Triclosan occurrence in freshwater systems in the United States (1999–2012): A meta‐analysis

Pérez, Angela L.; Sylor, Marianna Anderle De; Slocombe, Andrew J.; Lew, Mindy G.; Unice, Kenneth M.; Donovan, Ellen

doi:10.1002/etc.2217

Cited by 63 publications

(32 citation statements)

References 62 publications

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“…It is widely used in household and health care-related products, such as toothpaste, hand/dishwashing soaps, deodorants, and mouthwash, as well as in medical devices, textiles, toys, and construction materials(Bedoux et al, 2012; Dann and Hontela, 2011). Triclosan and its derivatives are present in the environment, particularly in various water bodies and sediments(Bedoux et al, 2012; Perez et al, 2013). As evidence that humans are widely exposed to triclosan, triclosan is detectable in the liver and bile(Geens et al, 2012), fat tissue(Geens et al, 2012), urine(Calafat et al, 2008; Li et al, 2013; Pirard et al, 2012), blood(Allmyr et al, 2006; Allmyr et al, 2008; Wu et al, 2012), nails(Shi et al, 2013), and human milk(Toms et al, 2011).…”

Section: Introductionmentioning

confidence: 99%

Urinary triclosan concentrations are inversely associated with body mass index and waist circumference in the US general population: Experience in NHANES 2003–2010

Zhao

Wang

et al. 2015

International Journal of Hygiene and Environmental Health

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Background Humans are extensively exposed to triclosan, an antibacterial and antifungal agent. Triclosan’s effects on human health, however, have not been carefully investigated. Objective To examine whether triclosan exposure is associated with obesity traits. Methods This study included 2,898 children (6-19 years old) and 5,066 adults (20 years or older) who participated in the National Health and Nutrition Examination Surveys (NHANES) 2003-2010 and had a detectable level of urinary triclosan. Multiple linear regression models were used to examine the association between urinary triclosan and both body mass index (BMI) and waist circumference. Results Each standard deviation increase in urinary triclosan was associated with a 0.34 (95% confidence interval, CI: 0.05, 0.64) kg/m2 lower level of BMI (p=0.02) and 0.92 (95% CI: 0.09, 1.74) cm smaller waist circumference (p=0.03) in boys, and a 0.62 (95% CI: 0.31, 0.94) kg/m2 lower level of BMI (p=0.0002) and 1.32 (95% CI: 0.54, 2.09) cm smaller waist circumference in girls (P=0.001); a 0.42 (95% CI: 0.06, 0.77) kg/m2 lower level of BMI (P=0.02) and 1.35 (95% CI: 0.48, 2.22) cm smaller waist circumference (P=0.003) in men, and a 0.71 (95% CI: 0.34, 1.07) kg/m2 lower level of BMI (P=0.0002) and 1.68 (95% CI: 0.86, 2.50) cm smaller waist circumference (P=0.0001) in women. In both children and adults, there was a consistent trend for lower levels of BMI and smaller waist circumference with increasing levels of urinary triclosan, from the lowest to the highest quartile of urinary triclosan (P≤0.001 in all cases). Conclusion Triclosan exposure is inversely associated with BMI and waist circumference. The biological mechanisms linking triclosan exposure to obesity await further investigation.

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Section: Introductionmentioning

confidence: 99%

Urinary triclosan concentrations are inversely associated with body mass index and waist circumference in the US general population: Experience in NHANES 2003–2010

Zhao

Wang

et al. 2015

International Journal of Hygiene and Environmental Health

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“…†Low reliability PNEC values derived from quantitative structure–activity relationship (QSAR) data are indicated in brackets. Data sources: (a) Quednow and Puttmann (2009); (b) Agerstrand and Ruden (2010); (c) derived based on no observable effect concentration (NOEC) for condition index in fathead minnow of 1 mg/L, as reported by Winter et al (2008) with an uncertainty factor (UF) of 100; (d) Jahnel et al (2006); (e) Escher et al (2011); (f) Carlsson et al (2006); (g) Wang et al (2010); (h) derived based on half maximal effective concentration (EC 50 ) for green algae (96 h) of 3.9 mg/L, as calculated by ECOSAR (Ecological Structure Activity Relationships, software developed by the USEPA), with a UF of 1000; (i) derived based on EC 50 for growth inhibition of Pseudokirchneriella subcapitata of 2 mg/L, as reported by Harada et al (2008), with a UF of 1000; (j) derived based on EC 50 for growth inhibition of Tetrahymena pyriformis of 45 mg/L, as reported by Henschel et al (1997), with a UF of 1000; (k) derived based on EC 50 for green algae (96 h) of 0.21 mg/L, as calculated by ECOSAR, with a UF of 1000; (l) Schowanek and Webb (2002); (m) Komori et al (2013); (n) derived based on EC 50 for green algae (96 h) of 0.69 mg/L, as calculated by ECOSAR, with a UF of 1000; (o) derived based on the median lethal dose (LC 50 ) for daphnid (48 h) of 1.9 mg/L, as calculated by ECOSAR, with a UF of 1000; (p) Halling‐Sorensen et al (2000); (q) Yamamoto et al (2011); (r) derived from a NOEC based on an 8‐d chronic toxicity test with Ceriodaphnia dubia reported by Tamura et al (2012), with a UF of 10; (s) Perez et al 2013; (t) Agriculture and Resource Management Council of Australia and New Zealand (2000) 95th percentile; (u) Crane et al (2007); (v) Derived from a NOEC based on a Daphnia magna reproduction test by Bayer AG (2001), with a UF of 10; (w) Agriculture and Resource Management Council of Australia and New Zealand (2000), 99th percentile.…”

Section: Resultsmentioning

confidence: 99%

“…Triclosan was also found in wild fish in WWTP effluent receiving environments in Sweden at concentrations up to 0.90 mg/kg fresh weight of bile (Adolfsson‐Erici et al, 2002). New evidence suggests that the risk from exposure to triclosan could be underestimated and, as such, the PNEC of 500 ng/L (Perez et al, 2013) may not be adequate. For instance, triclosan was found to negatively affect larval fathead minnow ( Pimephales promelas ) swimming performance at 151 ng/L, an exposure concentration less than twice the maximum concentration reported here (87 ng/L, Table 3; Cherednichenko et al, 2012).…”

Section: Resultsmentioning

confidence: 99%

A National Survey of Trace Organic Contaminants in Australian Rivers

et al. 2014

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Trace organic contaminant (TrOC) studies in Australia have, to date, focused on wastewater effluents, leaving a knowledge gap of their occurrence and risk in freshwater environments. This study measured 42 TrOCs including industrial compounds, pesticides, and pharmaceuticals and personal care products by liquid chromatography tandem mass spectrometry at 73 river sites across Australia quarterly for 1 yr. Trace organic contaminants were found in 92% of samples, with a median of three compounds detected per sample (maximum 18). The five most commonly detected TrOCs were the pharmaceuticals salicylic acid (82%, maximum = 1530 ng/L), paracetamol (also known as acetaminophen; 45%, maximum = 7150 ng/L), and carbamazepine (27%, maximum = 682 ng/L), caffeine (65%, maximum = 3770 ng/L), and the flame retardant (2-chloroethyl) phosphate (44%, maximum = 184 ng/L). Pesticides were detected in 28% of the samples. To determine the risk posed by the detected TrOCs to the aquatic environment, hazard quotients were calculated by dividing the maximum concentration detected for each compound by the predicted no-effect concentrations. Three of the 42 compounds monitored (the pharmaceuticals carbamazepine and sulfamethoxazole and the herbicide simazine) had a hazard quotient >1, suggesting that they may be causing adverse effects at the most polluted sites. A further 10 compounds had hazard quotients >0.1, indicating a potential risk; these included four pharmaceuticals, three personal care products, and three pesticides. Most compounds had hazard quotients significantly <0.1. The number of TrOCs measured in this study was limited and further investigations are required to fully assess the risk posed by complex mixtures of TrOCs on exposed biota.

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“…Triclosan is used in products ranging from hand soaps, toothpaste, and cosmetics to textiles and plastics. Environmental concentrations can vary widely from ng to low mg/L concentrations in surface waters (Dann and Hontela 2011;Blair et al 2013;Perez et al 2013) to as high as 20 mg/L near a wastewater treatment plant in Rhode Island (Lopez-Avila and Hites 1980). Environmental concentrations can vary widely from ng to low mg/L concentrations in surface waters (Dann and Hontela 2011;Blair et al 2013;Perez et al 2013) to as high as 20 mg/L near a wastewater treatment plant in Rhode Island (Lopez-Avila and Hites 1980).…”

Section: Introductionmentioning

confidence: 99%

Embryonic exposure to environmentally relevant concentrations of triclosan impairs foraging efficiency in zebrafish larvae

Wirt

Botka

Perez

et al. 2018

Enviro Toxic and Chemistry

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The ubiquitous and persistent contaminant triclosan is known to cause developmental and behavioral toxicity in fish, but few studies have evaluated the long‐term effects of these responses. We used a phenotypically anchored approach to evaluate the behavioral responses caused by early exposure to environmentally relevant concentrations of triclosan to better understand the risk triclosan poses to fish. Zebrafish were exposed to 0, 0.4, 4, or 40 μg triclosan/L (nominal concentrations) for 5 d followed by depuration for 16 d to assess effects on mortality, development, and foraging efficiency. Because foraging efficiency can be impacted by neurological and structural alterations, we assessed morphological and behavioral indicators of neurotoxicity and morphology of craniofacial features associated with gape to identify potential underlying mechanisms associated with altered foraging behaviors. To our knowledge, we are the first to show that early exposure to environmentally relevant concentrations of triclosan impairs foraging efficiency in larval fish by 10%, leading to emaciation and reduced growth and survival. The cause of the impacts of triclosan on foraging efficiency remains unknown, because effects were not associated with overt indicators of neurotoxicity or grossly malformed craniofacial structures. Our results suggest that early exposure to triclosan has the potential to impact the sustainability of wild fish populations, and thus the mechanism underlying behavioral alterations following exposure to triclosan warrants further study. Environ Toxicol Chem 2018;37:3124–3133. © 2018 SETAC

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Triclosan occurrence in freshwater systems in the United States (1999–2012): A meta‐analysis

Cited by 63 publications

References 62 publications

Urinary triclosan concentrations are inversely associated with body mass index and waist circumference in the US general population: Experience in NHANES 2003–2010

Urinary triclosan concentrations are inversely associated with body mass index and waist circumference in the US general population: Experience in NHANES 2003–2010

A National Survey of Trace Organic Contaminants in Australian Rivers

Embryonic exposure to environmentally relevant concentrations of triclosan impairs foraging efficiency in zebrafish larvae

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