2020
A general-purpose Monte Carlo particle transport code based on inverse transform sampling for radiotherapy dose calculation
Liang Y, Muhammad W, Hart GR, Nartowt BJ, Chen ZJ, Yu JB, Roberts KB, Duncan JS, Deng J. A general-purpose Monte Carlo particle transport code based on inverse transform sampling for radiotherapy dose calculation. Scientific Reports 2020, 10: 9808. PMID: 32555530, PMCID: PMC7300009, DOI: 10.1038/s41598-020-66844-7.Peer-Reviewed Original ResearchConceptsPhoton transportBoundary crossing algorithmMonte Carlo particle transport codeMonte Carlo methodTransport simulationsAcceptance-rejection samplingRadiotherapy dose calculationsPhoto-electric effectParticle transport codeEGSnrc simulationsCarlo methodBremsstrahlung eventsInelastic scatteringPair productionRayleigh scatteringThread divergenceMC simulationsTransport codeMC codeHistory schemeParticle transportCrossing algorithmInverseElectron transportSimulation accuracyA prototype open-ended multichannel intracavitary-interstitial hybrid applicator for gynecological high-dose-rate brachytherapy
Tien CJ, Chen Z. A prototype open-ended multichannel intracavitary-interstitial hybrid applicator for gynecological high-dose-rate brachytherapy. Radiological Physics And Technology 2020, 13: 187-194. PMID: 32424632, DOI: 10.1007/s12194-020-00567-2.Peer-Reviewed Original ResearchConceptsPrescription doseRate brachytherapyHybrid applicatorPrior patientsRisk doseMinimum doseOAR D2ccMultichannel applicatorCentral tandemDoseTarget coverageInterstitial needlesPatientsApplicator bodyBrachytherapyDistal endOpen distal endsPeripheral needlesPeripheral channelsSilico studiesNeedleBowelBladderD2ccRectum
2018
Monte Carlo dosimetry modeling of focused kV x‐ray radiotherapy of eye diseases with potential nanoparticle dose enhancement
Yan H, Ma X, Sun W, Mendez S, Stryker S, Starr‐Baier S, Delliturri G, Zhu D, Nath R, Chen Z, Roberts K, MacDonald CA, Liu W. Monte Carlo dosimetry modeling of focused kV x‐ray radiotherapy of eye diseases with potential nanoparticle dose enhancement. Medical Physics 2018, 45: 4720-4733. PMID: 30133705, DOI: 10.1002/mp.13144.Peer-Reviewed Original ResearchConceptsX-ray beamMC simulation programEye plaque treatmentCentral axis depth doseMC simulationsDose distributionBeam focusingEye Physics plaquesPhantom irradiationDose enhancementEnergy spectrumDepth doseLens modelingDosimetry modelingPhotoelectric absorptionKV rangeKV X-ray beamsBeamEBT3 filmSimulation programEnergy regimeModelingX-ray techniquesHalf maximumMore flexibility
2015
Concomitant Imaging Dose and Cancer Risk in Image Guided Thoracic Radiation Therapy
Zhang Y, Wu H, Chen Z, Knisely JP, Nath R, Feng Z, Bao S, Deng J. Concomitant Imaging Dose and Cancer Risk in Image Guided Thoracic Radiation Therapy. International Journal Of Radiation Oncology • Biology • Physics 2015, 93: 523-531. PMID: 26460994, DOI: 10.1016/j.ijrobp.2015.06.034.Peer-Reviewed Original ResearchMeSH KeywordsAdolescentAdultAge FactorsAgedAged, 80 and overAorta, ThoracicBody SizeBreastChildChild, PreschoolCone-Beam Computed TomographyFemaleHeartHumansLungMaleMiddle AgedMonte Carlo MethodOrgans at RiskPhantoms, ImagingPhotonsPrecision MedicineProtonsRadiation DosageRadiography, ThoracicRadiotherapy, Image-GuidedRisk AssessmentSex FactorsSpinal CordThoracic WallThoraxConceptsConcomitant imaging doseThoracic radiation therapyCancer riskRadiation therapyMean dosesCardiac substructuresKilovoltage cone-beamImaging doseAdverse eventsPediatric patientsMedian dosesCancer patientsRight ventricleExtra radiation doseSpinal cordHigh dosesPatientsCone beamPlanning CT imagesChest dimensionsDosesPatient sizeImaging guidanceTherapyDose
2011
Kilovoltage Imaging Doses in the Radiotherapy of Pediatric Cancer Patients
Deng J, Chen Z, Roberts KB, Nath R. Kilovoltage Imaging Doses in the Radiotherapy of Pediatric Cancer Patients. International Journal Of Radiation Oncology • Biology • Physics 2011, 82: 1680-1688. PMID: 21477943, DOI: 10.1016/j.ijrobp.2011.01.062.Peer-Reviewed Original ResearchConceptsPediatric cancer patientsCancer patientsTesticular shieldingSpinal cordKilovoltage cone-beamCBCT dosesMean dosesClinical conditionsDose reductionLarge dosesFemoral headPatientsCBCT scansCone beamDosesFull-fan modeOptical nerveCBCT fieldCordDose increaseImaging dosesScanning protocolOARsRadiotherapyHalf-fan mode
2010
A systematic evaluation of the dose-rate constant determined by photon spectrometry for 21 different models of low-energy photon-emitting brachytherapy sources
Chen Z, Nath R. A systematic evaluation of the dose-rate constant determined by photon spectrometry for 21 different models of low-energy photon-emitting brachytherapy sources. Physics In Medicine And Biology 2010, 55: 6089-6104. PMID: 20871136, PMCID: PMC3265933, DOI: 10.1088/0031-9155/55/20/004.Peer-Reviewed Original ResearchImpact of source‐production revision on the dose‐rate constant of interstitial brachytherapy sources
Chen Z, Bongiorni P, Nath R. Impact of source‐production revision on the dose‐rate constant of interstitial brachytherapy sources. Medical Physics 2010, 37: 3607-3610. PMID: 20831068, PMCID: PMC2902542, DOI: 10.1118/1.3453766.Peer-Reviewed Original Research
2006
Application of Gafchromic® film in the dosimetry of an intravascular brachytherapy source
Song H, Roa DE, Yue N, d'Errico F, Chen Z, Nath R. Application of Gafchromic® film in the dosimetry of an intravascular brachytherapy source. Medical Physics 2006, 33: 2519-2524. PMID: 16898455, DOI: 10.1118/1.2208930.Peer-Reviewed Original ResearchEvaluation of the EDR-2 film for relative dosimetry of high-energy photon and electron beams
Ahmad M, Chen Z, Song H, Deng J, Nath R. Evaluation of the EDR-2 film for relative dosimetry of high-energy photon and electron beams. Radiation Protection Dosimetry 2006, 120: 159-162. PMID: 16644932, DOI: 10.1093/rpd/ncj006.Peer-Reviewed Original ResearchConceptsEDR-2 filmsElectron beamRelative dosimetryHigh-energy photonsClinical radiation dosimetryDose profilesPhotonsRadiation dosimetryBeamDose distributionRadiographic filmsSensitometric studyFilmsDosimetryTreatment planning techniquesElectronsDiodesSymmetryKVFlatnessPlanning techniquesDistribution
2004
Iodine 125 Versus Palladium 103 Implants for Prostate Cancer
Peschel RE, Colberg JW, Chen Z, Nath R, Wilson LD. Iodine 125 Versus Palladium 103 Implants for Prostate Cancer. The Cancer Journal 2004, 10: 170-174. PMID: 15285926, DOI: 10.1097/00130404-200405000-00006.Peer-Reviewed Original ResearchConceptsExternal beam radiation therapyMinimum tumor doseDisease-free survival ratesComplication rateTumor doseProstate cancerRadiation therapyClinical outcomesPrognostic groupsBiochemical disease-free survival ratesSurvival rateBiochemical disease-free survivalDisease-free survivalHigh complication ratePoor prognostic groupProstate-specific antigenHormonal therapyT stageGleason scoreSingle institutionTransperineal implantationFavorable groupGrade 3Treatment groupsPatients