Two Novel Thio-Arsenosugars in Scallops Identified with HPLC - ICPMS and HPLC - ESMS

Kahn, Markus; Raml, Reingard; Schmeisser, Ernst; Vallant, Birgit; Francesconi, Kevin A.; Goessler, Walter

doi:10.1071/en05045

Cited by 50 publications

(42 citation statements)

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“…Thio-Gly was prepared from the oxo-Gly as 302 described elsewhere. [35] Thio-DMAP was prepared by purging the headspace of an HPLC vial containing…”

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confidence: 99%

Arsenic speciation in bodily fluids of harbor seals (Phoca vitulina) and harbor porpoises (Phocoena phocoena)

Kuenstl

Griesel²,

Prange³

et al. 2009

Environ. Chem.

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11 12Environmental context. Marine mammals as top predators ingest a lot of arsenic from their food. In this 13 study liver samples and body fluids of marine mammals from the North and Baltic Seas were investigated 14 for arsenic speciation in order to get some information about their feeding habits. Only organic arsenic 15 compounds with low toxicity were detected in all investigated samples. Although a high quantitative 16 variability was observed, the same compounds were determined in all fluids examined. 18Abstract. The total arsenic concentrations in whole blood of harbor seals (Phoca vitulina) and in liver 19 tissues of harbor porpoises (Phocoena phocoena) were determined using TXRF (total-reflection X-ray 20 fluorescence spectrometry). The total arsenic concentration found in whole blood was lower for fish-fed ). In porpoise liver the arsenic concentrations were higher from carcases found in the North Sea (217- ). 25Furthermore the total arsenic content and arsenic species in urine, plasma, and gastric juice of seals and 26 the urine of porpoises, which were collected from animals at different areas in the North and Baltic Seas, 27were determined using ICPMS (inductively coupled plasma mass spectrometry . The arsenic is almost entirely present in inorganic forms.[1] 49Marine organisms are known to accumulate and convert inorganic arsenic to organic arsenic compounds. 50Mammals such as porpoises and seals living in the marine environment and feeding exclusively on marine 51 organisms are in an exceptional position. As top predators they could accumulate arsenic due to their 52 position in the food web. Goessler et al., reported in 1997 the arsenic concentrations and speciation in a 53 three organism marine food chain starting with a seaweed followed by two gastropods. They showed that 54 arsenic was accumulated and metabolized within this food chain.[2] These results were in contrast to those 55of Kubota et al., who found lower arsenic concentrations in marine mammals (seals and porpoises) 56 compared to those of lower tropic level marine organisms from other studies.[3] Furthermore Kubota et al. 57investigated a possible correlation between arsenic accumulation and gender, age (or body length), or 58 feeding habits in liver tissues of 16 different marine mammal species. The determined arsenic 59concentrations varied widely among species and individuals ranging from 100 to 7680 µg kg -1 dry mass. 60Marine mammals feeding on fish contained lower arsenic concentrations compared to animals feeding on 61cephalopods and crustaceans but no trend with gender or age could be seen.[3] 62Seals feed with regional and seasonal variations on fish, crustaceans, and cephalopods, [4] in contrast to 63 harbor porpoises, which feed mainly on fish and less frequently on molluscs and squids.[5] 64Arsenic contents in tissues of field-collected marine mammals, fish, and invertebrates have been reported 65 in quantities ranges from less than 1000 up to 30000 µg As kg -1 dry mass. [6][7] Total arsenic content in 66 whole blood of...

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“…Thio-Gly was prepared from the oxo-Gly as 302 described elsewhere. [35] Thio-DMAP was prepared by purging the headspace of an HPLC vial containing…”

mentioning

confidence: 99%

Arsenic speciation in bodily fluids of harbor seals (Phoca vitulina) and harbor porpoises (Phocoena phocoena)

Kuenstl

Griesel²,

Prange³

et al. 2009

Environ. Chem.

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“…[9] Subsequent work revealed a range of thio-dimethyl arsenicals, and it is now accepted that the oxo analogs and thio analogs coexist in natural samples in ratios depending on the environmental conditions. [10][11][12] The oxo-thio interplay also has human toxicological implications. Thioarsenicals have been detected in urine of people exposed to inorganic arsenic in drinking water, [13] and they are likely to form readily in particular thio-rich cell compartments.…”

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confidence: 99%

Oxygen versus sulfur: Structure and reactivity of substituted arsine oxides and arsine sulfides

2011

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Although arsenic in its inorganic forms is a well know toxic agent, biotransformations in the environment and in the human body can produce organoarsenic compounds that are generally of much lower toxicity. Foremost among these products is a range of dimethylated arsine oxides and their analogous sulfides, which are crucial to the arsenic detoxification process. We have investigated the formation and interconversion of substituted and unsubstituted arsenicals (R²₂As(=Z)R¹, R² = CH₃, R¹ = CH₂CH₂OH, CH₂COOH; Z = S or O) with density functional theory (DFT)/B3LYP. Formation of isomers including a cyclic hydrogen bonded conformer is observed for the ethanol and acetate derivatives. Furthermore, investigating the reaction of arsine oxide with hydrogen sulfide revealed the formation of arsine sulfide via pentacoordinated trigonal bipyramidal intermediates. A tetragonal pyramidal transition state was located enabling exchange of equatorial and axial positions in the trigonal bipyramidal species. The reaction was proven exothermic for all studied substituents (ΔE(rxn) -50 to -80 kJ/mol). This fundamental study shows that H₂S easily leads to the formation of thio-organoarsenicals. Conversion of arsine sulfides into their corresponding arsine oxides is experimentally accomplished with hydrogen peroxide, which could also be rationalized by means of ab initio calculations showing high exothermicity (ΔE(rxn) ca. -550 kJ/mol). Reactions are considered at different levels of theory (i.e., DFT, second and fourth order Møller-Plesset (MP) perturbation theory) including two solvation models for DFT, which show good agreement for resulting geometries and reaction energies. Hence, the widely used B3LYP/6-31G** combination is a suitable method for the description of molecular organoarsenicals.

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“…[10] These studies have led to the discovery of new arsenic compounds, e.g. arseno sulfur sugars in marine animals [6] and corn [9] and metabolites produced in urine on ingestion of seaweed, such as dimethylated arsenic species, [12] that are potentially carcinogenic.…”

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“…With the advent of modern analytical instrumentation, such as high pressure liquid chromatography coupled to an inductively coupled mass spectrometer or a mass spectrometer [4] and X-ray spectroscopy, arsenic is being analysed in more and diverse samples including marine organisms such as polychaetes [5] and scallops, [6] terrestrial organisms such as mushrooms and snails, [7,8] food crops [9] and animal and human urine. [10] These studies have led to the discovery of new arsenic compounds, e.g.…”

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Foreword: Research Front—Arsenic Biogeochemistry

Maher¹

2005

Environ. Chem.

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Two Novel Thio-Arsenosugars in Scallops Identified with HPLC - ICPMS and HPLC - ESMS

Cited by 50 publications

References 10 publications

Arsenic speciation in bodily fluids of harbor seals (Phoca vitulina) and harbor porpoises (Phocoena phocoena)

Arsenic speciation in bodily fluids of harbor seals (Phoca vitulina) and harbor porpoises (Phocoena phocoena)

Oxygen versus sulfur: Structure and reactivity of substituted arsine oxides and arsine sulfides

Foreword: Research Front—Arsenic Biogeochemistry

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