R, Hanlon D, Meeth K, Ezaldein H, Girardi M, Sobolev O, Bosenberg MW, Edelson RL. Novel Protocol for Generating Physiologic Immunogenic Dendritic Cells. Journal Of Visualized Experiments 2019 PMID: 31157760, DOI: 10.3791/59370.Peer-Reviewed Original ResearchConceptsCutaneous T-cell lymphomaDendritic cellsCellular vaccinesClinical efficacyAnti-tumor T cell immunityVivo anti-tumor responsesMonocyte-derived dendritic cellsTumor cellsSyngeneic mouse tumor modelsImmunogenic dendritic cellsAnti-cancer immunityT cell immunityAnti-tumor responseHuman dendritic cellsT-cell lymphomaAnti-tumor effectsKey mechanistic driversApoptotic tumor cellsMouse tumor modelsCell immunitySafety profileCancer immunotherapyCell lymphomaMouse modelBlood samples
2018
Extracorporeal Photochemotherapy Drives Monocyte-to-Dendritic Cell Maturation to Induce Anti-Cancer Immunity
Ventura A, Vassall A, Robinson E, Filler R, Hanlon D, Meeth K, Ezaldein H, Girardi M, Sobolev O, Bosenberg MW, Edelson RL. Extracorporeal Photochemotherapy Drives Monocyte-to-Dendritic Cell Maturation to Induce Anti-Cancer Immunity. Cancer Research 2018, 78: canres.0171.2018. PMID: 29764863, DOI: 10.1158/0008-5472.can-18-0171.Peer-Reviewed Original ResearchConceptsT cellsT cell antitumor immunityTumor-specific T cellsTumor cellsEffective immunotherapeutic agentFavorable safety profileResponder T cellsDendritic cell differentiationTumor-challenged miceImmunogenic cell deathSelective antitumor effectApoptotic tumor cellsPotential therapeutic applicabilityProcessing/presentationAntimelanoma immunityHealthy DCsImmunogenic malignanciesAntitumor immunityCellular vaccinesImmunotherapeutic effectsAdditional malignanciesImmunotherapeutic agentsSafety profileCancer immunotherapyTumor antigens
2012
Optimization of Stability, Encapsulation, Release, and Cross-Priming of Tumor Antigen-Containing PLGA Nanoparticles
Prasad S, Cody V, Saucier-Sawyer JK, Fadel TR, Edelson RL, Birchall MA, Hanlon DJ. Optimization of Stability, Encapsulation, Release, and Cross-Priming of Tumor Antigen-Containing PLGA Nanoparticles. Pharmaceutical Research 2012, 29: 2565-2577. PMID: 22798259, PMCID: PMC4075113, DOI: 10.1007/s11095-012-0787-4.Peer-Reviewed Original Research
2007
Polymer Nanoparticles for Immunotherapy from Encapsulated Tumor-Associated Antigens and Whole Tumor Cells
Solbrig CM, Saucier-Sawyer JK, Cody V, Saltzman WM, Hanlon DJ. Polymer Nanoparticles for Immunotherapy from Encapsulated Tumor-Associated Antigens and Whole Tumor Cells. Molecular Pharmaceutics 2007, 4: 47-57. PMID: 17217312, DOI: 10.1021/mp060107e.Peer-Reviewed Original ResearchConceptsPolymer nanoparticlesMixture of proteinsMolecular weight polymersRate of nanoparticlesProtein loadingEfficiency of encapsulationWeight polymersDissolved nanoparticlesNanoparticle formulationDifferent particle loadingsRelease propertiesNanoparticlesPreparation methodEncapsulation efficiencyComplex mixturesMolecular weightSDS-acrylamide gel electrophoresisSolvent extractionProtein assaysAgEncapsulationParticle loadingMixtureSpectrum of proteinsPromising approach
2005
Enhanced and prolonged cross‐presentation following endosomal escape of exogenous antigens encapsulated in biodegradable nanoparticles
Shen H, Ackerman AL, Cody V, Giodini A, Hinson ER, Cresswell P, Edelson RL, Saltzman WM, Hanlon DJ. Enhanced and prolonged cross‐presentation following endosomal escape of exogenous antigens encapsulated in biodegradable nanoparticles. Immunology 2005, 117: 78-88. PMID: 16423043, PMCID: PMC1782199, DOI: 10.1111/j.1365-2567.2005.02268.x.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsAntigen PresentationB-LymphocytesBiocompatible MaterialsBiodegradation, EnvironmentalCell LineCross-PrimingDendritic CellsEndosomesHistocompatibility Antigens Class IIHumansLactic AcidLymphocyte ActivationMiceMice, Inbred C57BLNanostructuresOvalbuminPolyglycolic AcidPolylactic Acid-Polyglycolic Acid CopolymerPolymersSerum Albumin, BovineT-LymphocytesConceptsBone marrow-derived dendritic cellsMHC class I presentationAntigen-presenting cellsClass I presentationMHC class IExogenous antigensDendritic cellsClass IAntigen deliveryPrimary mouse bone marrow-derived dendritic cellsSoluble antigenMouse bone marrow-derived dendritic cellsMarrow-derived dendritic cellsProfessional antigen-presenting cellsMajor histocompatibility complex class IProtein-based vaccinationT cell responsesClassic MHC class IExogenous antigen presentationHistocompatibility complex class IAntigen-coated latex beadsCell-associated antigensInterleukin-2 secretionComplex class IEfficiency of presentation