2024
Association between family history with lung cancer incidence and mortality risk in the Asia Cohort Consortium
Kishida R, Yin X, Abe S, Rahman S, Saito E, Islam R, Lan Q, Blechter B, Rothman N, Sawada N, Tamakoshi A, Shu X, Hozawa A, Kanemura S, Kim J, Sugawara Y, Park S, Kweon S, Ahsan H, Boffetta P, Chia K, Matsuo K, Qiao Y, Zheng W, Inoue M, Kang D, Seow W. Association between family history with lung cancer incidence and mortality risk in the Asia Cohort Consortium. International Journal Of Cancer 2024, 156: 723-733. PMID: 39361428, PMCID: PMC11661513, DOI: 10.1002/ijc.35191.Peer-Reviewed Original ResearchFamily history of lung cancerAsia Cohort ConsortiumCohort ConsortiumLC incidenceSmoking statusFamily historyHazard ratioRisk of lung cancerIncreased risk of lung adenocarcinomaHistory of lung cancerConfidence intervalsLung cancer incidenceSignificant effect modificationEstimate hazard ratiosIncreased riskPopulation-based cohortCox proportional hazards regression modelsRisk of lung adenocarcinomaProspective cohort studyAssociated with increased riskLung cancerProportional hazards regression modelsEthnic groupsHazards regression modelsCancer incidenceEpigenome-wide association study of household air pollution exposure in an area with high lung cancer incidence.
Rahman M, Portengen L, Wong J, Breeze C, Blechter B, Hu W, Downward G, Zhang Y, Cardenas A, Ning B, Li J, Yang K, Hosgood H, Silverman D, Huang Y, Rothman N, Vermeulen R, Lan Q. Epigenome-wide association study of household air pollution exposure in an area with high lung cancer incidence. ISEE Conference Abstracts 2024, 2024 DOI: 10.1289/isee.2024.1088.Peer-Reviewed Original Research
2020
Is there an association between air pollution levels and lung cancer incidence?
Patel S, Chagpar A. Is there an association between air pollution levels and lung cancer incidence? Journal Of Clinical Oncology 2020, 38: e13584-e13584. DOI: 10.1200/jco.2020.38.15_suppl.e13584.Peer-Reviewed Original ResearchLung cancer incidence ratesLung cancer incidenceCancer incidence ratesMedian PMCancer incidenceIncidence rateProportion of smokersCountry-specific dataAir pollution levelsGlobal Cancer ObservatoryWorld Health OrganizationMedian ageRespiratory illnessTobacco useOlder populationSPSS version 26.0Health OrganizationVersion 26.0AgeLinear regression modelsIncidenceMultiple linear regression modelRegression modelsProportion of populationAssociation
2019
Cost-effectiveness of Canakinumab for Prevention of Recurrent Cardiovascular Events
Sehested T, Bjerre J, Ku S, Chang A, Jahansouz A, Owens D, Hlatky M, Goldhaber-Fiebert J. Cost-effectiveness of Canakinumab for Prevention of Recurrent Cardiovascular Events. JAMA Cardiology 2019, 4: 128-135. PMID: 30649147, PMCID: PMC6439626, DOI: 10.1001/jamacardio.2018.4566.Peer-Reviewed Original ResearchConceptsQuality-adjusted life yearsCost-effectiveness ratioIncremental cost-effectiveness ratioRecurrent cardiovascular eventsHealth-related quality of lifeStandard of careCanakinumab Anti-inflammatory Thrombosis Outcomes StudyHs-CRP levelsLung cancer incidenceHealth-related qualityMyocardial infarctionCardiovascular eventsRate of recurrent MIHealth care sector perspectiveReduced all-cause mortalityQuality of lifeAll-Cause MortalityCost-effectiveUS health care sector perspectiveHs-CRPCancer incidenceRisk of recurrent cardiovascular eventsMain OutcomesHigh-sensitivity C-reactive proteinSubstantial price reductions
2016
Differences in Active and Passive Smoking Exposures and Lung Cancer Incidence Between Veterans and Non-Veterans in the Women’s Health Initiative
Bastian LA, Gray KE, DeRycke E, Mirza S, Gierisch JM, Haskell SG, Magruder KM, Wakelee HA, Wang A, Ho GY, LaCroix AZ. Differences in Active and Passive Smoking Exposures and Lung Cancer Incidence Between Veterans and Non-Veterans in the Women’s Health Initiative. The Gerontologist 2016, 56: s102-s111. PMID: 26768384, PMCID: PMC5881614, DOI: 10.1093/geront/gnv664.Peer-Reviewed Original ResearchConceptsPassive smoking exposureWomen's Health InitiativeSmoking exposureLung cancer incidenceLung cancerWomen veteransHealth initiativesCancer incidenceHigh riskCox proportional hazards modelLung cancer incidence ratesOlder women veteransPassive tobacco exposureCancer incidence ratesProportional hazards modelHigh ratePostmenopausal womenPack yearsPassive smokingTobacco exposureProspective dataIncidence rateNon-VeteransTobacco useHazards model
2012
Chapter 12: Yale Lung Cancer Model
Holford TR, Ebisu K, McKay L, Oh C, Zheng T. Chapter 12: Yale Lung Cancer Model. Risk Analysis 2012, 32: s151-s165. PMID: 22882886, PMCID: PMC3662537, DOI: 10.1111/j.1539-6924.2011.01754.x.Peer-Reviewed Original ResearchConceptsLung cancer deathsCarcinogenesis modelCancer deathLung cancer incidenceLung cancer modelTwo-stage clonal expansion modelCigarette smokingCancer incidenceCancer modelTobacco controlClonal expansion modelPopulation ratesCohort modelSmokingDeathHarmful effectsPopulation dataTemporal trendsMortalityObserved numberIncidenceControl
2005
Predictors of Lung Cancer among Asbestos-exposed Men in the β-Carotene and Retinol Efficacy Trial
Cullen MR, Barnett MJ, Balmes JR, Cartmel B, Redlich CA, Brodkin CA, Barnhart S, Rosenstock L, Goodman GE, Hammar SP, Thornquist MD, Omenn GS. Predictors of Lung Cancer among Asbestos-exposed Men in the β-Carotene and Retinol Efficacy Trial. American Journal Of Epidemiology 2005, 161: 260-270. PMID: 15671258, DOI: 10.1093/aje/kwi034.Peer-Reviewed Original ResearchConceptsRetinol Efficacy TrialLung cancerEfficacy trialsAsbestos-exposed menStudy intervention armSubsequent lung cancerStrong independent predictorLung cancer incidenceLung cancer riskNormal lung parenchymaProportional hazards modelBaseline flow ratesRadiographic asbestosisIndependent predictorsStudy armsIntervention armVitamin supplementationPleural plaquesBaseline radiographsResidual confoundingCancer incidenceChest radiographsLung parenchymaLung carcinogenCancer risk
2003
Fruits, vegetables and lung cancer: A pooled analysis of cohort studies
Smith‐Warner S, Spiegelman D, Yaun S, Albanes D, Beeson WL, van den Brandt PA, Feskanich D, Folsom AR, Fraser GE, Freudenheim JL, Giovannucci E, Goldbohm RA, Graham S, Kushi LH, Miller AB, Pietinen P, Rohan TE, Speizer FE, Willett WC, Hunter DJ. Fruits, vegetables and lung cancer: A pooled analysis of cohort studies. International Journal Of Cancer 2003, 107: 1001-1011. PMID: 14601062, DOI: 10.1002/ijc.11490.Peer-Reviewed Original ResearchConceptsLung cancer riskCancer riskVegetable consumptionLung cancerRelative riskLung cancer risk factorsStudy-specific relative risksIncident lung cancer casesTotal fruitCancer risk factorsLung cancer incidenceLung cancer casesTotal vegetable consumptionRandom-effects modelCohort studyCurrent smokersSmoking habitsProspective studyQuintiles 2Pooled analysisLowest quintileResidual confoundingInverse associationRisk factorsCancer incidence
1996
A MODEL FOR THE EFFECT OF CIGARETTE SMOKING ON LUNG CANCER INCIDENCE IN CONNECTICUT
HOLFORD T, ZHANG Z, ZHENG T, MCKAY L. A MODEL FOR THE EFFECT OF CIGARETTE SMOKING ON LUNG CANCER INCIDENCE IN CONNECTICUT. Statistics In Medicine 1996, 15: 565-580. PMID: 8731001, DOI: 10.1002/(sici)1097-0258(19960330)15:6<565::aid-sim185>3.0.co;2-t.Peer-Reviewed Original ResearchConceptsLung cancer incidenceCancer incidenceIncidence rateLung cancer incidence ratesLung cancer incidence trendsEffect of smokingCancer incidence ratesCancer incidence trendsCohort studyCurrent smokersLevel of exposureMale smokersSmoking historySmoking subgroupsSmoking informationCigarette smokingMean durationSmoking prevalenceIncidence trendsSmokersSmokingPrevalenceCohort effectsAge distributionIncidence
1994
Time trend and the age‐period‐cohort effect on the incidence of histologic types of lung cancer in connecticut, 1960‐1989
Zheng T, Holford T, Boyle P, Chen Y, Ward B, Flannery J, Mayne S. Time trend and the age‐period‐cohort effect on the incidence of histologic types of lung cancer in connecticut, 1960‐1989. Cancer 1994, 74: 1556-1567. PMID: 8062189, DOI: 10.1002/1097-0142(19940901)74:5<1556::aid-cncr2820740511>3.0.co;2-0.Peer-Reviewed Original ResearchMeSH KeywordsAdenocarcinomaAdenocarcinoma, Bronchiolo-AlveolarAdultAge FactorsAgedAged, 80 and overCarcinomaCarcinoma, Small CellCarcinoma, Squamous CellCohort EffectCohort StudiesConnecticutFemaleHumansIncidenceLung NeoplasmsMaleMiddle AgedModels, StatisticalRegistriesSex FactorsSmokingTime FactorsConceptsAge-adjusted incidence ratesMajor histologic typesOverall age-adjusted incidence rateAge-specific incidence ratesHistologic typeLung cancer incidenceLung cancerIncidence rateBirth cohortRecent birth cohortsIncidence patternsObserved time trendsCell carcinomaCancer incidenceTime trendsConnecticut Tumor RegistryIncidence of adenocarcinomaSmall cell carcinomaSquamous cell carcinomaLung cancer casesRecent epidemiologic studiesDifferent histologic typesDifferent incidence patternsObserved incidence patternsTumor Registry
1992
Analysing the temporal effects of age, period and cohort
Holford T. Analysing the temporal effects of age, period and cohort. Statistical Methods In Medical Research 1992, 1: 317-337. PMID: 1341663, DOI: 10.1177/096228029200100306.Peer-Reviewed Original Research
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