Table 3.
Studies of IMIS exposure data having reported results related to potential biases.
| Publication | Main focus | Exposure metric | Variables studied | Bias |
|---|---|---|---|---|
| Oudiz et al. 1983 | silica exposures in foundries | % of exposures above PEL, severity | work area, type of foundry, number of employees | fraction of overexposures increasing with number of employees |
| Jones 1986 | under reporting in IMIS | % of samples in OSHA reports ending up in IMIS | N.A. | slightly fewer than 50% of compliance data reported in IMIS, 25% of plants with compliance data do not appear in IMIS, under-reporting does not seem related to level of exposure |
| Froines et al. 1986a | general portrait of silica exposure | severity | industry, union status, inspection type, job description | despite between-industry differences, general trend of higher probability of being >PEL for complaint inspections, especially in unionized companies. No consistent trend for mean severity. |
| Stewart et al. 1990 | use of IMIS for occupational epidemiologic studies | concentration | industry, job description | SIC specific measurement arithmetic mean higher for complaint inspections (median ratio of 2.4, 3 out of ten ratios less than 1) |
| Froines et al. 1990 | general portrait of lead exposure | median severity by inspection | industry, number of employees, union status, inspection type | odds ratio of 3 for complaint inspections versus scheduled for the probability of a median severity within an inspection to be greater than 1 |
| Gomez 1997 | association between IMIS variables and reported exposure levels | concentration, company specific mean concentration, probability of being greater than a specified value | job description, number of employees, union status, year, scope of inspection, type of inspection | clear trend for number of employees (exposure level decrease when number of employees increase : GMs for large companies (>273 employees) are 30–40% of those from small company (<60 employees) |
| Tanner-Martinez 1997 | effect of non-random sampling on estimation of exposure variability from IMIS data | company-specific geometric standard deviation | auto-correlation structures | GSDs smaller when estimated from few samples (n smaller than 6) or from samples within a small time period (week) |
| Melville and Lippman 2001 | association between IMIS variables and reported exposure levels | concentration, company specific mean concentration, probability of being greater than a specified value | job description, number of employees, union status, year, scope of inspection, type of inspection | variable results. General trend of higher levels for general scope inspections. For toluene and formaldehyde, levels associated with complaint inspections higher versus scheduled. Quantitative estimates no provided. |
| Lurie and Wolfe 2002 | general portrait of exposure to hexavalent chromium | concentration, number of measurements, citations | year, industry, inspection type, inspection conducted by federal or state agency | greater % of non-detects in state inspections (59.8% versus 48.9%) compared to federal inspections. |
| Middendorf 2004 | surveillance of occupational noise exposure | several noise exposure metrics | year, number of employees, | noise levels increase with number of employees (shift of 2–3 dBA from <20 to >499 employees). Mean consultation levels > mean enforcement levels (up to 4 dBA depending on year, average ~2) |
| Okun et al. 2004 | trends in occupational lead exposure | probability of a measurement exceeding the PEL | year, region, number of employees, union status, inspection type | probability of being higher than PEL slightly higher for compliance data than for consultation data (between 1 and 5% across years), and for complaint inspection than for general schedule inspections (estimate of 5% from logistic regression) |
| Yassin et al. 2005 | general portrait of exposure to silica dust | concentration | year, industry, job description, inspection type | programmed inspection industry specific geometric means slightly higher than overall industry specific GMs (0.077 versus 0.073mg/m3) |
| Lavoué et al. 2008 | general portrait of exposure to formaldehyde | concentration | inspection type, sample type (short-term, TWA), season, industry, year, state, outside temperature, | marginal effect of inspection type with complaint and referral inspections associated with slightly higher levels than scheduled inspections (7%). Exclusion of non-detects might have caused underestimation of ~20–30% for TWA results, up to 60% for short-term results. |
| Lavoue et al. 2011 | comparison of formaldehyde exposure levels in IMIS and the French exposure databank COLCHIC | concentration | data source, year, sample type (short-term versus TWA), industry | formaldehyde levels somewhat higher in the French database (by 14% in average, reduced to no difference after exclusion of health sector). Contrast between most industries very similar. Exclusion of non-detects would have caused overestimation of IMIS TWA results by ~20% and underestimation of the COLCHIC short-term data by ~30%. |
| Henn et al. 2011 | general portrait of exposure to lead | percent of samples over the PEL | industry, time period, region, number of employees, federal/state plan, union status, inspection type, advance notice of inspection, presence of employee representative, employees interviewed during inspection | higher probability of being over the PEL for smaller companies (1–99 versus over 500 :OR=2), federal versus state plan (OR=1.1), union versus no union (OR=1.23), advance notice of inspection (OR=1.6), absence of employee representative(OR=1.19), no employee interviewed (OR=1.33) |
| Teschke et al. 1999 | exposure to wood dust for a population-based case–control study | concentration | year, job description, number of employees, inspection type | none reported in multivariate analysis. In univariate analysis, GM for planned inspection slightly lower than program related (complaint or referral, 1.86 versus 1.99mg/m3) |