Overview of historical occupational exposure to trichloroethylene in China.

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

Annals Of Work Exposures and Health Pub Date : 2025-01-23 DOI:10.1093/annweh/wxae103

Jia Nie, Calvin B Ge, Nathaniel Rothman, Wei Hu, Roel Vermeulen, Qing Lan, Susan Peters

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引用次数: 0

Abstract

Objectives: Trichloroethylene (TCE) is a carcinogen that has been causally linked to kidney cancer and possibly other cancer sites including the liver and lymphatic system. Its use in China has increased since the early 1990s due to the growing metal and electronic industries. We aimed to summarize the major sources of occupational exposure to TCE over time in China.

Methods: Occupational TCE exposure assessments were extracted from both the Chinese and English scientific literature, as well as from industrial hygiene surveys performed in Guangdong, Tianjin, and Hong Kong. Weighted mean concentrations were summarized by occupation and industry.

Results: We extracted over 12,412 measurements from 55 industries and 35 occupations across China since 1976, of which at least 201 were from case reports. More than half of the measurements were derived from 4 industries, including "manufacture of footwear" (29%), "manufacture of electronic components and boards" (17%), "manufacture of games and toys" (14%), and "manufacture of fabricated metal products, except machinery and equipment" (13%). Several occupations, including "electronic-equipment assemblers," "metal-, rubber-, and plastic-products assemblers," "metal finishing-, plating-, and coating-machine operators," "precision-instrument makers and repairers," "printing-machine operators," and "ore and metal furnace operators" were identified as having high risks of TCE exposure, with either pooled weighted mean task-based or full-shift concentrations over 150 mg/m3 over the years. TCE exposure levels varied across different occupations and changed over time. In 1990 and earlier, 1991 to 2000, the exposure levels were at their highest with pooled weighted mean task-based concentrations of 202.8 and 242.9 mg/m3, respectively. Subsequently, the level decreased to 118.7 mg/m3 from 2001 to 2010 before increasing again to 216.0 mg/m3 from 2011 onwards. This overall trend was also observed for "electronic-equipment assemblers" and "metal finishing-, plating-, and coating-machine operators." However, for "precision-instrument makers and repairers," the exposure levels consistently declined over the years.

Conclusions: Over the past few decades, degreasing-related occupations, such as "electronic-equipment assemblers" and "metal finishing-, plating-, and coating-machine operators" have been consistently identified as being at high risk of significant TCE exposure and continued to warrant attention. Identifying high-risk industries and occupations can inform the development of targeted interventions and regulations to mitigate TCE exposure. Furthermore, enhancing the quality and coverage of exposure measurement data in occupational settings will advance epidemiological investigations in occupational health.

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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.