{"title":"瑞典室内游泳池中职业暴露于三氯胺和三卤甲烷:个人和固定监测的评估。","authors":"Jessica Westerlund, Pål Graff, Ing-Liss Bryngelsson, Håkan Westberg, Kåre Eriksson, Håkan Löfstedt","doi":"10.1093/annhyg/mev045","DOIUrl":null,"url":null,"abstract":"<p><strong>Introduction: </strong>Chlorination is a method commonly used to keep indoor swimming pool water free from pathogens. However, chlorination of swimming pools produces several potentially hazardous by-products as the chlorine reacts with nitrogen containing organic matter. Up till now, exposure assessments in indoor swimming pools have relied on stationary measurements at the poolside, used as a proxy for personal exposure. However, measurements at fixed locations are known to differ from personal exposure.</p><p><strong>Methods: </strong>Eight public swimming pool facilities in four Swedish cities were included in this survey. Personal and stationary sampling was performed during day or evening shift. Samplers were placed at different fixed positions around the pool facilities, at ~1.5 m above the floor level and 0-1 m from the poolside. In total, 52 personal and 110 stationary samples of trichloramine and 51 personal and 109 stationary samples of trihalomethanes, were collected.</p><p><strong>Results: </strong>The average concentration of trichloramine for personal sampling was 71 µg m(-3), ranging from 1 to 240 µg m(-3) and for stationary samples 179 µg m(-3), ranging from 1 to 640 µg m(-3). The air concentrations of chloroform were well below the occupational exposure limit (OEL). For the linear regression analysis and prediction of personal exposure to trichloramine from stationary sampling, only data from personal that spent >50% of their workday in the pool area were included. The linear regression analysis showed a correlation coefficient (r2) of 0.693 and a significant regression coefficient β of 0.621; (95% CI = 0.329-0.912, P = 0.001).</p><p><strong>Conclusion: </strong>The trichloramine exposure levels determined in this study were well below the recommended air concentration level of 500 µg m(-3); a WHO reference value based on stationary sampling. Our regression data suggest a relation between personal exposure and area sampling of 1:2, implying an OEL of 250 µg m(-3) based on personal sampling.</p>","PeriodicalId":8458,"journal":{"name":"Annals of Occupational Hygiene","volume":null,"pages":null},"PeriodicalIF":0.0000,"publicationDate":"2015-10-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://sci-hub-pdf.com/10.1093/annhyg/mev045","citationCount":"19","resultStr":"{\"title\":\"Occupational Exposure to Trichloramine and Trihalomethanes in Swedish Indoor Swimming Pools: Evaluation of Personal and Stationary Monitoring.\",\"authors\":\"Jessica Westerlund, Pål Graff, Ing-Liss Bryngelsson, Håkan Westberg, Kåre Eriksson, Håkan Löfstedt\",\"doi\":\"10.1093/annhyg/mev045\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p><strong>Introduction: </strong>Chlorination is a method commonly used to keep indoor swimming pool water free from pathogens. 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In total, 52 personal and 110 stationary samples of trichloramine and 51 personal and 109 stationary samples of trihalomethanes, were collected.</p><p><strong>Results: </strong>The average concentration of trichloramine for personal sampling was 71 µg m(-3), ranging from 1 to 240 µg m(-3) and for stationary samples 179 µg m(-3), ranging from 1 to 640 µg m(-3). The air concentrations of chloroform were well below the occupational exposure limit (OEL). For the linear regression analysis and prediction of personal exposure to trichloramine from stationary sampling, only data from personal that spent >50% of their workday in the pool area were included. The linear regression analysis showed a correlation coefficient (r2) of 0.693 and a significant regression coefficient β of 0.621; (95% CI = 0.329-0.912, P = 0.001).</p><p><strong>Conclusion: </strong>The trichloramine exposure levels determined in this study were well below the recommended air concentration level of 500 µg m(-3); a WHO reference value based on stationary sampling. 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引用次数: 19
摘要
简介:氯化是一种常用的方法,以保持室内游泳池的水不受病原体。然而,游泳池的氯化处理会产生几种潜在的有害副产品,因为氯会与含氮的有机物发生反应。到目前为止,室内游泳池的暴露评估依赖于泳池边的固定测量,作为个人暴露的代表。然而,已知在固定地点的测量与个人接触不同。方法:选取瑞典4个城市的8个公共游泳池设施作为调查对象。个人和固定抽样在白班或夜班期间进行。采样器被放置在游泳池设施周围不同的固定位置,在地板以上~1.5 m和距离池边0-1 m处。共收集三氯胺个人样品52份,固定样品110份,三卤甲烷个人样品51份,固定样品109份。结果:个人样品的三氯胺平均浓度为71µg m(-3),范围为1 ~ 240µg m(-3),固定样品的三氯胺平均浓度为179µg m(-3),范围为1 ~ 640µg m(-3)。空气中氯仿浓度远低于职业暴露限值(OEL)。对于固定采样的个人接触三氯胺的线性回归分析和预测,仅包括在泳池区域花费超过50%工作日的个人数据。线性回归分析显示,相关系数(r2)为0.693,显著回归系数β为0.621;(95% ci = 0.329-0.912, p = 0.001)。结论:本研究确定的三氯胺暴露水平远低于500µg m(-3)的推荐空气浓度水平;世卫组织基于固定抽样的参考值。我们的回归数据表明,个人暴露与区域采样之间的关系为1:2,这意味着基于个人采样的OEL为250µg m(-3)。
Occupational Exposure to Trichloramine and Trihalomethanes in Swedish Indoor Swimming Pools: Evaluation of Personal and Stationary Monitoring.
Introduction: Chlorination is a method commonly used to keep indoor swimming pool water free from pathogens. However, chlorination of swimming pools produces several potentially hazardous by-products as the chlorine reacts with nitrogen containing organic matter. Up till now, exposure assessments in indoor swimming pools have relied on stationary measurements at the poolside, used as a proxy for personal exposure. However, measurements at fixed locations are known to differ from personal exposure.
Methods: Eight public swimming pool facilities in four Swedish cities were included in this survey. Personal and stationary sampling was performed during day or evening shift. Samplers were placed at different fixed positions around the pool facilities, at ~1.5 m above the floor level and 0-1 m from the poolside. In total, 52 personal and 110 stationary samples of trichloramine and 51 personal and 109 stationary samples of trihalomethanes, were collected.
Results: The average concentration of trichloramine for personal sampling was 71 µg m(-3), ranging from 1 to 240 µg m(-3) and for stationary samples 179 µg m(-3), ranging from 1 to 640 µg m(-3). The air concentrations of chloroform were well below the occupational exposure limit (OEL). For the linear regression analysis and prediction of personal exposure to trichloramine from stationary sampling, only data from personal that spent >50% of their workday in the pool area were included. The linear regression analysis showed a correlation coefficient (r2) of 0.693 and a significant regression coefficient β of 0.621; (95% CI = 0.329-0.912, P = 0.001).
Conclusion: The trichloramine exposure levels determined in this study were well below the recommended air concentration level of 500 µg m(-3); a WHO reference value based on stationary sampling. Our regression data suggest a relation between personal exposure and area sampling of 1:2, implying an OEL of 250 µg m(-3) based on personal sampling.
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