Melissa C Friesen1, David C Wheeler2, Roel Vermeulen3, Sarah J Locke4, Dennis D Zaebst5, Stella Koutros4, Anjoeka Pronk6, Joanne S Colt4, Dalsu Baris4, Margaret R Karagas7, Nuria Malats8, Molly Schwenn9, Alison Johnson10, Karla R Armenti11, Nathanial Rothman4, Patricia A Stewart12, Manolis Kogevinas13, Debra T Silverman4. 1. 1.Occupational and Environmental Epidemiology Branch, Division of Cancer Epidemiology and Genetics, National Cancer Institute, Bethesda, MD 208952, USA; friesenmc@mail.nih.gov. 2. 2.Department of Biostatistics, Virginia Commonwealth University, Richmond, VA 23298, USA; 3. 3.Institute for Risk Assessment Sciences, Utrecht University, Utrecht, The Netherlands; 4. 1.Occupational and Environmental Epidemiology Branch, Division of Cancer Epidemiology and Genetics, National Cancer Institute, Bethesda, MD 208952, USA; 5. 4.Westat, Rockville, MD 20850, USA; 6. 5.TNO, 3700 Zeist, The Netherlands; 7. 6.Geisel School of Medicine at Dartmouth, Hanover, NH 03756, USA; 8. 7.Genetic and Molecular Epidemiology Group, Spanish National Cancer Research Center (CNIO), 28029 Madrid, Spain; 9. 8.Maine Cancer Registry, Augusta, ME 04333-0011, USA; 10. 9.Vermont Cancer Registry, Burlington, VT 05402-0070, USA; 11. 10.New Hampshire Department of Health and Human Services, Division of Public Health Services, Bureau of Public Health Statistics and Informatics, Concord, NH 03301, USA; 12. 11.Stewart Exposure Assessments LLC, Arlington, VA 22207, USA; 13. 12.Centre for Research in Environmental Epidemiology (CREAL), 08003 Barcelona, Spain; 13.CIBER Epidemiología y Salud Pública (CIBERESP), 28029 Barcelona, Spain; 14.IMIM (Hospital del Mar Medical Research Institute), 08003 Barcelona, Spain;
Abstract
OBJECTIVES: To efficiently and reproducibly assess occupational diesel exhaust exposure in a Spanish case-control study, we examined the utility of applying decision rules that had been extracted from expert estimates and questionnaire response patterns using classification tree (CT) models from a similar US study. METHODS: First, previously extracted CT decision rules were used to obtain initial ordinal (0-3) estimates of the probability, intensity, and frequency of occupational exposure to diesel exhaust for the 10 182 jobs reported in a Spanish case-control study of bladder cancer. Second, two experts reviewed the CT estimates for 350 jobs randomly selected from strata based on each CT rule's agreement with the expert ratings in the original study [agreement rate, from 0 (no agreement) to 1 (perfect agreement)]. Their agreement with each other and with the CT estimates was calculated using weighted kappa (κ w) and guided our choice of jobs for subsequent expert review. Third, an expert review comprised all jobs with lower confidence (low-to-moderate agreement rates or discordant assignments, n = 931) and a subset of jobs with a moderate to high CT probability rating and with moderately high agreement rates (n = 511). Logistic regression was used to examine the likelihood that an expert provided a different estimate than the CT estimate based on the CT rule agreement rates, the CT ordinal rating, and the availability of a module with diesel-related questions. RESULTS: Agreement between estimates made by two experts and between estimates made by each of the experts and the CT estimates was very high for jobs with estimates that were determined by rules with high CT agreement rates (κ w: 0.81-0.90). For jobs with estimates based on rules with lower agreement rates, moderate agreement was observed between the two experts (κ w: 0.42-0.67) and poor-to-moderate agreement was observed between the experts and the CT estimates (κ w: 0.09-0.57). In total, the expert review of 1442 jobs changed 156 probability estimates, 128 intensity estimates, and 614 frequency estimates. The expert was more likely to provide a different estimate when the CT rule agreement rate was <0.8, when the CT ordinal ratings were low to moderate, or when a module with diesel questions was available. CONCLUSIONS: Our reliability assessment provided important insight into where to prioritize additional expert review; as a result, only 14% of the jobs underwent expert review, substantially reducing the exposure assessment burden. Overall, we found that we could efficiently, reproducibly, and reliably apply CT decision rules from one study to assess exposure in another study. Published by Oxford University Press on behalf of the British Occupational Hygiene Society 2016.
OBJECTIVES: To efficiently and reproducibly assess occupational diesel exhaust exposure in a Spanish case-control study, we examined the utility of applying decision rules that had been extracted from expert estimates and questionnaire response patterns using classification tree (CT) models from a similar US study. METHODS: First, previously extracted CT decision rules were used to obtain initial ordinal (0-3) estimates of the probability, intensity, and frequency of occupational exposure to diesel exhaust for the 10 182 jobs reported in a Spanish case-control study of bladder cancer. Second, two experts reviewed the CT estimates for 350 jobs randomly selected from strata based on each CT rule's agreement with the expert ratings in the original study [agreement rate, from 0 (no agreement) to 1 (perfect agreement)]. Their agreement with each other and with the CT estimates was calculated using weighted kappa (κ w) and guided our choice of jobs for subsequent expert review. Third, an expert review comprised all jobs with lower confidence (low-to-moderate agreement rates or discordant assignments, n = 931) and a subset of jobs with a moderate to high CT probability rating and with moderately high agreement rates (n = 511). Logistic regression was used to examine the likelihood that an expert provided a different estimate than the CT estimate based on the CT rule agreement rates, the CT ordinal rating, and the availability of a module with diesel-related questions. RESULTS: Agreement between estimates made by two experts and between estimates made by each of the experts and the CT estimates was very high for jobs with estimates that were determined by rules with high CT agreement rates (κ w: 0.81-0.90). For jobs with estimates based on rules with lower agreement rates, moderate agreement was observed between the two experts (κ w: 0.42-0.67) and poor-to-moderate agreement was observed between the experts and the CT estimates (κ w: 0.09-0.57). In total, the expert review of 1442 jobs changed 156 probability estimates, 128 intensity estimates, and 614 frequency estimates. The expert was more likely to provide a different estimate when the CT rule agreement rate was <0.8, when the CT ordinal ratings were low to moderate, or when a module with diesel questions was available. CONCLUSIONS: Our reliability assessment provided important insight into where to prioritize additional expert review; as a result, only 14% of the jobs underwent expert review, substantially reducing the exposure assessment burden. Overall, we found that we could efficiently, reproducibly, and reliably apply CT decision rules from one study to assess exposure in another study. Published by Oxford University Press on behalf of the British Occupational Hygiene Society 2016.
Authors: Jérôme Lavoué; Javier Pintos; Martie Van Tongeren; Laurel Kincl; Lesley Richardson; T Kauppinen; Elisabeth Cardis; Jack Siemiatycki Journal: Occup Environ Med Date: 2012-04-01 Impact factor: 4.402
Authors: Melissa C Friesen; Joseph B Coble; Hormuzd A Katki; Bu-Tian Ji; Shouzheng Xue; Wei Lu; Patricia A Stewart Journal: Ann Occup Hyg Date: 2011-04-21
Authors: David C Wheeler; Kellie J Archer; Igor Burstyn; Kai Yu; Patricia A Stewart; Joanne S Colt; Dalsu Baris; Margaret R Karagas; Molly Schwenn; Alison Johnson; Karla Armenti; Debra T Silverman; Melissa C Friesen Journal: Ann Occup Hyg Date: 2014-11-27
Authors: Anjoeka Pronk; Patricia A Stewart; Joseph B Coble; Hormuzd A Katki; David C Wheeler; Joanne S Colt; Dalsu Baris; Molly Schwenn; Margaret R Karagas; Alison Johnson; Richard Waddell; Castine Verrill; Sai Cherala; Debra T Silverman; Melissa C Friesen Journal: Occup Environ Med Date: 2012-07-27 Impact factor: 4.402
Authors: C M Samanic; M Kogevinas; D T Silverman; A Tardón; C Serra; N Malats; F X Real; A Carrato; R García-Closas; M Sala; J Lloreta; N Rothman; M Dosemeci Journal: Occup Environ Med Date: 2007-10-19 Impact factor: 4.402
Authors: Lin Fritschi; Melissa C Friesen; Deborah Glass; Geza Benke; Jennifer Girschik; Troy Sadkowsky Journal: J Environ Public Health Date: 2009-10-15
Authors: Calvin B Ge; Melissa C Friesen; Hans Kromhout; Susan Peters; Nathaniel Rothman; Qing Lan; Roel Vermeulen Journal: Ann Work Expo Health Date: 2018-11-12 Impact factor: 2.179
Authors: Pabitra R Josse; Stella Koutros; Adonina Tardon; Nathaniel Rothman; Debra T Silverman; Melissa C Friesen Journal: Ann Work Expo Health Date: 2022-03-15 Impact factor: 2.779
Authors: Pamela J Dopart; Sarah J Locke; Pierluigi Cocco; Bryan A Bassig; Pabitra R Josse; Patricia A Stewart; Mark P Purdue; Qing Lan; Nathaniel Rothman; Melissa C Friesen Journal: Ann Work Expo Health Date: 2019-10-11 Impact factor: 2.179
Authors: Stella Koutros; Manolis Kogevinas; Melissa C Friesen; Patricia A Stewart; Dalsu Baris; Margaret R Karagas; Molly Schwenn; Alison Johnson; G M Monawar Hosain; Consol Serra; Adonina Tardon; Alfredo Carrato; Reina Garcia-Closas; Lee E Moore; Michael L Nickerson; Stephen M Hewitt; Petra Lenz; Alan R Schned; Josep Lloreta; Yves Allory; Haoyu Zhang; Nilanjan Chatterjee; Montserrat Garcia-Closas; Nathaniel Rothman; Núria Malats; Debra T Silverman Journal: Environ Int Date: 2019-12-18 Impact factor: 9.621
Authors: Albeliz Santiago-Colón; Carissa M Rocheleau; Stephen Bertke; Annette Christianson; Devon T Collins; Emma Trester-Wilson; Wayne Sanderson; Martha A Waters; Jennita Reefhuis Journal: Ann Work Expo Health Date: 2021-07-03 Impact factor: 2.179