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Toxic Action (toxic + action)
Selected AbstractsInfluence of stability on the acute toxicity of CdSe/ZnS nanocrystals to Daphnia magnaENVIRONMENTAL TOXICOLOGY & CHEMISTRY, Issue 6 2010Heather E. Pace Abstract The acute toxicity of polymer-coated CdSe/ZnS quantum dots (QDs) to Daphnia magna was investigated using 48-h exposure studies. The principal objective was to relate the toxicity of QDs to specific physical and chemical aspects of the QD. As such, two different CdSe core diameters, 2,nm QDs (green-emitting) and 5,nm QDs (red-emitting), and two different surface coatings, polyethylene oxide (PEO) and 11-mercaptoundecanoic acid (MUA) were studied. The QDs were characterized before and after the 48-h exposure using fluorescence, ultrafiltrations (3 kDa), and inductively coupled plasma-atomic emission spectrometry (ICP-AES) metal analysis. In addition, flow field flow fractionation-inductively coupled plasma-mass spectrometry (Fl FFF-ICP-MS) was used as a more extensive characterization technique to determine particle size and composition as well as identify other potential constituents in the QD solutions. The more stable QDs (PEO) were found to be less acutely toxic than the QDs with accelerated dissolution (MUA), suggesting QD stability has significant impact on the nanoparticles' short-term toxicity. The emergence of dissolved Cd2+ in solution indicates that the toxicity of the MUA QDs is likely due to Cd poisoning, and a mass-based dose response occurred as a consequence of this mode of action. Alternatively, the PEO QDs caused acute toxicity without observed particle dissolution (i.e., no detectable metals were solubilized), suggesting an alternative mode of toxic action for these nanoparticles. Results of the present study suggest that using particle number, instead of mass, as a dose metric for the PEO QDs, produces markedly different conclusions, in that smaller core size does not equate to greater toxicity. Environ. Toxicol. Chem. 2010;29:1338,1344. © 2010 SETAC [source] Acute toxicity of triorganotin compounds: Different specific effects on the energy metabolism and role of pHENVIRONMENTAL TOXICOLOGY & CHEMISTRY, Issue 6 2002René W. Hunziker Abstract Triorganotin compounds exhibit several modes of toxic action on the energy metabolism in energy-transducing membranes. The inhibition of the adenosine triphosphate (ATP) synthase and the hydroxide/chloride-antiport have been extensively investigated, but debate still exists on whether further mechanisms are relevant. In this work, two possible further effects have been investigated: inhibition of the bc1 complex and the hydroxide uniport, and in addition, the overall inhibition of the ATP synthesis was investigated in chromatophores of the photosynthetic purple bacterium Rhodobacter sphaeroides at pH = 7.5 and pH = 6.1. Experimental conditions were chosen in order to exclude the hydroxide/anion antiport as a possible effect. Inhibition of the cytochromes bc1 complex was detected, but at such high concentrations that it is not relevant for acute toxicity. Tributyltin was found to induce a decrease of the membrane potential, which can be attributed to a hydroxide uniport, whereas for triphenyltin no such activity was observed. For both compounds, inhibition of the ATP synthesis was higher at pH = 6.1 than at pH = 7.5. Also the hydroxide uniport activity of tributyltin was higher at lower pH. The contribution of the hydroxide uniport of tributyltin to the overall inhibition of the ATP synthesis cannot be quantified; however, hydroxide uniport occurred in the same concentration range as inhibition of the ATP synthesis. For triphenyltin, inhibition of the ATP synthesis can be attributed to the inhibition of the ATP synthase. It was concluded that chromatophores of R. sphaeroides are a useful system to discriminate various effects of toxicants on the energy metabolism of a cell. [source] Glutamate and the glutamate receptor system: a target for drug actionINTERNATIONAL JOURNAL OF GERIATRIC PSYCHIATRY, Issue S1 2003Stefan Bleich Abstract Glutamate is the most important excitatory neurotransmitter in the central nervous system. In the process, glutamate fulfills numerous physiological functions, but also plays an important role in the pathophysiology of different neurological and psychiatric diseases, especially when an imbalance in glutamatergic neurotransmission occurs. Under certain conditions, glutamate has a toxic action resulting from an activation of specific glutamate receptors, which leads to acute or chronic death of nerve cells. Such mechanisms are currently under discussion in acute neuronal death within the context of hypoxia, ischaemia and traumas, as well as in chronic neurodegenerative or neurometabolic diseases, idiopathic parkinsonian syndrome, Alzheimer's dementia and Huntington's disease. It is hoped that glutamate antagonists will lead to novel therapies for these diseases, whereby the further development of glutamate antagonists for blocking disease-specific subtypes of glutamate receptors may be of major importance in the future. Copyright © 2003 John Wiley & Sons, Ltd. [source] Hepatotoxic effect of cyclosporin A in the mitochondrial respiratory chainJOURNAL OF APPLIED TOXICOLOGY, Issue 4 2007Lilia Cristina De la Cruz Rodríguez Abstract Cyclosporin A (CyA), a potent immunosuppressant, was used to determine the hepatotoxic effect in long-term treatments. Male Wistar rats were used in these experiments. They were given CyA chronically at doses used in patients for 120 days, and at doses of 5, 10, 15 and 20 mg kg,1 day,1. These doses amount to CyA values in blood of 200 ± 24, 314 ± 40, 445 ± 33 and 598 ± 53 ng ml,1, respectively. A significant increase in glutamate dehydrogenase (GLDH) was found in the groups treated with 15 and 20 mg kg,1 day,1, which would point to mitochondria as the potential target of the toxic action of CyA. The mitochondrial respiratory chain of rat livers was studied in enzyme complexes I and II. Enzyme complex I was determined by spectrophotometry at 340 nm using NADH oxidase with the respirable substrate 10 mm NADH; enzyme complex II was determined by monitoring succinate dehydrogenase by oxymetry using the respirable substrate 10 mm succinate. The results show the inhibition of NADH oxidase in the groups treated with 10, 15 and 20 mg kg,1 day,1, an effect dependent both on time and on CyA concentration. Enzyme complex II showed a decrease in oxygen consumption. These findings were confirmed by histological studies (hematoxylin-eosin technique). Conclusions: Long-term treatment with CyA at doses of 15 and 20 mg kg,1 day,1, amounting to concentrations in blood of 445 ± 33 and 598 ± 53 ng ml,1, causes alterations in the mitochondria, revealed by the increase in serum GLDH and by the functional alteration of enzyme complexes I and II of the mitochondrial respiratory chain. Copyright © 2007 John Wiley & Sons, Ltd. [source] Role of astrocytes in trimethyltin neurotoxicityJOURNAL OF BIOCHEMICAL AND MOLECULAR TOXICOLOGY, Issue 5 2001Palur G. Gunasekar Abstract Although the neurotoxicity of trimethyltin (TMT) is well known, mechanisms are still not clear. Glia have been proposed to mediate the toxic action of TMT on nerve cells. Accordingly, the effects of TMT were tested in primary neuronal cultures from rat cerebellum and compared to effects in astrocytes and mixed cultures. Neuronal damage observed following TMT exposure was less in the presence of astrocytes and astrocytes alone were resistant to TMT. Thus, astrocytes have a protective effect against TMT-induced neurotoxicity. TMT caused an oxidative stress in granule cell cultures involving a variety of oxidative species ((O2),,, H2O2, NO), but astrocytes were less sensitive to TMT-induced oxidative species generation. Antioxidants, glutathione and 7-nitroindazole attenuated neuronal cell death induced by TMT. It appears that oxidative stress mediates a large part of the destructive action of TMT in neuronal cultures. The presence of astrocytes appears to modulate TMT-induced oxidative stress so that TMT causes only a small increase in lipid peroxidation in mouse brain after systemic administration. Thus, TMT induces a pronounced oxidative stress in cultured neurons, but when astrocytes are present, oxidative species play a lesser role in the neurotoxic action of TMT. © 2001 John Wiley & Sons, Inc. J Biochem Mol Toxicol 15:256,262, 2001 [source] Nitrobenzene toxicity: QSAR correlations and mechanistic interpretations,JOURNAL OF PHYSICAL ORGANIC CHEMISTRY, Issue 10 2003Alan R. Katritzky Abstract The overall five-parameter QSAR correlation [ in terms of log(IGC50,1)] based on CODESSA-PRO methodology for the aquatic toxicity of 97 substituted nitrobenzenes to the ciliate Tetrahymena pyriformis supports previous conclusions that hydrophobicity and electrophilic reactivity control nitrobenzene toxicity. Correcting for the ionization of acidic species (picric and nitrobenzoic acids) improves the results: . Consideration of the total set of 97 compounds suggests two mechanisms of toxic action. A subset containing 43 compounds favorably disposed to reversible reduction of nitro group with respect to the single occupied molecular orbital energy, ESOMO correlated well with just four theoretically derived descriptors: . Another set of 49 substances predisposed to aromatic nucleophilic substitution modeled well () with five descriptors. Copyright © 2003 John Wiley & Sons, Ltd. [source] Toxicity Effect of Pb(II) on Two Different Kinds of Microbes Measured by MicrocalorimetryCHINESE JOURNAL OF CHEMISTRY, Issue 3 2009Nan GAI Abstract In this work, microcalorimetric technique was used to analyze Pb(II) toxic action on the metabolic activities of Candida humicola and Bacillus subtilis. The experimental results revealed that Pb(II) had a stimulating effect on C. humicola and B. subtilis growth at a relatively low concentration (10.0 g·mL,1); while, C. humicola and B. subtilis were inhibited completely when the concentrations were up to 320.0 and 160.0 g·mL,1, respectively, and the relationships between growth rate constant (k) and doses of Pb(II) were approximately linear for the two microbes at certain concerntrations. At the same time, their cell dry weight and turbidity (OD600) during growth were also obtained. Their thermogenic curves of the growth coincided well with their turbidity curves, elucidating that the microcalorimetric method agreed with the routine microbiology methods. All of these corroborate the validity and sensitivity of the microcalorimetric technique to investigate the toxic effect of Pb(II) on soil microorganisms. [source] Alcoholic macrocytosis,is there a role for acetaldehyde and adducts?ADDICTION BIOLOGY, Issue 1 2004Onni Niemelä Although alcohol abuse is known to cause a wide array of adverse effects on blood cell formation, the molecular mechanisms by which alcohol exerts its toxic actions have remained poorly defined. Elevated mean corpuscular volume (MCV), macrocytosis, is the most typical morphological abnormality induced by excessive ethanol consumption. This paper reviews recent data indicating that acetaldehyde, the first metabolite of ethanol, may play a role in the haematological derangements in peripheral blood cells and in bone marrow of alcoholic patients. Studies in experimental animals and in human alcoholics have shown that acetaldehyde can bind to proteins and cellular constituents forming stable adducts. Elevated adduct levels have been found from the erythrocytes of alcohol abusers, which may also be associated with ethanol-induced effects in haematopoiesis and adverse consequences in cellular functions. [source] Back to the Future: Middle Molecules, High Flux Membranes, and Optimal DialysisHEMODIALYSIS INTERNATIONAL, Issue 1 2003Raymond C. Vanholder Middle molecules can be defined as compounds with a molecular weight (MW) above 500 Da. An even broader definition includes those molecules that do not cross the membranes of standard low-flux dialyzers, not only because of molecular weight, but also because of protein binding and/or multicompartmental behavior. Recently, several of these middle molecules have been linked to the increased tendency of uremic patients to develop inflammation, malnutrition, and atheromatosis. Other toxic actions can also be attributed to the middle molecules. In the present publication we will consider whether improved removal of middle molecules by large pore membranes has an impact on clinical conditions related to the uremic syndrome. The clinical benefits of large pore membranes are reduction of uremia-related amyloidosis; maintenance of residual renal function; and reduction of inflammation, malnutrition, anemia, dyslipidemia, and mortality. It is concluded that middle molecules play a role in uremic toxicity and especially in the processes related to inflammation, atherogenesis, and malnutrition. Their removal seems to be related to a better outcome, although better biocompatibility of membranes might be a confounding factor. [source] | ||||||||||||||||