Validity of retrospective occupational exposure estimates of lead and manganese in a case–control study

Objectives The validity of surrogate measures of retrospective occupational exposure in population-based epidemiological studies has rarely been evaluated. Using toenail samples as bioindicators of exposure, we assessed whether work tasks and expert assessments of occupational metal exposure obtained from personal interviews were associated with lead and manganese concentrations. Methods We selected 609 controls from a case–control study of bladder cancer in New England who had held a job for ≥1 year 8–24 months prior to toenail collection. We evaluated associations between toenail metal concentrations and five tasks extracted from occupational questionnaires (grinding, painting, soldering, welding, working near engines) using linear regression models. For 139 subjects, we also evaluated associations between the toenail concentrations and exposure estimates from three experts. Results We observed a 1.9-fold increase (95% CI 1.4 to 2.5) in toenail lead concentrations with painting and 1.4-fold increase (95% CI 1.1 to 1.7) in manganese concentrations with working around engines and handling fuel. We observed significant trends with increasing frequency of both activities. For lead, significant trends were observed with the ratings from all three experts. Their average ratings showed the strongest association, with subjects rated as possibly or probably exposed to lead having concentrations that were 2.0 and 2.5 times higher, respectively, than in unexposed subjects (ptrend <0.001). Expert estimates were only weakly associated with manganese toenail concentrations. Conclusions Our findings support the ability of experts to identify broad contrasts in previous occupational exposure to lead. The stronger associations with task frequency and expert assessments support using refined exposure characterisation whenever possible.

[1]  Ahmad Mujahid Ahmad Zaidi,et al.  Heavy metals found in the breathing zone, toenails and lung function of welders working in an air-conditioned welding workplace , 2018, International journal of occupational safety and ergonomics : JOSE.

[2]  N. Rothman,et al.  Use and Reliability of Exposure Assessment Methods in Occupational Case–Control Studies in the General Population: Past, Present, and Future , 2018, Annals of work exposures and health.

[3]  R. Pacifici,et al.  Nails in Forensic Toxicology: An Update. , 2018, Current pharmaceutical design.

[4]  Mahmoud M Nour,et al.  Toenail Manganese: A Sensitive and Specific Biomarker of Exposure to Manganese in Career Welders , 2017, Annals of work exposures and health.

[5]  Sarah J. Locke,et al.  Evaluating predictors of lead exposure for activities disturbing materials painted with or containing lead using historic published data from U.S. workplaces , 2017, American journal of industrial medicine.

[6]  Sarah J. Locke,et al.  Validity of expert assigned retrospective estimates of occupational polychlorinated biphenyl exposure. , 2015, The Annals of occupational hygiene.

[7]  Sarah J. Locke,et al.  Lead exposure in US worksites: A literature review and development of an occupational lead exposure database from the published literature. , 2015, American journal of industrial medicine.

[8]  S. Praveena,et al.  Toenail as a biomarker of heavy metal exposure via drinking water: a systematic review , 2014, Reviews on environmental health.

[9]  I. Bergdahl,et al.  Chapter 43 – Lead , 2015 .

[10]  M. Baumgartner Nails: an adequate alternative matrix in forensic toxicology for drug analysis? , 2014, Bioanalysis.

[11]  Sarah J. Locke,et al.  Evaluating temporal trends from occupational lead exposure data reported in the published literature using meta-regression. , 2014, The Annals of occupational hygiene.

[12]  David C Christiani,et al.  Toenail Metal Concentration as a Biomarker of Occupational Welding Fume Exposure , 2014, Journal of occupational and environmental hygiene.

[13]  L. Sheppard,et al.  Blood Manganese as an Exposure Biomarker: State of the Evidence , 2014, Journal of occupational and environmental hygiene.

[14]  H. Neels,et al.  Nail analysis for the detection of drugs of abuse and pharmaceuticals: a review , 2014, Forensic Toxicology.

[15]  Wei Lu,et al.  Validity and reliability of exposure assessors' ratings of exposure intensity by type of occupational questionnaire and type of rater. , 2011, The Annals of occupational hygiene.

[16]  Xihong Lin,et al.  Toenail, Blood, and Urine as Biomarkers of Manganese Exposure , 2011, Journal of occupational and environmental medicine.

[17]  Margaret R Karagas,et al.  Occupation and bladder cancer in a population-based case–control study in Northern New England , 2010, Occupational and Environmental Medicine.

[18]  S. Yaemsiri,et al.  Growth rate of human fingernails and toenails in healthy American young adults , 2010, Journal of the European Academy of Dermatology and Venereology : JEADV.

[19]  Muci Jose Chali Zarzar Are the threshold limit values (TLVS®) for lifting proposed by the American Conference of Governmental Industrial Hygienists independent of gender and anthropometry? , 2010 .

[20]  H. Kromhout,et al.  Inter-rater agreement in the assessment of exposure to carcinogens in the offshore petroleum industry , 2007, Occupational and Environmental Medicine.

[21]  A. Kodali,et al.  Investigation of Job-Related Pesticide Exposure in the Third National Health and Nutrition Examination Survey , 2006, Archives of environmental & occupational health.

[22]  A. J. Bailer,et al.  Trends in occupational lead exposure since the 1978 OSHA lead standard. , 2004, American journal of industrial medicine.

[23]  J. Siemiatycki,et al.  Validation of expert assessment of occupational exposures. , 2003, American journal of industrial medicine.

[24]  A. Olshan,et al.  Occupational exposure assessment in case–control studies: opportunities for improvement , 2002, Occupational and environmental medicine.

[25]  S. Semple,et al.  A training exercise in subjectively estimating inhalation exposures. , 2001, Scandinavian journal of work, environment & health.

[26]  T. Tosteson,et al.  Measurement of low levels of arsenic exposure: a comparison of water and toenail concentrations. , 2000, American journal of epidemiology.

[27]  H Kromhout,et al.  Assessment of occupational exposures in a general population: comparison of different methods. , 1999, Occupational and environmental medicine.

[28]  G. Benke,et al.  Retrospective assessment of occupational exposure to chemicals in community-based studies: validity and repeatability of industrial hygiene panel ratings. , 1997, International journal of epidemiology.

[29]  J. Siemiatycki,et al.  Reliability of an expert rating procedure for retrospective assessment of occupational exposures in community-based case-control studies. , 1997, American journal of industrial medicine.

[30]  Michigan.,et al.  Toxicological profile for dichloropropenes , 2008 .

[31]  Gunnar F. Nordberg,et al.  Handbook on the Toxicology of Metals , 1979 .