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Short-term respiratory function changes in relation to workshift welding fume exposures

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Summary

The forced vital capacity (FVC), the forced expiratory volume in one second (FEV1) and the transfer factor for the lung (TL) were measured before and after the 8-h work shift in groups of welders and non-welder controls in a shipyard. For each subject, full-shift average concentrations of welding fume constituents were evaluated. On the average, the lung function indices in both groups of welders and controls decreased from morning through afternoon. The welders demonstrated more reduction in the indices than the control group. In general, there was no significant association between the acute changes in the lung function and the daily amount of exposure to welding fume constituents or the welding environmental factors. However, the overall difference of mean diurnal variations in TL between the groups working under different ventilation condition was significant (P<0.01). On the average, welders who did not use any ventilation system showed maximum reductin in TL value. Acute reduction of FEV1 was positively correlated (P<0.05) with the levels of iron oxide produced during welding.

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References

  1. Akbar-Khanzadeh F (1980) Long-term effects of welding fumes upon respiratory symptoms and pulmonary function. J Occup Med 22:337–341

    Google Scholar 

  2. Akbar-Khanzadeh F (1981) Combined effects of cigarette smoking and occupational air pollution in welding environment. Med Lavoro 72:61–67

    Google Scholar 

  3. Akbar-Khanzadeh F (1984) A personal sampler for measuring shift exposure to welding fumes. Ann Occup Hyg 28:365–371

    Google Scholar 

  4. American Conference of Governmental Industrial Hygienists (1992) Threshold limit values for chemical substances and physical agents and biological exposure indices for 1992–1993, Cincinnati, Ohio

  5. American Welding Society (1973) The welding environment. AWS Technical Department, Miami, Florida

    Google Scholar 

  6. American Welding Society (1987) Method for sampling airborne particulates generated by welding and allied processes. AWS F1.4-87, AWS Miami, Florida

    Google Scholar 

  7. Antti-Poika M, Hassi J, Pyy L (1977) Respiratory diseases in arc welders. Int Arch Occup Environ Health 40:225–230

    Google Scholar 

  8. Ashford JR, Forwell GD, Routledge R (1960) A study of the repeatability of ventilators tests, anthropometric measurements, and answers to a respiratory symptoms questionnaire in working coal-miners. Br J Industr Med 17:114–121

    Google Scholar 

  9. Attfield MD, Ross DS (1978) Radiological abnormalities in electric-arc welders. Br J Industr Med 35: 117–122

    Google Scholar 

  10. Bouhuys A, Barbero A, Lindell SE, Roach SA, Schilling RSF (1967) Byssinosis in hemp workers. Arch Environ Hlth 14: 533–544

    Google Scholar 

  11. Bouhuys A, Barbero A, Schilling RSF (1969) Chronic respiratory disease in hemp workers. Am J Med 46:526–537

    Google Scholar 

  12. British Standards Institution: Methods for the sampling and analysis of fume from welding and allied processes. BSI DD54: part I (1977) Particulate matter. DD54: part II (1980) Gases

  13. Cotes JE (1975) Lung function-assessment and application in medicine. 3rd ed. Blackwell Scientific Publications, Oxford

    Google Scholar 

  14. Fay H, Mohr PH, McDaniel PW (1957) Nitrogen dioxide and ozone concentrations in welding operations. Ind Hyg Qurt 18: 19–28

    Google Scholar 

  15. Fogh A, Frost J, Gorrg J (1969) Respiratory symptoms and pulmonary function in welders. Ann Occup Hyg 12:213–218

    Google Scholar 

  16. Guberan E, William MK, Walford J, Smith M (1969) Circadian variation of FEV in shift workers. Br J Industr Med 26: 121–125

    Google Scholar 

  17. Hooftman RN, Arkesteyn CWM, Roza P (1988) Cytotoxicity of some types of welding fume particles to bovine alveolar macrophages. Ann Occup Hyg 32:95–102

    Google Scholar 

  18. Hruby J, Butler J (1975) Variability of routine pulmonary function tests. Thorax, 30:548–553

    Google Scholar 

  19. Jarnuszkiewicz I, Knapik A, Kwiatkowski B (1966) Particle size distribution of welding fume depending on the microclimate conditions of welders working places. Bull Instit Marine Med in Gdansk 17:73–76

    Google Scholar 

  20. Kiburn KH, Warshaw R, Boylen CT (1986) Airway obstruction, volume loss and respiratory symptoms in shipyard welders in Los Angeles: Baseline values and cross shift changes. In: Stern RM, Berlin A, Fletcher AC, Jarvisalo J (eds) Health hazards and biological effects of welding fumes and gases. Excerpta Medica, Amsterdam

    Google Scholar 

  21. Keimig DG, Pomrehn PR, Burmeister LF (1983) Respiratory symptoms and pulmonary function in welders of mild steel: a cross-sectional study. Am J Ind Med 4:489–499

    Google Scholar 

  22. Lewinsohn HC, Capel LH, Smart J (1960) Changes in forced expiratory volumes throughout the day. Br Med J 1:462–464

    Google Scholar 

  23. McDermott M (1966) Diurnal and weekly changes in lungs airway resistance. J Physiol 186:90–92

    Google Scholar 

  24. McKerrows CB, McDermott M, Gilson JC, Schilling RSF (1958) Respiratory function during the day in cotton workers. A study in byssinosis. Br J Industr Med 15:73–83

    Google Scholar 

  25. McMillan GHG, Heath J (1979) The health of welders in naval dockyards: Acute changes in respiratory function during standardized welding. Ann Occup Hyg 22:19–32

    Google Scholar 

  26. Mur JM, Teculescu D, Pham QT, Gaertner M, Massin N, Meyer-Bisch C, Moulin JJ, Diebold F, Pierr F, Meurou-Poncelet B, Muller J (1985) Lung function and clinical findings in a cross-sectional study of arc-welders-an epidemiological study. Int Arch Occup Environ Health 57:1–17

    Google Scholar 

  27. Mur JM, Pham QT, Teclescu D, Massin N, Meyer-Bisch C, Moulin JJ, Wild P, Leonard M, Henquel JC, Baudin V, Betz M, Fontana JM, Toamain JP (1989) Arc welders' respiratory health evolution over five years. Int Arch Occup Environ Health 61:321–327

    Google Scholar 

  28. Oleru G, Ademiluyi SA (1987) Some acute and long-term effects of exposure in welding and thermal-cutting operations in Nigeria. Int Arch Occup Environ Health 59:605–612

    Google Scholar 

  29. Oxhoj H, Bake B, Wedel H, Wilhelmsen L (1979) Effects of electric are welding on ventilatory lung function. Arch Environ Hlth 3:211–217

    Google Scholar 

  30. Peters JM, Murphy RLH, Pagnotto LD, Van Ganse WF (1968) Acute respiratory effects in workers exposed to low levels of toluene diisocyanate (TDI). Arch Environ Health 16:642–647

    Google Scholar 

  31. Sulotto F, Romano C, Piolatto G, Coggiola M, Polizzi S, Ciacco C, Berra A (1990) Short-term respiratory changes in polyurethane foam workers exposed to low MDI concentration. Int Arch Occup Environ Health 62:521–524

    Google Scholar 

  32. Wal JF Van Der (1985) Exposure of welders to fumes Cr, Ni, Cu and gases in Dutch industries. Ann Occup Hyg 29:377–389

    Google Scholar 

  33. Walford J, Lammers B, Schilling RSF, Hoven van den, Genderen D van, Veen YG van der (1966) Diurnal variation in ventilation capacity: An epidemiological study of cotton and other factory workers employed on shift work. Br J Industr Med 23:142–148

    Google Scholar 

  34. World Health Organization (1985) Health hazards and biological effects of welding fumes and gases. In: Stern RM, Berlin A, Fletcher AC, Jarvisalo J (eds) Proceedings of the International Conference. WHO Regional Office for Europe, Copenhagen

    Google Scholar 

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Author notes

  1. Farhang Akbar-Khanzadeh

    Present address: School of Allied Health, Occupational Health Program, Medical College of Ohio, P.O. Box 10008, 43699-0008, Toledo, Ohio, USA

Authors and Affiliations

  1. Department of Occupational Health and Hygiene, Medical School, University of Newcastle-upon-Tyne, UK

    Farhang Akbar-Khanzadeh

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Akbar-Khanzadeh, F. Short-term respiratory function changes in relation to workshift welding fume exposures. Int. Arch Occup Environ Heath 64, 393–397 (1993). https://doi.org/10.1007/BF00517944

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  • DOI: https://doi.org/10.1007/BF00517944

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