nitrogen-dioxide and formic-acid

Indoor air quality (IAQ) is a major concern, because people on average spend the vast majority of their time indoors and they are repeatedly exposed to indoor air pollutants. In this study, to assess indoor air quality in Chiba City, gaseous chemical compounds were surveyed using four types of diffusive sampler.. Gaseous chemical compounds such as carbonyls, volatile organic compounds (VOC), acid gases, basic gases, and ozone were measured in indoor and outdoor air of 50 houses throughout Chiba City in winter and summer. Four types of diffusive sampler were used in this study: DSD-BPE/DNPH packed with 2,4-dinitrophenyl hydrazine and trans-1,2-bis(2-pyridyl)ethylene-coated silica for ozone and carbonyls; VOC-SD packed with Carboxen 564 particles for volatile organic compounds; DSD-TEA packed with triethanolamine-impregnated silica for acid gases; and DSD-NH3 packed with phosphoric acid-impregnated silica for basic gases.. Almost all compounds in indoor air were detected at higher concentrations in summer than in winter. However, the nitrogen dioxide concentration in indoor air particularly increased only in winter, which well correlated with the formic acid concentration (correlation coefficient=0.974). The compound with the highest concentrations in indoor air was p-dichlorobenzene, with recorded levels of 13,000 μg m(-3) in summer and 1,100 μg m(-3) in winter in indoor air.. p-Dichlorobenzene in summer and nitrogen dioxide in winter are detected at markedly high concentrations. Pollution control and continuous monitoring of IAQ are indispensable for human health.

Topics: Air; Air Pollutants; Air Pollution, Indoor; Chlorobenzenes; Environmental Monitoring; Formates; Gases; Japan; Nitrogen Dioxide; Seasons

The assessment of damage to indoor cultural heritage, in particular by pollutants, is nowadays a major and growing concern for curators and conservators. Nevertheless, although many museums have been widely investigated in Europe, the effects of particulate matter and gaseous pollutants in museums under tropical and subtropical climates and with different economic realities are still unclear. An important portion of the world's cultural heritage is currently in tropical countries where both human and financial resources for preserving museum collections are limited. Hence, our aim is to assess the damage that can be caused to the artwork by pollution in hot and humid environments, where air quality and microclimatic condition differences can cause deterioration. As a case study, particulate matter as well as gases were collected at the Oscar Niemeyer Museum (MON) in Curitiba, Brazil, where large modern and contemporary works of art are displayed. NO2, SO2, O3, Acetic Acid, Formic Acids and BTEX, in the ambient air, were sampled by means of passive diffusive sampling and their concentrations were determined by IC or GC-MS. The particulate matter was collected in bulk form and analyzed with the use of energy dispersive X-ray fluorescence and aethalometer. The chemical compositions of individual particles were quantitatively elucidated, including low-Z components like C, N and O, as well as higher-Z elements, using automated electron probe microanalysis. The gaseous and particulate matter levels were then compared with the concentrations obtained for the same pollutants in other museums, located in places with different climates, and with some reference values provided by international cultural heritage conservation centers. Results are interpreted separately and as a whole with the specific aim of identifying compounds that could contribute to the chemical reactions taking place on the surfaces of artifacts and which could potentially cause irreversible damage to the artworks.

Topics: Acetic Acid; Aerosols; Air Conditioning; Air Pollutants; Air Pollution, Indoor; Art; Brazil; Formates; Gas Chromatography-Mass Spectrometry; Humans; Museums; Nitrogen Dioxide; Ozone; Particulate Matter; Sulfur Dioxide; Tropical Climate

The killing of Escherichia coli by nitrite plus hydrogen peroxide was observed in lactate, but not in phosphate or acetate. Although nitrite or hydrogen peroxide alone caused a slight decrease in bacterial survival, nitrite plus hydrogen peroxide killed bacteria synergistically in time-, dose-, and pH-dependent manners. The killing was increased with decreasing pH. The plot of viable cells versus [nitrous acid] was linear. Among the hydroxyl radical scavengers used, only benzoate and formate at concentrations higher than that of lactate inhibited the killing by nitrite plus hydrogen peroxide, whereas dimethyl sulfoxide enhanced it. The generation of peroxynitrous acid during the reaction of nitrite and hydrogen peroxide was confirmed by the formation of malondialdehyde using deoxyribose as a hydroxyl radical-like oxidant detector. The nitration of glycyl-tryosine was observed only in lactate buffer, but not in phosphate and acetate buffers. Benzoate and formate inhibited the nitration, whereas dimethyl sulfoxide and ethanol enhanced it. No evidence for the formation of nitric oxide and superoxide during the reaction of nitrite and hydrogen peroxide was found. These data suggest that nitrogen dioxide from the decomposition of peroxynitrous acid or secondary oxidants formed from the reaction of peroxynitrous acid with lactate is responsible for the lactate-dependent killing of E. coli induced by the reaction of protonated nitrite and hydrogen peroxide.

Topics: Animals; Benzoates; Benzoic Acid; Cattle; Deoxyribose; Dimethyl Sulfoxide; Drug Synergism; Escherichia coli; Ethanol; Formates; Free Radical Scavengers; Humans; Hydrogen Peroxide; Hydrogen-Ion Concentration; Hydroxyl Radical; Kinetics; Lactates; Lactic Acid; Malondialdehyde; Nitrites; Nitrogen Dioxide

The influence of HCHO and NO2 on clinical, haematological, immunological, sensory and lung function parameters were tested in 129 children out of 3 classes. As part of a biological monitoring programme formic acid content in urine was determined. Concentration of the pollutants in indoor air was measured by means of passive samples.

Topics: Air Pollutants; Child, Preschool; Formaldehyde; Formates; Humans; Nitrogen Dioxide; Time Factors