Comparison of 3 methods characterizing H2S exposure in water and wastewater management work.

IF 1.8 4区医学 Q3 PUBLIC, ENVIRONMENTAL & OCCUPATIONAL HEALTH

Annals Of Work Exposures and Health Pub Date : 2024-08-08 DOI:10.1093/annweh/wxae043

Åse Dalseth Austigard, Hans Thore Smedbold, Kristin von Hirsch Svendsen

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引用次数: 0

Abstract

This study evaluates the effectiveness of self-assessed exposure (SAE) data collection for characterization of hydrogen sulfide (H2S) risks in water and wastewater management, challenging the adequacy of traditional random or campaign sampling strategies. We compared 3 datasets derived from distinct strategies: expert data with activity metadata (A), SAE without metadata (B), and SAE with logbook metadata (C). The findings reveal that standard practices of random sampling (dataset A) fail to capture the sporadic nature of H2S exposure. Instead, SAE methods enhanced by logbook metadata and supported by reliable detection and calibration infrastructure (datasets B and C) are more effective. When assessing risk, particularly peak exposure risks, it is crucial to adopt measures that capture exposure variability, such as the range and standard deviations. This finer assessment is vital where high H2S peaks occur in confined spaces. Risk assessment should incorporate indices that account for peak exposure, utilizing variability measures like range and standard or geometric standard deviation to reflect the actual risk more accurately. For large datasets, a histogram is just as useful as statistical measures. This approach has revealed that not only wastewater workers but also water distribution network workers, can face unexpectedly high H2S levels when accessing confined underground spaces. Our research underscores the need for continuous monitoring with personal electrochemical gas detector alarm systems, particularly in environments with variable and potentially hazardous exposure levels.

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比较表征水和废水管理工作中 H2S 暴露的 3 种方法。

本研究评估了自我评估暴露（SAE）数据收集在表征水和废水管理中的硫化氢（H2S）风险方面的有效性，对传统随机或活动采样策略的适当性提出了挑战。我们比较了由不同策略产生的 3 个数据集：带活动元数据的专家数据（A）、不带元数据的自测暴露（SAE）（B）和带日志元数据的自测暴露（SAE）（C）。研究结果表明，随机抽样的标准做法（数据集 A）无法捕捉到 H2S 暴露的偶发性。相反，由日志元数据增强并由可靠的检测和校准基础设施（数据集 B 和 C）支持的 SAE 方法更为有效。在评估风险，尤其是峰值暴露风险时，采用能够捕捉暴露变异性（如范围和标准偏差）的措施至关重要。在密闭空间出现高 H2S 峰值时，这种更精细的评估至关重要。风险评估应纳入考虑峰值暴露的指数，利用范围和标准或几何标准偏差等可变性指标来更准确地反映实际风险。对于大型数据集，直方图与统计量一样有用。这种方法揭示出，不仅废水处理工人，输水管网工人在进入密闭地下空间时也可能面临意想不到的高 H2S 水平。我们的研究强调了使用个人电化学气体检测报警系统进行持续监测的必要性，尤其是在暴露水平不稳定且具有潜在危险的环境中。

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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来源期刊

Annals Of Work Exposures and Health Medicine-Public Health, Environmental and Occupational Health

CiteScore

4.60

自引率

19.20%

发文量

期刊介绍： About the Journal Annals of Work Exposures and Health is dedicated to presenting advances in exposure science supporting the recognition, quantification, and control of exposures at work, and epidemiological studies on their effects on human health and well-being. A key question we apply to submission is, "Is this paper going to help readers better understand, quantify, and control conditions at work that adversely or positively affect health and well-being?" We are interested in high quality scientific research addressing: the quantification of work exposures, including chemical, biological, physical, biomechanical, and psychosocial, and the elements of work organization giving rise to such exposures; the relationship between these exposures and the acute and chronic health consequences for those exposed and their families and communities; populations at special risk of work-related exposures including women, under-represented minorities, immigrants, and other vulnerable groups such as temporary, contingent and informal sector workers; the effectiveness of interventions addressing exposure and risk including production technologies, work process engineering, and personal protective systems; policies and management approaches to reduce risk and improve health and well-being among workers, their families or communities; methodologies and mechanisms that underlie the quantification and/or control of exposure and risk. There is heavy pressure on space in the journal, and the above interests mean that we do not usually publish papers that simply report local conditions without generalizable results. We are also unlikely to publish reports on human health and well-being without information on the work exposure characteristics giving rise to the effects. We particularly welcome contributions from scientists based in, or addressing conditions in, developing economies that fall within the above scope.