2020
[11C]Methionine and [11C]PBR28 as PET Imaging Tracers to Differentiate Metastatic Tumor Recurrence or Radiation Necrosis
Tran TT, Gallezot JD, Jilaveanu LB, Zito C, Turcu G, Lim K, Nabulsi N, Huang H, Huttner A, Kluger HM, Chiang VL, Carson R. [11C]Methionine and [11C]PBR28 as PET Imaging Tracers to Differentiate Metastatic Tumor Recurrence or Radiation Necrosis. Molecular Imaging 2020, 19: 1536012120968669. PMID: 33147119, PMCID: PMC7649862, DOI: 10.1177/1536012120968669.Peer-Reviewed Original ResearchConceptsRadiation necrosisTumor regrowthStereotactic radiosurgeryBrain metastasesPET tracersHigh amino acid uptakeMetastatic tumor recurrenceLung cancer cellsSpecific PET tracersPET imaging tracerTumor recurrenceAmino acid uptakeImaging tracerReliable markerDiagnostic imagingLack of specificityAcid uptakeCancer cellsSpecific markersMethionine levelsTranslocator proteinSequential imagingInflammationMetastasisDual tracer
2016
Demonstration of differential radiosensitivity based upon mutation profile in metastatic melanoma treated with stereotactic radiosurgery.
Rutter CE, Johung KL, Yao X, Lu AY, Jilaveanu LB, Yu JB, Contessa JN, Kluger HM, Chiang VLS, Bindra RS. Demonstration of differential radiosensitivity based upon mutation profile in metastatic melanoma treated with stereotactic radiosurgery. Journal Of Radiosurgery And SBRT 2016, 4: 97-106. PMID: 29296434, PMCID: PMC5658871.Peer-Reviewed Original ResearchWild-type patientsC-kit mutationsLocal recurrenceMetastatic melanomaBrain metastasesType patientsN-RASCox proportional hazards modelMelanoma brain metastasesImproved local controlLocal recurrence rateProportional hazards modelN-RAS mutationsB-RafDifferential radiosensitivityDistant failureRecurrence rateImportant treatmentStereotactic radiosurgeryHazards modelPatientsLocal controlMultivariate analysisStandardized imagingRecurrence