2016
Increased Nanoparticle Delivery to Brain Tumors by Autocatalytic Priming for Improved Treatment and Imaging
Han L, Kong DK, Zheng MQ, Murikinati S, Ma C, Yuan P, Li L, Tian D, Cai Q, Ye C, Holden D, Park JH, Gao X, Thomas JL, Grutzendler J, Carson RE, Huang Y, Piepmeier JM, Zhou J. Increased Nanoparticle Delivery to Brain Tumors by Autocatalytic Priming for Improved Treatment and Imaging. ACS Nano 2016, 10: 4209-4218. PMID: 26967254, PMCID: PMC5257033, DOI: 10.1021/acsnano.5b07573.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsAntineoplastic AgentsBiological TransportBlood-Brain BarrierBrain NeoplasmsCell Line, TumorDecanoic AcidsDrug Delivery SystemsEthanolaminesFemaleGenetic TherapyHeterograftsHumansMatrix Metalloproteinase 2MiceMice, Inbred C57BLNanoparticlesOptical ImagingPaclitaxelPermeabilityPolymersPurinesPyrazolesScorpion VenomsTranscytosisTumor MicroenvironmentConceptsBlood-brain barrierLow delivery efficiencyTransport of nanoparticlesCancer gene therapyNanoparticle deliveryMore nanoparticlesBrain tumorsNanoparticlesDelivery efficiencyGene therapySystemic deliveryNPsBrain malignanciesBBB modulatorsPharmacological agentsBrain cancerBrain regionsTumorsDeliveryBrainImproved treatmentInadequate amountsPositive feedback loopChemotherapyMalignancy
2011
Biodegradable poly(amine-co-ester) terpolymers for targeted gene delivery
Zhou J, Liu J, Cheng CJ, Patel TR, Weller CE, Piepmeier JM, Jiang Z, Saltzman WM. Biodegradable poly(amine-co-ester) terpolymers for targeted gene delivery. Nature Materials 2011, 11: 82-90. PMID: 22138789, PMCID: PMC4180913, DOI: 10.1038/nmat3187.Peer-Reviewed Original ResearchConceptsGene deliveryNon-viral gene deliveryEfficient gene deliveryGene delivery abilityTargeted gene deliveryHighest molecular weight terpolymerDelivery abilityTargeted deliveryLipofectamine 2000Dialkyl diesterVivo applicationsPolycationic vectorsSpecific ring sizesTRAIL geneHigh efficiencyCharge densityLow charge densityDeliveryPolyethylenimineMinimal toxicityEfficiencyHydrophobicityLactone contentDensityApplications
1996
Targeting microtubule-associated proteins in glioblastoma: A new strategy for selective therapy
Piepmeier J, Pedersen P, Yoshida D, Greer C. Targeting microtubule-associated proteins in glioblastoma: A new strategy for selective therapy. Annals Of Surgical Oncology 1996, 3: 543-549. PMID: 8915486, DOI: 10.1007/bf02306087.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsAntineoplastic Agents, AlkylatingBrain NeoplasmsCarrier ProteinsCell LineColony-Forming Units AssayEstramustineFlow CytometryGlioblastomaHumansImmunohistochemistryMiceMice, NudeMicrotubule-Associated ProteinsNeoplasm TransplantationRadiation-Sensitizing AgentsThymidineTransplantation, HeterologousTumor Cells, CulturedConceptsSubcutaneous xenograftsGlioblastoma cellsHuman glioblastoma cellsMicrotubule-associated proteinsHuman glioblastomaPotent antimitotic effectsUse of estramustineAntimicrotubule agentsEstramustine-binding proteinPreclinical dataEstramustineNeoplastic cellsAntiproliferative effectsSelective therapyGlioma cellsAntimitotic effectCytotoxic effectsGlioblastomaUseful targetTherapyXenograftsLaboratory investigationsSelective effectAntimitotic activityCellsIn vitro and in vivo inhibition of glioblastoma and neuroblastoma with MDL101731, a novel ribonucleoside diphosphate reductase inhibitor.
Piepmeier J, Rabidou N, Schold S, Bitonti A, Prakash N, Bush T. In vitro and in vivo inhibition of glioblastoma and neuroblastoma with MDL101731, a novel ribonucleoside diphosphate reductase inhibitor. Cancer Research 1996, 56: 359-61. PMID: 8542592.Peer-Reviewed Original ResearchConceptsMalignant brain tumorsMedian survivalControl animalsAthymic miceBrain tumorsReductase inhibitorsHuman malignant brain tumorsHuman glioblastomaDays of treatmentSK-N-MCConcentration-dependent inhibitionTumor regressionIntracerebral implantsIntracerebral xenograftsXenograft modelGlioblastoma cell linesVivo inhibitionPotent antiproliferative activityNeuroblastomaGlioblastomaSurvivalCell linesXenograftsNanomolar concentrationsTumors