The Kinetics and Mechanisms for Photodegradation of Nitrated Polycyclic Aromatic Hydrocarbons on Lettuce Leaf Surfaces: An In Vivo Study

Sun, Haifeng; Wang, Meng; Nan, Yanli; Han, Ming; Lu, Haoliang

doi:10.1021/acs.jafc.9b02326

Cited by 10 publications

(9 citation statements)

References 37 publications

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“…This evidence can be mutually supported by our previous investigation of 89 milk samples in which the parent PAHs of 9-FO and ATQ (fluorene and anthracene) were also detected in all samples. Actually, it was reported that ATQ may occur in light or thermal processes during food processing and storage. − Therefore, it is reasonably assumed that these OPAHs can be produced by the oxidization of parent PAHs during thermal processing. ATQ has been classified as a 2B carcinogen by the International Agency for Research on Cancer .…”

Section: Resultsmentioning

confidence: 99%

Simultaneous Determination of Typical Chlorinated, Oxygenated, and European Union Priority Polycyclic Aromatic Hydrocarbons in Milk Samples and Milk Powders

Yan

Gong

et al. 2021

J. Agric. Food Chem.

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An increasing number of studies have suggested that PAH contamination in dairy products demands high concern. This study established an efficient determination method for the European Union 15 + 1 PAHs and four PAH derivatives in dairy samples using a QuEChERS method coupled with GC-QqQ-MS. The optimized method obtained a recovery of 63.38−109.17% with a precision of 3.82−15.62%, and the limit of detection and limit of quantification were 0.08−0.78 and 0.27−2.59 μg/kg, respectively. The validated method was then successfully applied to identify the 20 PAHs in 82 dairy samples, including 43 commercial milk samples and 39 milk powders. The total PAH concentrations ranged from 2.37 to 11.83 μg/kg, and benzo[a]pyrene was only quantified in one milk and one milk powder sample at 0.35 and 0.42 μg/kg, respectively. The concentrations of PAH4 in milk samples and milk powders were not quantified (nq)−3.99 and nq−4.51 μg/kg, respectively. The results confirmed the appreciable occurrence of PAHs in dairy products, especially in infant formula. The data in this study provide a scientific basis for assessment on origin tracing, dietary exposure, and health risk of PAHs and their derivatives.

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Section: Resultsmentioning

confidence: 99%

Simultaneous Determination of Typical Chlorinated, Oxygenated, and European Union Priority Polycyclic Aromatic Hydrocarbons in Milk Samples and Milk Powders

Yan

Gong

et al. 2021

J. Agric. Food Chem.

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“…Although there is compelling evidence for the presence of exogenous substances onto plant leaves, information on their multiphase reactivity is scarce and biased toward anthropogenic compounds. To the best of our knowledge, leaf-surface photodegradation of pesticides is the only process that has been investigated in detail (reviewed by Sleiman et al and others , )although primarily in laboratory settings using model surfaces or reconstructed cuticles. ,, Some work has also been performed on the photodegradation of PAHs and their oxidation products on and within leaf cuticles, − while other studies investigated HNO 3 /nitrate photolysis on leaves of various plants. , On the contrary, the reactivity of anthropogenic SVOCs adsorbed on leaves with other gas-phase oxidants has received considerably less attention . An early investigation reported the oxidation of parathion (a pesticide) adsorbed onto lemon tree leaves in the presence of ozone and “foliar dust” (soil organic matter particles) .…”

Section: Chemicals From the Environmentmentioning

confidence: 99%

“…Overall, photodegradation obeys pseudo-first-order kinetics, with reaction rate constants that change considerably (but not predictably) based on chemistry, surface coverage, and micromorphology of the reaction substrate, as well as co-occurrence of other substances (e.g., Figure ). ,,− Formulation ingredients (e.g., surfactants) and co-occurring volatile and semivolatile metabolites can further influence surface photolysis by acting as photosensitizers or quenchers of reactive species, stabilizing radical intermediates, screening light, or a combination of these processes. ,,, By modifying the leaf’s wettability, surfactants can also influence shape, density, and crystallinity of the active ingredient’s residue, with impacts on its photochemical stability. , Variation in epicuticular wax chemistry, thickness, and morphology impact photodegradation in a similar manner . Wax components may act as photosensitizers or quenchers of reactive species and actively participate in reactions to form “bond residues”, whereas the presence of specific microstructures modifies light transmission and water spreading. ,, SVOC solubility in epicuticular waxes can also impact half-lives, as compounds buried within the cuticle are less susceptible to photodegradation than less lipophilic molecules sitting on its surface .…”

Section: Chemicals From the Environmentmentioning

confidence: 99%

The Chemical Landscape of Leaf Surfaces and Its Interaction with the Atmosphere

Ossola,

Farmer

2024

Chem. Rev.

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Atmospheric chemists have historically treated leaves as inert surfaces that merely emit volatile hydrocarbons. However, a growing body of evidence suggests that leaves are ubiquitous substrates for multiphase reactions−implying the presence of chemicals on their surfaces. This Review provides an overview of the chemistry and reactivity of the leaf surface's "chemical landscape", the dynamic ensemble of compounds covering plant leaves. We classified chemicals as endogenous (originating from the plant and its biome) or exogenous (delivered from the environment), highlighting the biological, geographical, and meteorological factors driving their contributions. Based on available data, we predicted ≫2 μg cm −2 of organics on a typical leaf, leading to a global estimate of ≫3 Tg for multiphase reactions. Our work also highlighted three major knowledge gaps: (i) the overlooked role of ambient water in enabling the leaching of endogenous substances and mediating aqueous chemistry; (ii) the importance of phyllosphere biofilms in shaping leaf surface chemistry and reactivity; (iii) the paucity of studies on the multiphase reactivity of atmospheric oxidants with leaf-adsorbed chemicals. Although biased toward available data, we hope this Review will spark a renewed interest in the leaf surface's chemical landscape and encourage multidisciplinary collaborations to move the field forward. CONTENTS

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“… Deposition of PAHs and their retention on leaf surfaces make them more susceptible to photodegradation. However, the photodegradation rate can be highly influenced by various factors, including PAHs location on leaves, their photochemical behavior and structure, as well as the nature of the substrate. , Once the PAHs penetrate the epidermal cell wall or cytoplasm, they become protected from photodegradation, but more susceptible to cell metabolism . Investigations into the environmental behavior of PAHs on different types of leaves/needles, including those from mangrove, spruce, oak, or pine, have demonstrated their significant involvement in the photolysis of PAHs on the leaf surface, thereby influencing the environmental fate of PAHs. ,, Chen et al studied the fluorene (FLU) photolysis processes in three different mangrove leaves and observed variations in photolysis rates among three of them.…”

Section: Uptake and Translocation And The Fate Of Pahs In Plantsmentioning

confidence: 99%

Transfer and Degradation of PAHs in the Soil–Plant System: A Review

Tarigholizadeh,

Sushkova,

Rajput

et al. 2023

J. Agric. Food Chem.

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Polycyclic aromatic hydrocarbons (PAHs) are highly toxic, persistent organic pollutants that threaten ecosystems and human health. Consistent monitoring is essential to minimize the entry of PAHs into plants and reduce food chain contamination. PAHs infiltrate plants through multiple pathways, causing detrimental effects and triggering diverse plant responses, ultimately increasing either toxicity or tolerance. Primary plant detoxification processes include enzymatic transformation, conjugation, and accumulation of contaminants in cell walls/vacuoles. Plants also play a crucial role in stimulating microbial PAHs degradation by producing root exudates, enhancing bioavailability, supplying nutrients, and promoting soil microbial diversity and activity. Thus, synergistic plant−microbe interactions efficiently decrease PAHs uptake by plants and, thereby, their accumulation along the food chain. This review highlights PAHs uptake pathways and their overall fate as contaminants of emerging concern (CEC). Understanding plant uptake mechanisms, responses to contaminants, and interactions with rhizosphere microbiota is vital for addressing PAH pollution in soil and ensuring food safety and quality.

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The Kinetics and Mechanisms for Photodegradation of Nitrated Polycyclic Aromatic Hydrocarbons on Lettuce Leaf Surfaces: An In Vivo Study

Cited by 10 publications

References 37 publications

Simultaneous Determination of Typical Chlorinated, Oxygenated, and European Union Priority Polycyclic Aromatic Hydrocarbons in Milk Samples and Milk Powders

Simultaneous Determination of Typical Chlorinated, Oxygenated, and European Union Priority Polycyclic Aromatic Hydrocarbons in Milk Samples and Milk Powders

The Chemical Landscape of Leaf Surfaces and Its Interaction with the Atmosphere

Transfer and Degradation of PAHs in the Soil–Plant System: A Review

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