Drinking Water Disinfection Byproducts: Review and Approach to Toxicity Evaluation

Boorman, Gary A.; Dellarco, Vicki L.; Dunnick, June K.; Chapin, Robert E.; Hunter, Sid; Hauchman, Fred S.; Gardner, Henry S.; Cox, Michael J.; Sills, Robert C.

doi:10.2307/3434484

Cited by 121 publications

(123 citation statements)

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“…Chlorination, the most commonly used method to disinfect tap water, has led to a sharp decrease in both mortality and morbidity from many diseases known to be waterborne (Boorman et al 1999). However, the presence of chlorinated disinfection by-products (DBP) in tap water is of concern from a public health aspect because they are suspected to be carcinogenic (Attias et al 1995;Moudgal et al 2000;Tokmak et al 2004;Komulainen 2004).…”

Section: Introductionmentioning

confidence: 99%

Risk assessment of trihalomethanes from tap water in Fortaleza, Brazil

Viana

Cavalcante

Braga

et al. 2008

Environ Monit Assess

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The cancer risks (CR) by oral ingestion, dermal absorption, and inhalation exposure of trihalomethanes (THM) from tap water of ten districts in Fortaleza, Brazil were estimated. The mean levels of THM compounds were obtained in Fortaleza tap water as follow: 63.9 microg L(-1) for chloroform (CHCl(3)), 40.0 microg L(-1) for bromodichloromethane (CHBrCl(2)), and 15.6 microg L(-1) for dibromochloromethane (CHBr(2)Cl). Bromoform (CHBr(3)) was not detected. The mean CR for THMs in tap water is 3.96 x 10(-4). The results indicate that Fortaleza residents have a higher CR by inhalation than dermal absorption and oral ingestion. The CR for CHCl(3) contributes with 68% as compared with the total CR, followed by CHBrCl(2) (21%), and CHBr(2)Cl (11%). The hazard index (HI) is about ten times lower than unity, not indicating non-cancer effects.

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Section: Introductionmentioning

confidence: 99%

Risk assessment of trihalomethanes from tap water in Fortaleza, Brazil

Viana

Cavalcante

Braga

et al. 2008

Environ Monit Assess

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“…It also ensures the microbiological stability within the distribution systems. However, nowadays it is well known that chlorine reacts with natural organic matter to form several organic halides termed as disinfection by-products (Boorman et al 1999;Richardson et al 2000). Examples include trihalomethanes (THMs), haloacetic acids (HAAs), haloacetonitriles (HCNs), haloketones (HKNs), and chloropicrin.…”

Section: Introductionmentioning

confidence: 99%

Trihalomethane formation in ozonated and chlorinated surface water

Iriarte¹,

Álvarez-Uriarte²,

López‐Fonseca³

et al. 2003

Environmental Chemistry Letters

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The relatively recent discovery of disinfection by-products has driven the main regulatory organisms to set maximum contaminant levels for certain substances in drinking water. Trihalomethanes can be deemed as the most important group of by-products in chlorinated surface waters. The present work has focused on trihalomethane formation in a full-scale water treatment plant. We studied the effect of several factors, including ozonation, on trihalomethane levels in chlorinated treated water. The treatment scheme also includes an ozonation step.

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“…There is strong evidence that chloroform is naturally formed in soil and subsequently transported to air and groundwater (Hoekstra et al 1998;Khalil and Rasmussen 2000;Haselmann et al 2000a, b;Dimmer et al 2001). The finding that chloroform is produced naturally has raised concern, since it is toxic and natural sources seem to be as significant as anthropogenic sources (Boorman et al 1999;Bove et al 2002;Laturnus et al 2002).…”

Section: Introductionmentioning

confidence: 92%

Chloroform in runoff water—a two-year study in a small catchment in Southeast Sweden

et al. 2006

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Chloroform concentrationswere observed and input and output fluxes estimated over a 2-yr period in a small coniferous catchment (0.22 km 2 ) in southeast Sweden. Water discharge was measured daily, and runoff water was sampled bi-weekly for chloroform analysis. An approximate chloroform budget was calculated, which indicated that the annual output of 6 lg m -2 yr -1 was approximately six times higher than the input, inferring an internal source of chloroform in the catchment. To the best of our knowledge, neither flux estimates nor mass balances have previously been made for chloroform on a catchment scale, nor have data regarding natural runoff variation with time been gathered. Concentrations of chloroform in runoff were found to be generally high during wet periods, such as spring, but also peaked during summer rain events. The observed pattern suggests that chloroform is formed in surface soil layers and transported to the outlet under high-flow conditions and during dry-period rain events; it is lost through degradation or evaporation during drier periods due to longer soil water residence times. The data suggest that the variation among replicates increases with concentration; this emphasizes the need to know what the degree of on-site variation is, so one can collect a sufficient number of replicates to permit detection of spatial or temporal changes.

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Drinking Water Disinfection Byproducts: Review and Approach to Toxicity Evaluation

Cited by 121 publications

References 0 publications

Risk assessment of trihalomethanes from tap water in Fortaleza, Brazil

Risk assessment of trihalomethanes from tap water in Fortaleza, Brazil

Trihalomethane formation in ozonated and chlorinated surface water

Chloroform in runoff water—a two-year study in a small catchment in Southeast Sweden

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