Bioconcentration, Bioaccumulation, and Metabolism of Pesticides in Aquatic Organisms

Katagi, Toshiyuki

doi:10.1007/978-1-4419-1440-8_1

Cited by 137 publications

(118 citation statements)

References 594 publications

(639 reference statements)

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“…For example, (Smith et al (2010) demonstrated that hepatic metabolism of fluoxetine in trout was limited unless induced by pre-exposure to carbamazepine. In fact, limited information exists on invertebrate metabolism of organic chemicals (Katagi, 2010); however, biotransformation by the invertebrate G. pulex has been to shown to alter internal concentrations of xenobiotics . Clearly, an advanced understanding of biotransformation of pharmaceuticals in fish, invertebrate, plant and periphytic communities is needed to improve bioaccumulation assessments .…”

Section: Pharmaceutical Bioaccumulation By Periphyton and Invertebratmentioning

confidence: 99%

Pharmaceutical bioaccumulation by periphyton and snails in an effluent-dependent stream during an extreme drought

Haddad

Scott

et al. 2015

Chemosphere

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Section: Pharmaceutical Bioaccumulation By Periphyton and Invertebratmentioning

confidence: 99%

Pharmaceutical bioaccumulation by periphyton and snails in an effluent-dependent stream during an extreme drought

Haddad

Scott

et al. 2015

Chemosphere

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“…Among the most toxic pesticides are the organochlorine pesticides, recognized to have potential to induce hormonal disruption and cancer (Ehrlich et al 2011;Mearns et al 2012;Vallack et al 1998), mainly due to their extreme persistency, bioaccumulating and/or rippling through the food chain (Chopra et al 2011;Katagi 2010). So, the abusive use of pesticides and inefficient treatment of residues increase their probability of reaching estuarine and marine environments affecting fish nurseries as well as the benthic and pelagic communities (Liu et al 2008;McMillin and Means 1996).…”

Section: Introductionmentioning

confidence: 99%

Occurrence and seasonal loads of pesticides in surface water and suspended particulate matter from a wetland of worldwide interest—the Ria Formosa Lagoon, Portugal

Cruzeiro

Pardal²,

Rocha

et al. 2015

Environ Monit Assess

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Two novel methods were developed to extract and quantify 56 pesticides in surface waters, considering their content in both dissolved aqueous phase (DAP) and suspended particulate matter (SPM) fractions. These procedures were applied to coastal samples taken seasonally during 2012-2013, from three strategic sampling sites along the Ria Formosa Lagoon (south of Portugal). Briefly, 500 mL of water samples were filtrated, separating both fractions. The DAP fraction was extracted and pre-concentrated by solid-phase extraction (SPE), while the SPM was extracted using ultrasonic extraction technique (USE). Both fractions were then analyzed, and the pesticides were quantified and identified, within 35 min, by gas chromatography (GC) coupled to mass spectrometry (GC-MS and GC-MS/MS), respectively. The extraction of pesticides from the SPM fraction showed average recoveries of 102%, detection limits below 2.2 ng/L, and quantification limits ranging from 0.3 to 6.6 ng/L. Considering the real water samples, 73% of the selected pesticides were quantified in both DAP and SPM fractions (ΣDAP+SPM 2.3 μg/L) and their maximum levels were measured in autumn and winter. By category, the global loads of fungicides, herbicides, and insecticides were ≈407, ≈323, and ≈1.6 μg/L, respectively. Thirty-one percent of the quantified pesticides exceeded the European directives levels (2008/105/EC and 98/83/EC). From the total loads, the SPM fraction contribution was 32%, showing the importance of measuring pesticides in that fraction. The water physicochemical parameters revealed that the total nitrogen amounts were very high relatively to the legal required values, mainly close to the city of Faro (2.6 mg/L). In light of the above, measures are in need to meet European directives and protect both fauna and humans that use this area for leisure.

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“…The gap in knowledge related to mechanisms required to process nutrients in marine herbivorous fishes, for example, has only recently begun to close (Choat and Clements, 1998;Clements et al, 2009). Moreover, despite a long history of investigating how aquatic animals process chemical contaminants (Chambers and Yarbrough, 1976;Katagi, 2010;Rewitz et al, 2006;Smital et al, 2004), studies investigating how they process dietary secondary metabolites have only recently been initiated (Gross and Bakker, 2012;Liang et al, 2007;Richardson et al, 2009). An understanding of pharmacology can fill these gaps in both terrestrial and aquatic systems.…”

Section: Pharmacological Mechanismsmentioning

confidence: 99%

A Pharm-Ecological Perspective of Terrestrial and Aquatic Plant-Herbivore Interactions

et al. 2013

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-We describe some recent themes in the nutritional and chemical ecology of herbivores and the importance of a broad pharmacological view of plant nutrients and chemical defenses that we integrate as "Pharm-ecology". The central role that dose, concentration, and response to plant components (nutrients and secondary metabolites) play in herbivore foraging behavior argues for broader application of approaches derived from pharmacology to both terrestrial and aquatic plant-herbivore systems. We describe how concepts of pharmacokinetics and pharmacodynamics are used to better understand the foraging phenotype of herbivores relative to nutrient and secondary metabolites in food. Implementing these concepts into the field remains a challenge but new modeling approaches that emphasize tradeoffs and the properties of individual animals show promise. Throughout we highlight similarities and differences between the historic and future applications of pharm-ecological concepts in understanding the ecology and evolution of terrestrial and aquatic interactions between herbivores and plants. We offer several pharm-ecology related questions and hypotheses that could strengthen our understanding of the nutritional and chemical factors that modulate foraging behavior of herbivores across terrestrial and aquatic systems.

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Bioconcentration, Bioaccumulation, and Metabolism of Pesticides in Aquatic Organisms

Cited by 137 publications

References 594 publications

Pharmaceutical bioaccumulation by periphyton and snails in an effluent-dependent stream during an extreme drought

Pharmaceutical bioaccumulation by periphyton and snails in an effluent-dependent stream during an extreme drought

Occurrence and seasonal loads of pesticides in surface water and suspended particulate matter from a wetland of worldwide interest—the Ria Formosa Lagoon, Portugal

A Pharm-Ecological Perspective of Terrestrial and Aquatic Plant-Herbivore Interactions

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