Decoupling of microbial carbon, nitrogen, and phosphorus cycling in response to extreme temperature events
Efficient collection and preparation of methane from low concentration waters for natural abundance radiocarbon analysis
Freshwater and marine environments constitute the largest global reservoirs of the greenhouse gas methane (CH4) and natural abundance radiocarbon measurements (14C-CH4) can allow for high confidence interpretations about CH4 dynamics operating in these environments. Collecting sufficient amounts of CH4 sample for a standard, high precision 14C-accelerator mass spectrometry (AMS) analysis (∼ 200 μg carbon (C)) was previously unfeasible when sampling from low CH4 concentration waters, such as much of the surface ocean (∼ 2 nM), which would require collecting the CH4 from 8500 L of seawater. The method described here involves pumping 20,000–40,000 L of seawater up from depth through a dissolved gas extraction system, which enables the collection of a sample composed of 100s of L of gas in less than 4 h on station. The large volume extracted gas sample is compressed into a 1.7 L cylinder for transport from the ship to the home laboratory. The home laboratory preparation of each sample to a CH4-derived carbon dioxide aliquot for 14C-AMS analysis is carried out in 3 h on a flow-through vacuum line that simultaneously prepares aliquots for stable isotope analyses (δ13C-CH4 and δ2H-CH4). The total process blank of the method is small (5.0 μg CH4-C) and composes 1.2% of the average collected and prepared sample (424 ± 163 μg, from a recent campaign; n = 16). The 14C-CH4 blanks prepared on the vacuum line have acceptably low 14C content (0.23 ± 0.07 percent Modern Carbon (pMC); n = 7) relative to the 14C-dead (0 pMC) CH4 from which they are prepared.
Adductomic Screening of Hemoglobin Adducts and Monitoring of Micronuclei in School-Age Children
Electrophilic compounds/metabolites present in humans, originating from endogenous processes or exogenous exposure, pose a risk to health effects through their reactions with nucleophilic sites in proteins and DNA, forming adducts. Adductomic approaches are developed to screen for adducts to biomacromolecules in vivo by mass spectrometry (MS), with the aim to detect adducts corresponding to unknown exposures from electrophiles. In the present study, adductomic screening was performed using blood samples from healthy children about 12 years old (n = 51). The frequencies of micronuclei (MN) in erythrocytes in peripheral blood were monitored as a measure of genotoxic effect/genotoxic exposure. The applied adductomic approach has been reported earlier by us and is based on analysis of N-terminal valine adducts in hemoglobin (Hb) by liquid chromatography tandem mass spectrometry (LC-MS/MS). High resolution MS was introduced for refined screening of previously unknown N-terminal Hb adducts. Measured adduct levels were compared with MN frequencies using multivariate data analysis. In the 51 individuals, a total of 24 adducts (whereof 12 were previously identified) were observed and their levels quantified. Relatively large interindividual variations in adduct levels were observed. The data analysis (with partial least-squares regression) showed that as much as 60% of the MN variation could be explained by the adduct levels. This study, for the first time, applies the combination of these sensitive methods to measure the internal dose of potentially genotoxic chemicals and genotoxic effects, respectively. The results indicate that this is a valuable approach for the characterization of exposure to chemical risk factors for the genotoxic effects present in individuals of the general population.
An academic researcher’s guide to increased impact on regulatory assessment of chemicals.
The interactions between academic research and regulatory assessment of chemicals may in theory seem straightforward: researchers perform studies, and these studies are used by regulators for decision-making. However, in practice the situation is more complex, and many factors decide a research study’s regulatory use. According to several EU chemical legislations, all available and relevant studies can be used in hazard and risk assessment of chemicals. However, in practice, standard tests conducted under GLP and sponsored and provided by industry are predominantly used. Peer-reviewed studies from independent sources are often disregarded or disputed since they often do not comply with regulatory data requirements and quality criteria. There are several possible reasons for this, one being that academic research is reported in a way that does not fit the regulatory requirements. To help bridge such a gap, the aim of this paper is to give an overview of the general workings of chemicals legislation and propose a set of actions to increase the usability of research data. In the end, this may increase the use of academic research for decision-making and ultimately result in more science-based policies. From a policy perspective, useful scientific evidence are those studies that are sufficiently reliable and relevant. This is not in contradiction to the aims of research and generally accepted scientific standards.
Export of calcium carbonate corrosive waters from the East Siberian Sea
The Siberian shelf seas are areas of extensive biogeochemical transformation of organic matter, both of marine and terrestrial origin. This in combination with brine production from sea ice formation results in a cold bottom water of relative high salinity and partial pressure of carbon dioxide (pCO2). Data from the SWERUS-C3 expedition compiled on the icebreaker Oden in July to September 2014 show the distribution of such waters at the outer shelf, as well as their export into the deep central Arctic basins. Very high pCO2 water, up to ∼ 1000 µatm, was observed associated with high nutrients and low oxygen concentrations. Consequently, this water had low saturation state with respect to calcium carbonate down to less than 0.8 for calcite and 0.5 for aragonite. Waters undersaturated in aragonite were also observed in the surface in waters at equilibrium with atmospheric CO2; however, at these conditions the cause of under-saturation was low salinity from river runoff and/or sea ice melt. The calcium carbonate corrosive water was observed all along the continental margin and well out into the deep Makarov and Canada basins at a depth from about 50 m depth in the west to about 150 m in the east. These waters of low aragonite saturation state are traced in historic data to the Canada Basin and in the waters flowing out of the Arctic Ocean north of Greenland and in the western Fram Strait, thus potentially impacting the marine life in the North Atlantic Ocean.
Provningsjämförelse / Proficiency Test 2017-1, Metaller i vatten / Metals in waterDownload
NanoCRED: A transparent framework to assess’ the regulatory adequacy of ecotoxicity data for nanomaterials – Relevance and reliability revisited
Environmental hazard and risk assessment serve as the basis for regulatory decisions to protect the environment from unintentional adverse effects of chemical substances including nanomaterials. This process requires reliable and relevant environmental hazard data upon which classification and labelling can be based and Predicted No-Effect Concentration (PNEC) values can be estimated. In a regulatory context ecotoxicological data is often recommended to be generated according to accepted and validated test guidelines, preferably also following Good Laboratory Practice. However, engineered nanomaterials are known to behave very differently in ecotoxicity tests compared to the conventional soluble chemicals, for which most guidelines were developed. Therefore non-guideline tests, or tests following modified test guidelines, can provide valuable information and should not per se be considered less adequate for regulatory use. Here we propose a framework for reliability and relevance evaluation of ecotoxicity data for nanomaterials that take into account the challenges and characterisation requirements associated with testing of these substances. The nanoCRED evaluation criteria, and accompanying guidance, were developed to be used in combination with those developed through the ‘Criteria for Reporting and Evaluating Ecotoxicity Data (CRED)’ project. This approach can accommodate all types of nanomaterials, all types of aquatic ecotoxicity studies, and qualitative as well as quantitative data evaluation requirements. Furthermore, it is practically feasible to implement and directly applicable in European as well as international regulatory frameworks.
Granskning av vattenkemidata inom delprogrammet IKEU
Denna rapport utgör rapportering av ett projekt med syfte att sammanställa och granska vattenkemidata inom delprogrammet IKEU analyserade vid institutionen för miljövetenskap och analytisk kemi (ACES) vid Stockholms universitet respektive institutionen för vatten och miljö (IVM) vid Sveriges Lantbruksuniversitet.
Inom IKEU-programmet föreligger det särskilt intresse för de kemiska analyserna pH, alkalinitet, katjoner och anjoner då dessa värden används för surhetsbedömning och för att modellera pH och aluminiumfraktioner. Granskningen av vattenkemiska analysdata inom IKEU visar på hög kvalitet av dessa parametrar vid IVM och ACES. Sjuttiofem analysvärden har observerats där resultaten bör användas med försiktighet alternativt strykas helt.
Inget i denna granskning av data tyder på att det kommer att uppkomma några tydliga brott i tidserierna där IVM från och med januari 2016 analyserar vattenkemin istället för ACES. Men detta bör följas upp när det finns minst två år av motsvarande mätdata från IVM.
Under vissa perioder har det analyserats spårmetaller, järn, mangan och aluminium parallellt vid ACES och IVM. Överensstämmelsen i resultaten är relativt god mellan laboratorierna. Inga systematiska skillnader syns mellan ACES och IVMs resultat vid parallellanalyser av aluminium, järn och mangan. För spårmetaller finns det dock små systematiska skillnader mellan laboratorierna och spridningen, särskilt för zink, koppar och kadmium, är relativt stor, vilket delvis kan förklaras med att risken för kontamination är stor för dessa metaller. De flesta parallellanalyserna utfördes under 1999-2004. Troligtvis är överensstämmelsen mellan de bägge laboratorierna i dagsläget bättre i och med att analysernas precision och känslighet har förbättrats sedan dess.