Disulfide Oil Hazard Assessment Using Categorical Analysis and a Mode of Action Determination

Diethyl and diphenyl disulfides, naphtha sweetening (Chemical Abstracts Service [CAS] # 68955-96-4), are primarily composed of low-molecular-weight dialkyl disulfides extracted from C4 to C5 light hydrocarbon streams during the refining of crude oil. The substance, commonly known as disulfide oil (DSO), can be composed of up to 17 different disulfides and trisulfides with monoalkyl chain lengths no greater than C4. The disulfides in DSO constitute a homologous series of chemical constituents that are perfectly suited for a hazard evaluation using a read-across/worst-case approach. The DSO constituents exhibit a common mode of action that is operable at all trophic levels. The observed oxidative stress response is mediated by reactive oxygen species and free radical intermediates generated after disulfide bond cleavage and subsequent redox cycling of the resulting mercaptan. Evidence indicates that the lowest series member, dimethyl disulfide (DMDS), can operate as a worst-case surrogate for other members of the series, since it displays the highest toxicity. Increasing the alkyl chain length or degree of substitution has been shown to serially reduce disulfide toxicity through resonance stabilization of the radical intermediate or steric inhibition of the initial enzymatic step. The following case study examines the mode of action for dialkyl disulfide toxicity and documents the use of read-across information from DMDS to assess the hazards of DSO. The results indicate that DSO possesses high aquatic toxicity, moderate environmental persistence, low to moderate acute toxicity, high repeated dose toxicity, and a low potential for genotoxicity, carcinogenicity, and reproductive/developmental effects.

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Comparison of global and mode of action-based models for aquatic toxicity

SAR and QSAR in Environmental Research ◽

10.1080/1062936x.2015.1018939 ◽

2015 ◽

Vol 26 (3) ◽

pp. 245-262 ◽

Cited By ~ 19

Author(s):

T.M. Martin ◽

D.M. Young ◽

C.R. Lilavois ◽

M.G. Barron

Keyword(s):

Mode Of Action ◽

Aquatic Toxicity

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Tsunamis from prospected mass failure on the Marsili submarine volcano flanks and hints for tsunami hazard evaluation

Bulletin of Volcanology ◽

10.1007/s00445-020-01425-0 ◽

2020 ◽

Vol 83 (1) ◽

Author(s):

G. Gallotti ◽

F. Zaniboni ◽

G. Pagnoni ◽

C. Romagnoli ◽

F. Gamberi ◽

...

Keyword(s):

Numerical Models ◽

Hydrothermal Activity ◽

Hazard Evaluation ◽

Medium Size ◽

Tyrrhenian Sea ◽

Submarine Volcano ◽

Case Scenario ◽

Worst Case ◽

Tsunami Waves ◽

Mass Failure

AbstractThe Marsili Seamount (Tyrrhenian Sea, Italy) is the largest submarine volcano in the Mediterranean Sea, located in the middle of the Marsili Basin, facing the Calabrian and Sicilian coasts on its eastern side, and the coasts of Sardinia on the opposite side. It has erupted in historical times, and its summit crest is affected by widespread hydrothermal activity. This study looks at mass failures taking place at different depths on the flanks of the volcano and estimates their associated tsunamigenic potential. Mass failure, tsunami generation, and propagation have been simulated by means of numerical models developed by the Tsunami Research Team of the University of Bologna. In all, we consider five cases. Of these, three scenarios, one regarding a very small detachment and two medium-sized ones (between 2 and 3 km3 failure volume), have been suggested as possible failure occurrences in the published literature on a morphological basis and involve the north-eastern and north-western sectors of the volcano. The two additional cases, one medium-sized and one extreme, intended as a possible worst-case scenario (volume 17.6 km3), affecting the eastern flank. Results indicate that small-volume failures are not able to produce significant tsunamis; medium-size failures can produce tsunamis which dangerously affect the coasts if their detachment occurs in shallow water, i.e., involves the volcano crest; and extreme volume failures have the potential to create disastrous tsunamis. In all the simulations, tsunami waves appear to reach the Aeolian Islands in around 10 min and the coasts of Calabria and Sicily in 20 min. This study highlights that there is a potential for dangerous tsunamis generation from collapses of the Marsili volcano and as a consequence a need to intensify research on its status and stability conditions. More broadly, this investigation should also be extended to the other volcanic seamounts of the Tyrrhenian Sea, since their eruptive style, evolution, and tsunamigenic potential are still poorly known.

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Light-Driven Depolymerization of Native Lignin Enabled by Proton- Coupled Electron Transfer

10.26434/chemrxiv.9702377 ◽

2019 ◽

Author(s):

Suong Nguyen ◽

Phillip Murray ◽

Robert Knowles

Keyword(s):

Electron Transfer ◽

Visible Light ◽

Bond Cleavage ◽

Direct Conversion ◽

Alkoxy Radical ◽

Radical Intermediate ◽

Polymer Backbone ◽

Good Efficiency ◽

Chemical Reagents ◽

Proton Coupled Electron Transfer

<div>Here we report a catalytic, light-driven method for the redox-neutral depolymerization of native lignin biomass at ambient temperature. This transformation proceeds via a proton-coupled electron-transfer (PCET) activation of an alcohol O–H bond to generate a key alkoxy radical intermediate, which then drives the β-scission of a vicinal C–C bond. Notably, this depolymerization is driven solely by visible light irradiation, requiring no stoichiometric chemical reagents and producing no stoichiometric waste. This method exhibits good efficiency and excellent selectivity for the activation and fragmentation of β-O-4 linkages in the polymer backbone, even in the presence of numerous other PCET-active functional groups. DFT analysis suggests that the key C–C bond cleavage reactions produce non-equilibrium product distributions, driven by excited-state redox events. These results provide further evidence that visible-light photocatalysis can serve as a viable method for the direct conversion of lignin biomass into valuable arene feedstocks.</div>

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Humic substances alleviate the aquatic toxicity of polyvinylpyrrolidone-coated silver nanoparticles to organisms of different trophic levels

Environmental Toxicology and Chemistry ◽

10.1002/etc.2936 ◽

2015 ◽

Vol 34 (6) ◽

pp. 1239-1245 ◽

Cited By ~ 33

Author(s):

Zhuang Wang ◽

Joris T.K. Quik ◽

Lan Song ◽

Evert-Jan Van Den Brandhof ◽

Marja Wouterse ◽

...

Keyword(s):

Silver Nanoparticles ◽

Humic Substances ◽

Aquatic Toxicity ◽

Trophic Levels

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Prediction of Aquatic Toxicity Mode of Action Using Linear Discriminant and Random Forest Models

Journal of Chemical Information and Modeling ◽

10.1021/ci400267h ◽

2013 ◽

Vol 53 (9) ◽

pp. 2229-2239 ◽

Cited By ~ 23

Author(s):

Todd M. Martin ◽

Christopher M. Grulke ◽

Douglas M. Young ◽

Christine L. Russom ◽

Nina Y. Wang ◽

...

Keyword(s):

Random Forest ◽

Mode Of Action ◽

Aquatic Toxicity ◽

Linear Discriminant ◽

Forest Models ◽

Random Forest Models

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Aquatic Toxicity Effects and Risk Assessment of ‘Form Specific’ Product-Released Engineered Nanomaterials

International Journal of Molecular Sciences ◽

10.3390/ijms222212468 ◽

2021 ◽

Vol 22 (22) ◽

pp. 12468

Author(s):

Raisibe Florence Lehutso ◽

James Wesley-Smith ◽

Melusi Thwala

Keyword(s):

Risk Estimation ◽

Aquatic Toxicity ◽

Engineered Nanomaterials ◽

Pseudokirchneriella Subcapitata ◽

Worst Case ◽

Specific Product ◽

Test Organisms ◽

Risk Potential ◽

Imminent Risk ◽

Toxicity Effects

The study investigated the toxicity effects of ‘form specific’ engineered nanomaterials (ENMs) and ions released from nano-enabled products (NEPs), namely sunscreens, sanitisers, body creams and socks on Pseudokirchneriella subcapitata, Spirodela polyrhiza, and Daphnia magna. Additionally, risk estimation emanating from the exposures was undertaken. The ENMs and the ions released from the products both contributed to the effects to varying extents, with neither being a uniform principal toxicity agent across the exposures; however, the effects were either synergistic or antagonistic. D. magna and S. polyrhiza were the most sensitive and least sensitive test organisms, respectively. The most toxic effects were from ENMs and ions released from sanitisers and sunscreens, whereas body creams and sock counterparts caused negligible effects. The internalisation of the ENMs from the sunscreens could not be established; only adsorption on the biota was evident. It was established that ENMs and ions released from products pose no imminent risk to ecosystems; instead, small to significant adverse effects are expected in the worst-case exposure scenario. The study demonstrates that while ENMs from products may not be considered to pose an imminent risk, increasing nanotechnology commercialization may increase their environmental exposure and risk potential; therefore, priority exposure cases need to be examined.

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Anticipating cascading risks at the imminent Hochvogel peak failure

10.5194/egusphere-egu21-9581 ◽

2021 ◽

Author(s):

Johannes Leinauer ◽

Manfred Meindl ◽

Benjamin Jacobs ◽

Verena Stammberger ◽

Michael Krautblatter

Keyword(s):

Debris Flow ◽

Debris Flows ◽

Point Clouds ◽

Volume Estimation ◽

Rock Fall ◽

Recent Case ◽

Hazard Evaluation ◽

Event Analysis ◽

Worst Case ◽

Cascading Effects

Climatic changes are exacerbating the risk of alpine mass movements for example through more frequent and extreme heavy precipitation events. To cope with this situation, the monitoring, anticipation, and early warning of rock slope failures based on process dynamics is a key strategy for alpine communities. However, only investigating the release area of an imminent event is insufficient, as the primary hazard can trigger or increase secondary hazards like debris flows or the damming of a river. Nevertheless, recent case studies dealing with successive hazards are rarely existent for the Calcareous Alps. In this study, we precisely investigate the cascading effects resulting from an imminent rock fall and perform a pre-event analysis instead of back-modelling of a past event.The Hochvogel summit (2592 m&#160;a.s.l., Allg&#228;u Alps, Germany/Austria) is divided by several pronounced clefts that separate multiple instable blocks. 3D-UAV point clouds reveal a potentially instable mass of 260,000&#160;m&#179; in six main subunits. From our near real time monitoring system (Leinauer et al. 2020), we know that some cracks are opening at faster pace and react differently to heavy rainfall, making a successive failure of subunits likely. However, pre-deformations are not yet pronounced enough to decide on the exact expected volume whereas secondary effects are likely as the preparing rock fall mass will be deposited into highly debris-loaded channels. Therefore, we developed different rock fall scenarios from the gathered monitoring information, which we implemented into a RAMMS modelling of secondary debris flows. To obtain best- and worst-case results, each scenario is calculated with different erosion parameters in the runout channel. The models are calibrated with a well-documented debris flow event at Ro&#223;bichelgraben (10&#160;km NW and similar lithology) and are supported by field investigations in the runout channel including electrical resistivity tomography profiles (ERT) for determination of the depth of erodible material as well as a drone survey for mapping the area and the generation of an elevation model.Here we show a comprehensive scenario-based assessment for anticipating cascading risks at the Hochvogel from initial rock failure volume estimation to debris flow evolution and potential river damming. This recent case study from an alpine calcareous peak is an excellent and rare chance to gain insights into cascading risks modelling and an improved hazard evaluation.

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Effect of UV-A, UV-B and UV-C irradiation of glyphosate on photolysis and mitigation of aquatic toxicity

Scientific Reports ◽

10.1038/s41598-020-76241-9 ◽

2020 ◽

Vol 10 (1) ◽

Author(s):

Dimitra Papagiannaki ◽

Claudio Medana ◽

Rita Binetti ◽

Paola Calza ◽

Peter Roslev

Keyword(s):

High Resolution Mass Spectrometry ◽

Aquatic Toxicity ◽

Aquatic Organisms ◽

Transformation Products ◽

Trophic Levels ◽

Indirect Photolysis ◽

Before And After ◽

Test Organisms ◽

Inorganic Constituents ◽

Uv C

AbstractThe active herbicide ingredient glyphosate [N-(phosphonomethyl)glycine] is frequently detected as a contaminant in groundwater and surface waters. This study investigated effects of UV-A (365 nm), UV-B (302 nm) and UV-C (254 nm) irradiation of glyphosate in water on photolysis and toxicity to aquatic organisms from different trophic levels. A test battery with bacteria (Bacillus subtilis, Aliivibrio fischeri), a green microalga (Raphidocelis subcapitata), and a crustacean (Daphnia magna) was used to assess biological effect of glyphosate and bioactive transformation products before and after UV irradiation (4.7–70 J/cm2). UV-C irradiation at 20 J/cm2 resulted in a 2–23-fold decrease in toxicity of glyphosate to aquatic test organisms. UV-B irradiation at 70 J/cm2 caused a twofold decrease whereas UV-A did not affect glyphosate toxicity at doses ≤ 70 J/cm2. UV-C irradiation of glyphosate in drinking water and groundwater with naturally occurring organic and inorganic constituents showed comparable or greater reduction in toxicity compared to irradiation in deionized water. High-resolution mass spectrometry analyses of samples after UV-C irradiation showed > 90% decreases in glyphosate concentrations and the presence of multiple transformation products. The study suggests that UV mediated indirect photolysis can decrease concentrations of glyphosate and generate less toxic products with decreased overall toxicity to aquatic organisms.

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