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http://dx.doi.org/10.1016/j.shaw.2018.05.006

Occupational Exposure to Metals in Shooting Ranges: A Biomonitoring Study  

Vandebroek, Eline (Occupational Health Service)
Haufroid, Vincent (Louvain Centre for Toxicology and Applied Pharmacology (LTAP), Institut de Recherche Experimentale et Clinique (IREC), Universite catholique de Louvain)
Smolders, Erik (Division of Soil and Water Management)
Hons, Luc (Occupational Health Service)
Nemery, Benoit (Centre for Environment and Health, Department of Public Health and Primary Care)
Publication Information
Safety and Health at Work / v.10, no.1, 2019 , pp. 87-94 More about this Journal
Abstract
Background: Lead (Pb) exposure in shooting ranges has been reduced by various measures such as jacketed ammunition and lead-free primers. Nevertheless, this may lead to exposure to other metals, potentially resulting in adverse health effects. Methods: In a cross-sectional study, 35 subjects from seven different shooting ranges were studied: four shooting instructors, 10 police officers, 15 Special Forces, and six maintenance staff members. Metals and metalloids were determined in blood and urine by inductively coupled plasma-mass spectrometry. Results: The concentrations of most elements did not differ significantly between groups or compared to reference values, except for Sb and Pt in urine and Pb in blood. Mean values for Sb were considerably higher in urine from the Special Forces ($0.34{\mu}g/L$), the maintenance staff ($0.13{\mu}g/L$), and shooting instructors ($0.32{\mu}g/L$) compared to the police officers before shooting ($0.06{\mu}g/L$) and a Belgian reference value ($0.04{\mu}g/L$). For Pt, the Special Forces showed higher mean urinary concentrations ($0.078{\mu}g/L$) compared to a Belgian reference value (<$0.061{\mu}g/L$). Mean values for blood lead were markedly higher in the Special Forces ($3.9{\mu}g/dL$), maintenance staff ($5.7{\mu}g/dL$), and instructors ($11.7{\mu}g/dL$) compared to police officers ($1.4{\mu}g/dL$). One instructor exceeded the biological exposure index for blood Pb ($38.8{\mu}g/dL$). Conclusion: Since both Pb and Sb were found to be higher in shooting range employees, especially among frequent shooters, it is advisable to provide appropriate protective equipment, education, and medical follow-up for shooting range personnel in addition to careful choice of ammunition.
Keywords
Biomonitoring; Metals; Occupational health;
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1 Pawlas N, Dobrakowski M, Kasperczyk A, Kozlowska A, Mikolajczyk A, Kasperczyk S. The level of selenium and oxidative stress in workers chronically exposed to lead. Biol Trace Elem Res 2016;170:1-8.   DOI
2 Bergstrom U, Ekstrand-Hammarstrom B, Hagglund L, Wingfors H. Comparing acute toxicity of gunshot particles, from firing conventional and lead-Free ammunition, in pulmonary epithelial cell cultures. J Toxicol Environ Health A 2015;78:645-61.   DOI
3 Park WJ, Lee SH, Lee SH, Yoon HS, Moon JD. Occupational lead exposure from indoor firing ranges in Korea. J Korean Med Sci 2016;31:497-501.   DOI
4 Laidlaw MA, Filippelli G, Mielke H, Gulson B, Ball AS. Lead exposure at firing ranges-a review. Environ Health 2017;16:34.   DOI
5 National Research Council. Potential health risks to DOD firing-range personnel from recurrent lead exposure. Washington, DC (U.S.): The National Academies Press; 2013. p. 62-129 p15.
6 Nesveda J, Brandejs S, Jirasek K. Non-toxic and non-corrosive ignition mixture. United States Patent 2005; US 6,964,287 B1.
7 Cheyns K, Banza Lubaba Nkulu C, Ngombe LK, Asosa JN, Haufroid V, De Putter T, Nawrot T, Kimpanga CM, Numbi OL, Ilunga BK, Nemery B, Smolders E. Pathways of human exposure to cobalt in Katanga, a mining area of the DR Congo. Sci Total Environ 2014;490:313-21.   DOI
8 Hoet P, Jacquerye C, Deumer G, Lison D, Haufroid V. Reference values and upper reference limits for 26 trace elements in the urine of adults living in Belgium. Clin Chem Lab Med 2013;51:839-49.   DOI
9 American Conference of Governmental Industrial Hygienists. TLVs$^{(R)}$ and BEIs$^{(R)}$: based on the documentation of the threshold limit values for chemical substances and physical agents & biological exposure indices. 7th ed.; 2015. Cincinnati, OH (U.S.).
10 Holland MG, Cawthon D. Workplace Lead Exposure. J Occup Environ Med 2016;58:e371-4.   DOI
11 Nisse C, Tagne-Fotso R, Howsam M, Richeval C, Labat L, Leroyer A. Blood and urinary levels of metals and metalloids in the general adult population of Northern France: The IMEPOGE study, 2008-2010. Int J Hyg Environ Health 2017;220:341-63.   DOI
12 Tripathi RK, Sherertz PC, Llewellyn GC, Armstrong CW. Lead exposure in outdoor firearm instructors. Am J Public Health 1991;81:753-5.   DOI
13 Novotny T, Cook M, Hughes J, Lee SA. Lead exposure in a firing range. Am J Public Health 1987;77:1225-6.   DOI
14 Dams R, Vandecasteele C, Desmet B, Helsen M, Nagels M, Vermeir G, Yu ZQ. Element concentrations in the air of an indoor shooting range. Sci Total Environ 1988;77:1-13.   DOI
15 Valway SE, Martyny JW, Miller JR, Cook M, Mangione EJ. Lead absorption in indoor firing range users. Am J Public Health 1989;79:1029-32.   DOI
16 Fairfax R, Noll M, Clark F. OSHA Compliance Issues: Airborne lead and noise exposures during police firearms qualification. Appl Occup Environ Hyg 1997;12:633-7.   DOI
17 Lofstedt H, Selden A, Storeus L, Bodin L. Blood lead in Swedish police officers. Am J Ind Med 1999;35:519-22.   DOI
18 Ochsmann E, Goen T, Schaller KH, Drexler H. Lead - still a health threat for marksmen. Int J Hyg Environ Health 2009;212:557-61.   DOI
19 Gulson BL, Davis JJ, Mizon KJ, Korsch MJ, Bawden-Smith J. Sources of lead in soil and dust and the use of dust fallout as a sampling medium. Sci Total Environ 1995;166:245-62.   DOI
20 Cocker J, Mason HJ, Warren ND, Cotton RJ. Creatinine adjustment of biological monitoring results. Occup Med 2011;61:349-53.   DOI
21 Wlodarczyk J, Jardim-Surman K, Robertsan R, Aldrich R, Toneguzzi R, Hensley MJ, Gruszynski C, Gulson B. Measuring the amount of lead in indoor dust: long-term dust-fall accumulation in petri dishes (A pilot study). N S W Public Health Bull 1997;8:92-4.   DOI
22 Boreland F, Lyle DM,Wlodarczyk J, Balding WA, Reddan S. Lead dust in Broken Hill homes - a potential hazard for young children? Aust N Z J Public Health 2002;26:203-7.   DOI
23 Hogervorst J, Plusquin M, Vangronsveld J, Nawrot T, Cuypers A, Van Hecke E, Roels HA, Carleer R, Staessen JA. House dust as possible route of environmental exposure to cadmium and lead in the adult general population. Environ Res 2007;103:30-7.   DOI
24 Cooper RG, Harrison AP. The exposure to and health effects of antimony. Indian J Occup Environ Med 2009;13:3-10.   DOI
25 Di Lorenzo L, Borraccia V, Corfiati M, Mantineo GA, Caciari T, Marino M, Soleo L. Lead exposure in firearms instructors of the Italian State Police. Med Lav 2010;101:30-7.
26 Demmeler M, Nowak D, Schierl R. High blood lead levels in recreational indoor-shooters. Int Arch Occup Environ Health 2009;82:539-42.   DOI
27 Bailly R, Lauwerys R, Buchet JP, Mahieu P, Konings J. Experimental and human studies on antimony metabolism: their relevance for the biological monitoring of workers exposed to inorganic antimony. Occup Environ Med 1991;48:93-7.   DOI
28 Selden AD. Electric primer. United States Patent 1888; US 389448 A.
29 Sullivan JB, Krieger GR. Hazardous materials toxicology: clinical principles of environmental health. Baltimore (U.S.): Williams & Wilkins; 1992. p. 874-81.
30 Paschal DC, Ting BG, Morrow JC, Pirkle JL, Jackson RJ, Sampson EJ, Miller DT, Caldwell KL. Trace metals in urine of United States residents: reference range concentrations. Environ Res 1998;76:53-9.   DOI
31 Grandahl K, Suadicani P, Jacobsen P. Individual and environmental risk factors for high blood lead concentrations in Danish indoor shooters. Dan Med J 2012;59:A4488.
32 Diaz E, Sarkis JE, Viebig S, Saldiva P. Measurement of airborne gunshot particles in a ballistics laboratory by sector field inductively coupled plasma mass spectrometry. Forensic Sci Int 2012;214:44-7.   DOI
33 Wingfors H, Svensson K, Hagglund L, Hedenstierna S, Magnusson R. Emission factors for gases and particle-bound substances produced by firing lead-free small-caliber ammunition. J Occup Environ Hyg 2014;11:282-91.   DOI
34 Methner MM, Gibbins CJ, Niemeier T. Health hazard evaluation report: evaluation of instructor and range officer exposure to emissions from copper-based frangible ammunition at a military firing range. Cincinnati (OH): U.S. Department of Health and Human Services, Centers for Disease Control and Prevention. National Institute for Occupational Safety and Health, NIOSH; 2013. Report No. HETA2012-0091-3187.
35 Moxnes JF, Jensen TL, Smestad E, Unneberg E, Dullum O. Lead free ammunition without toxic propellant gases. Propellants Explos Pyrotech 2013;38: 255-60.   DOI
36 Rocha ED, Sarkis JE, Carvalho MD, Santos GV, Canesso C. Occupational exposure to airborne lead in Brazilian police officers. Int J Hyg Environ Health 2014;217:702-4.   DOI
37 Lach K, Steer B, Gorbunov B, Micka V, Muir RB. Evaluation of exposure to airborne heavy metals at gun shooting ranges. Ann Occup Hyg 2015;59:307-23.   DOI
38 Gelberg KH, Depersis R. Lead exposure among target shooters. Arch Environ Occup Health 2009;64:115-20.   DOI