The SAM-Krom biomonitoring study shows occupational exposure to hexavalent chromium and increased genotoxicity in Denmark.

Anne Thoustrup Saber, Marcus Levin, Pete Kines, Kukka Aimonen, Lucas Givelet, Christina Andersen, Anja Julie Huusom, Tanja Carøe, Niels Erik Ebbehøj, Frans Møller Christensen, Zheshun Jiang, Thomas Lundh, Håkan Tinnerberg, Maria Albin, Malin Engfeldt, Karin Broberg, Julia Catalan, Katrin Loeschner, Karsten Fuglsang, Ulla Vogel
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The aim of this study was to assess occupational exposure to Cr(VI) in Denmark.</p><p><strong>Methods: </strong>This cross-sectional study included 28 workers and 8 apprentices with potential Cr(VI) exposure and 24 within company controls, all recruited from six companies and one vocational school. Use of occupational safety and health (OSH) risk prevention measures were assessed through triangulation of interviews, a questionnaire and systematic observations. Inhalable Cr(VI) and Cr-total were assessed by personal air exposure measurements on Cr(VI) exposed participants and stationary measurements. Cr concentrations were measured in urine and in red blood cells (RBC) (the latter reflecting Cr(VI)). Genotoxicity was assessed by measurement of micronuclei in peripheral blood reticulocytes (MNRET).</p><p><strong>Results: </strong>At announced visits, a consistent high degree of compliance to OSH risk prevention measures were seen in 'chromium bath plating' for both technical devices (e.g. ventilation, plastic balls, sheet coverings) and in the use of personal protective equipment (e.g. gloves, respirators), yet a lesser degree of compliance was observed in 'stainless steel welding'. The geometric mean of the air concentration of Cr(VI) was 0.26 μg/m<sup>3</sup> (95% confidence interval (CI): 0.12-0.57) for the Cr(VI)-exposed workers and 3.69 μg/m<sup>3</sup> (95% CI: 1.47-9.25) for the Cr(VI)-exposed apprentices. Subdivided by company type, the exposure levels were 0.13 μg/m<sup>3</sup> (95% CI: 0.04-0.41) for companies manufacturing and processing metal products, and 0.81 μg/m<sup>3</sup> (95% CI: 0.46-1.40) for bath plating companies. Workers with occupational exposure to Cr(VI) had significantly higher median levels of urinary Cr (2.42 μg/L, 5th-95th percentile 0.28-58.39), Cr in RBC (0.89 μg/L, 0.54-4.92) and MNRET (1.59 ‰, 0.78-10.92) compared to the within company controls (urinary: 0.40 μg/L, 0.16-21.3, RBC: 0.60 μg/L, 0.50-0.93,MNRET: 1.06 ‰, 0.71-2.06). When sub-dividing by company type, urinary Cr (4.61 μg/L, 1.72-69.5), Cr in RBC (1.33 μg/L, 0.95-4.98) and MNRET (1.89 μg/L, 0.78-12.92) levels were increased for workers with potential Cr(VI) exposure in bath-plating companies, and when subdividing by work task, workers engaged in process operation had increased levels of urinary Cr (8.51 μg/L, 1.71-69.5), Cr in RBC (1.33 μg/L, 0.95-4.98) and MNRET (1.89 μg/L, 0.82-12.92) levels.</p><p><strong>Conclusion: </strong>This biomonitoring study shows that bath platers were highly exposed to Cr(VI), as suggested by relatively high levels of urinary Cr, Cr in RBC and increased levels of micronuclei. The urinary Cr concentrations were high when compared to the French biological limit value of 2.5 μg Cr/L, corresponding to the Danish occupational exposure limit of 1 μg/m<sup>3</sup>. This, in turn, indirectly suggests that additional exposure routes than via air may contribute to the exposure. For welders, no statistically significant increases compared to within company controls were observed, however, the observed urinary Cr levels were similar to the levels observed in a European study (HBM4EU), and were higher than the levels observed for welders in Sweden (SafeChrom). In spite of a high degree of self-reported and observed compliance to OSH risk prevention measures during announced visits, the biomarkers of exposure reflecting recent exposure (urinary Cr) or exposure during the last four months (Cr in RBC) may point to variation in compliance to OSH risk prevention measures in general. Reduced occupational exposure to Cr(VI) may be achieved by applying the hierarchy of controls in eliminating or substituting Cr(VI), and the use of more effective technical solutions (e.g. automation).</p>","PeriodicalId":94049,"journal":{"name":"International journal of hygiene and environmental health","volume":" ","pages":"114444"},"PeriodicalIF":0.0000,"publicationDate":"2024-09-16","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"International journal of hygiene and environmental health","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.1016/j.ijheh.2024.114444","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}
引用次数: 0

Abstract

Background: Hexavalent chromium (Cr(VI)) is a carcinogen. Exposure to Cr(VI) may occur in different industrial processes such as chrome plating and stainless steel welding. The aim of this study was to assess occupational exposure to Cr(VI) in Denmark.

Methods: This cross-sectional study included 28 workers and 8 apprentices with potential Cr(VI) exposure and 24 within company controls, all recruited from six companies and one vocational school. Use of occupational safety and health (OSH) risk prevention measures were assessed through triangulation of interviews, a questionnaire and systematic observations. Inhalable Cr(VI) and Cr-total were assessed by personal air exposure measurements on Cr(VI) exposed participants and stationary measurements. Cr concentrations were measured in urine and in red blood cells (RBC) (the latter reflecting Cr(VI)). Genotoxicity was assessed by measurement of micronuclei in peripheral blood reticulocytes (MNRET).

Results: At announced visits, a consistent high degree of compliance to OSH risk prevention measures were seen in 'chromium bath plating' for both technical devices (e.g. ventilation, plastic balls, sheet coverings) and in the use of personal protective equipment (e.g. gloves, respirators), yet a lesser degree of compliance was observed in 'stainless steel welding'. The geometric mean of the air concentration of Cr(VI) was 0.26 μg/m3 (95% confidence interval (CI): 0.12-0.57) for the Cr(VI)-exposed workers and 3.69 μg/m3 (95% CI: 1.47-9.25) for the Cr(VI)-exposed apprentices. Subdivided by company type, the exposure levels were 0.13 μg/m3 (95% CI: 0.04-0.41) for companies manufacturing and processing metal products, and 0.81 μg/m3 (95% CI: 0.46-1.40) for bath plating companies. Workers with occupational exposure to Cr(VI) had significantly higher median levels of urinary Cr (2.42 μg/L, 5th-95th percentile 0.28-58.39), Cr in RBC (0.89 μg/L, 0.54-4.92) and MNRET (1.59 ‰, 0.78-10.92) compared to the within company controls (urinary: 0.40 μg/L, 0.16-21.3, RBC: 0.60 μg/L, 0.50-0.93,MNRET: 1.06 ‰, 0.71-2.06). When sub-dividing by company type, urinary Cr (4.61 μg/L, 1.72-69.5), Cr in RBC (1.33 μg/L, 0.95-4.98) and MNRET (1.89 μg/L, 0.78-12.92) levels were increased for workers with potential Cr(VI) exposure in bath-plating companies, and when subdividing by work task, workers engaged in process operation had increased levels of urinary Cr (8.51 μg/L, 1.71-69.5), Cr in RBC (1.33 μg/L, 0.95-4.98) and MNRET (1.89 μg/L, 0.82-12.92) levels.

Conclusion: This biomonitoring study shows that bath platers were highly exposed to Cr(VI), as suggested by relatively high levels of urinary Cr, Cr in RBC and increased levels of micronuclei. The urinary Cr concentrations were high when compared to the French biological limit value of 2.5 μg Cr/L, corresponding to the Danish occupational exposure limit of 1 μg/m3. This, in turn, indirectly suggests that additional exposure routes than via air may contribute to the exposure. For welders, no statistically significant increases compared to within company controls were observed, however, the observed urinary Cr levels were similar to the levels observed in a European study (HBM4EU), and were higher than the levels observed for welders in Sweden (SafeChrom). In spite of a high degree of self-reported and observed compliance to OSH risk prevention measures during announced visits, the biomarkers of exposure reflecting recent exposure (urinary Cr) or exposure during the last four months (Cr in RBC) may point to variation in compliance to OSH risk prevention measures in general. Reduced occupational exposure to Cr(VI) may be achieved by applying the hierarchy of controls in eliminating or substituting Cr(VI), and the use of more effective technical solutions (e.g. automation).

SAM-Krom 生物监测研究表明,在丹麦,职业接触六价铬会增加基因毒性。
背景:六价铬(Cr(VI))是一种致癌物质。在镀铬和不锈钢焊接等不同的工业流程中都可能接触到六价铬。本研究的目的是评估丹麦的职业接触六价铬情况:这项横断面研究包括 28 名可能接触六价铬的工人和 8 名学徒,以及 24 名公司内部控制人员,他们都来自六家公司和一所职业学校。通过访谈、问卷调查和系统观察等方法对职业安全与健康(OSH)风险预防措施的使用情况进行了评估。通过对接触六价铬的参与者进行个人空气接触测量和固定测量,评估了可吸入六价铬和六价铬总量。对尿液和红细胞(RBC)中的铬浓度进行了测量(后者反映六价铬)。通过测量外周血网状细胞(MNRET)中的微核来评估遗传毒性:在公布的考察结果中,"铬浴电镀 "的技术设备(如通风设备、塑料球、板材覆盖物)和个人防护设备(如手套、呼吸器)的使用均符合职业安全和健康风险预防措施,但 "不锈钢焊接 "的符合程度较低。接触六价铬的工人的空气中六价铬浓度的几何平均数为 0.26 μg/m3(95% 置信区间:0.12-0.57),接触六价铬的学徒的空气中六价铬浓度的几何平均数为 3.69 μg/m3(95% 置信区间:1.47-9.25)。按公司类型细分,金属产品制造和加工公司的接触水平为 0.13 微克/立方米(95% CI:0.04-0.41),电镀公司的接触水平为 0.81 微克/立方米(95% CI:0.46-1.40)。职业暴露于六价铬的工人的尿铬中位数(2.42 μg/L,第 5-95 百分位数 0.28-58.39)、红细胞中的铬含量(0.89 μg/L,0.与公司内部对照组(尿液:0.40 μg/L,0.16-21.3;RBC:0.60 μg/L,0.50-0.93;MNRET:1.06 ‰,0.71-2.06)相比,尿液中的 Cr(2.42 μg/L,第 5-95 百分位数为 0.28-58.39)、RBC 中的 Cr(0.89 μg/L,0.54-4.92)和 MNRET 中的 Cr(1.59 ‰,0.78-10.92)均有所下降。如果按公司类型细分,尿液中的 Cr(4.61 μg/L,1.72-69.5)、RBC 中的 Cr(1.33 μg/L,0.95-4.98)和 MNRET(1.89 μg/L,0.78-12.92)水平在公司类型较多的工人中有所增加。如果按工作任务细分,从事加工操作的工人尿液中的 Cr(8.51 μg/L,1.71-69.5)、RBC 中的 Cr(1.33 μg/L,0.95-4.98)和 MNRET(1.89 μg/L,0.82-12.92)水平均有所增加:这项生物监测研究表明,电镀工人暴露于六价铬的程度很高,尿液中的六价铬、红细胞中的六价铬含量相对较高,微核含量也有所增加。与法国的生物限值 2.5 微克/升(相当于丹麦的职业接触限值 1 微克/立方米)相比,尿液中的铬浓度较高。这反过来间接表明,除空气外,其他接触途径也可能造成接触。就焊工而言,与公司内部的对照组相比,没有观察到统计意义上的显著增加,但是,观察到的尿铬水平与欧洲的一项研究(HBM4EU)中观察到的水平相似,并且高于瑞典焊工(SafeChrom)中观察到的水平。尽管在公布的访问中,职业安全和健康风险预防措施的自我报告和观察遵守情况都很好,但反映近期接触(尿液中的铬含量)或过去四个月接触(红细胞中的铬含量)的生物标志物可能表明,职业安全和健康风险预防措施的遵守情况总体上存在差异。通过采用分级控制消除或替代六价铬,以及使用更有效的技术解决方案(如自动化),可以减少职业接触六价铬的机会。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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