2016
Real-time Tumor Oxygenation Changes After Single High-dose Radiation Therapy in Orthotopic and Subcutaneous Lung Cancer in Mice: Clinical Implication for Stereotactic Ablative Radiation Therapy Schedule Optimization
Song C, Hong BJ, Bok S, Lee CJ, Kim YE, Jeon SR, Wu HG, Lee YS, Cheon GJ, Paeng JC, Carlson DJ, Kim HJ, Ahn GO. Real-time Tumor Oxygenation Changes After Single High-dose Radiation Therapy in Orthotopic and Subcutaneous Lung Cancer in Mice: Clinical Implication for Stereotactic Ablative Radiation Therapy Schedule Optimization. International Journal Of Radiation Oncology • Biology • Physics 2016, 95: 1022-1031. PMID: 27130790, DOI: 10.1016/j.ijrobp.2016.01.064.Peer-Reviewed Original ResearchConceptsStereotactic ablative radiation therapyTumor/brain ratiosAblative radiation therapyRadiation therapyDay 0Day 6Brain ratioSingle doseVascular collapseHigh-dose irradiationDay 2Single high-dose irradiationHigh-dose radiation therapyTumor hypoxiaSyngeneic Lewis lung carcinomaHoechst 33342 perfusionTumor oxygenation changesRadiation therapy schedulesLewis lung carcinomaOrthotopic lung tumorsOptimal fractionation schedulePositron emission tomography (PET) imagingEmission Tomography ImagingTumor hypoxia levelsFluorescence-activated cell
2014
Serial Imaging of Tumor Hypoxia in Early Stage Non-Small Cell Lung Cancer Patients Undergoing Stereotactic Body Radiotherapy
Kelada O, Decker R, Zheng M, Huang Y, Xia Y, Gallezot J, Liu C, Rockwell S, Carson R, Oelfke U, Carlson D. Serial Imaging of Tumor Hypoxia in Early Stage Non-Small Cell Lung Cancer Patients Undergoing Stereotactic Body Radiotherapy. International Journal Of Radiation Oncology • Biology • Physics 2014, 90: s26-s27. DOI: 10.1016/j.ijrobp.2014.05.126.Peer-Reviewed Original ResearchWE‐G‐BRD‐06: Variation in Dynamic Positron Emission Tomography Imaging of Tumor Hypoxia in Early Stage Non‐Small Cell Lung Cancer Patients Undergoing Stereotactic Body Radiotherapy
Kelada O, Decker R, Zheng M, Huang Y, Xia Y, Gallezot J, Liu C, Rockwell S, Carson R, Oelfke U, Carlson D. WE‐G‐BRD‐06: Variation in Dynamic Positron Emission Tomography Imaging of Tumor Hypoxia in Early Stage Non‐Small Cell Lung Cancer Patients Undergoing Stereotactic Body Radiotherapy. Medical Physics 2014, 41: 520-520. DOI: 10.1118/1.4889490.Peer-Reviewed Original ResearchNon-small cell lung cancer patientsCell lung cancer patientsPositron emission tomographyTumor hypoxic volumeLung cancer patientsCancer patientsHypoxic volumeEarly stage non-small cell lung cancer patientsTumor hypoxiaTumor vascular responseStereotactic body radiotherapyTotal tumor volumeNovel pilot studyEmission Tomography ImagingPositron emission tomography (PET) imagingDifferent time pointsTreatment failureFirst patientVascular responsesBody radiotherapyNSCLC tumorsTreatment individualizationBlood ratioTumor volumeSingle patientMolecular Imaging of Tumor Hypoxia with Positron Emission Tomography
Kelada OJ, Carlson DJ. Molecular Imaging of Tumor Hypoxia with Positron Emission Tomography. Radiation Research 2014, 181: 335-349. PMID: 24673257, PMCID: PMC5555673, DOI: 10.1667/rr13590.1.Peer-Reviewed Original ResearchConceptsTumor hypoxiaOncology communityTumor hypoxic volumeImportant prognostic factorOverall treatment responseRisk of metastasisTypes of tumorsEmission Tomography ImagingPositron emission tomography (PET) imagingClinical oncology communityPositron emission tomographyConventional cancer therapiesMagnitude of hypoxiaPrognostic factorsCancer patientsTreatment responseField of PETChemotherapy resistanceEmission tomographyClinical settingRadiolabelled agentsCancer typesPatientsHypoxia tracerHypoxia
2013
MO‐D‐141‐01: Quantification of Tumor Hypoxia Using [18F]‐Fluoromisonidazole Positron Emission Tomography and Tracer Kinetic Modeling
Kelada O, Rockwell S, Carson R, Decker R, Oelfke U, Carlson D. MO‐D‐141‐01: Quantification of Tumor Hypoxia Using [18F]‐Fluoromisonidazole Positron Emission Tomography and Tracer Kinetic Modeling. Medical Physics 2013, 40: 399-399. DOI: 10.1118/1.4815248.Peer-Reviewed Original ResearchPositron emission tomographyBlood ratioComputed tomographyFluoromisonidazole positron emission tomographyMale BALB/c miceEmission tomographyTumor hypoxiaBALB/c miceEMT-6 tumorsNon-invasive imaging methodVoxel basisTreatment failureC miceConventional tumorHypoxia quantificationHypoxic fractionAnaesthetized animalsTumorsHistologic sectionsPharmacokinetic modelPharmacokinetic modelingDynamic positron emission tomographyPET imagingHypoxic radioresistanceBetter delineation
2011
Tumor hypoxia is an important mechanism of radioresistance in hypofractionated radiotherapy and must be considered in the treatment planning process
Carlson DJ, Yenice KM, Orton CG. Tumor hypoxia is an important mechanism of radioresistance in hypofractionated radiotherapy and must be considered in the treatment planning process. Medical Physics 2011, 38: 6347-6350. PMID: 22149817, DOI: 10.1118/1.3639137.Peer-Reviewed Original Research
2010
Hypofractionation Results in Reduced Tumor Cell Kill Compared to Conventional Fractionation for Tumors With Regions of Hypoxia
Carlson DJ, Keall PJ, Loo BW, Chen ZJ, Brown JM. Hypofractionation Results in Reduced Tumor Cell Kill Compared to Conventional Fractionation for Tumors With Regions of Hypoxia. International Journal Of Radiation Oncology • Biology • Physics 2010, 79: 1188-1195. PMID: 21183291, PMCID: PMC3053128, DOI: 10.1016/j.ijrobp.2010.10.007.Peer-Reviewed Original ResearchConceptsTumor cell killingTumor hypoxiaCell killingRadiation fractionation schemesTumor biological effective doseBiological effective doseTumor cell killRegions of hypoxiaRadiotherapy regimenTreatment failureConventional fractionationNeck cancerStandard fractionationProstate cancerTumor cell populationFractionation schemeRadiation therapyTumor clonogensTumor oxygenationBlood vessels resultsCell killEffective doseAlternate fractionationResistant cellsHypoxia