Time-weighted averages, peaks, and other indices of exposure in occupational epidemiology.

Dose surrogates commonly used in occupational epidemiology are exposure intensity, exposure duration, and cumulative exposure. The appropriateness of any of these measures as dose indicators depends on the nature of the induction process for the disease under consideration. Peak exposure intensity is often associated with acute health outcomes, whereas cumulative exposure is generally more relevant for diseases with long induction times, i.e., "chronic" diseases. However, there may be situations where peak exposure is etiologically relevant in chronic disease induction, such as might occur with nonlinear rates of damage during brief intervals of very high exposure. An approach is described for evaluating the effect of peak exposures in which peaks may be defined on a relative basis for each worker, or with respect to an absolute value, such as the permissible occupational exposure limit. The analytic strategy is illustrated with data from a case-control study of silicosis in relation to quantitative estimates of silica exposure. In this example, relative peak exposures and average non-peak exposures appear to be better predictors of silicosis risk than cumulative exposure.

[1]  D. Thomas,et al.  Temporal patterns of exposure and nonmalignant pulmonary abnormality in Quebec chrysotile workers. , 1985, Archives of environmental health.

[2]  M. Finkelstein A study of dose-response relationships for asbestos associated disease. , 1985, British journal of industrial medicine.

[3]  E. Gilbert,et al.  An analysis of the mortality of workers in a nuclear facility. , 1979, Radiation research.

[4]  H Austin,et al.  Benzene and leukemia. A review of the literature and a risk assessment. , 1988, American journal of epidemiology.

[5]  T. Smith Exposure assessment for occupational epidemiology. , 1987, American journal of industrial medicine.

[6]  C. Garrard,et al.  A mathematical model of particle retention in the air-spaces of human lungs. , 1983, British journal of industrial medicine.

[7]  O. Wong An industry wide mortality study of chemical workers occupationally exposed to benzene. II. Dose response analyses. , 1987, British journal of industrial medicine.

[8]  T. Okuno Thermal effect of infra-red radiation on the eye: a study based on a model. , 1991, The Annals of occupational hygiene.

[9]  K. Rothman Induction and latent periods. , 1981, American journal of epidemiology.

[10]  H Checkoway Methods of treatment of exposure data in occupational epidemiology. , 1986, La Medicina del lavoro.

[11]  T. J. Smith,et al.  Development and application of a model for estimating alveolar and interstitial dust levels. , 1985, The Annals of occupational hygiene.

[12]  T. Robins,et al.  The use of geometric and arithmetic mean exposures in occupational epidemiology. , 1988, American journal of industrial medicine.

[13]  R L Harris,et al.  Reconstruction of silica exposure in the North Carolina dusty trades. , 1984, American Industrial Hygiene Association journal.