An assessment of the relative influence of a vapor recovery system in reducing occupational exposure to volatile organic compounds in high performance liquid chromatography

Occupational exposures to organic solvents, specifically acetonitrile and methanol, have the potential to cause serious long-term health effects. In the laboratory, these solvents are used extensively in protocols involving the use of high performance liquid chromatography (HPLC). Operators of HPLC equipment may be potentially exposed to these organic solvents when local exhaust ventilation is not employed properly or is not available, which can be the case in many settings. The objective of this research was to characterize the various sites of vapor release in the HPLC process and then to determine the relative influence of a novel vapor recovery system on the overall exposure to laboratory personnel. The effectiveness of steps to reduce environmental solvent vapor concentrations was assessed by measuring exposure levels of acetonitrile and methanol before and after installation of the vapor recovery system. With respect to acetonitrile, the concentration was not statistically significant with p=0.938; moreover, exposure after the intervention was actually higher than prior to intervention. With respect to methanol, the concentration was not statistically significant with p=0.278. This indicates that the exposure to methanol after the intervention was not statistically significantly higher or lower than prior to intervention. Thus, installation of the vapor recovery device did not result in statistically significant reduction in exposures in the settings encountered, and acetonitrile actually increased significantly.^

ATP- and carbachol -stimulated 1,2-diacylglycerol production during sensitization of adenylyl cyclase

Stimulation of LM5 cells with the phorbol ester 4$\beta$-phorbol 12-myristate 13-acetate (PMA), causes a 2-4 fold sensitization of hormonally-stimulated adenylyl cyclase (AC) activity. This effect is thought to be due to protein kinase C (PKC)-mediated phosphorylation of either G$\sb{\rm i}$ or the catalytic subunit of AC. PKC are components of the phosphatidylinositol-4,5-bisphosphate phospholipase C (PIP$\sb2$-PLC) pathway. The currently accepted model of this pathway is that its activation by an agonist results in the production of inositol 1,4,5-triphosphate (IP$\sb3$) which causes Ca$\sp{++}$ mobilization, and 1,2-diacylglycerols (DAG) which activate PKC. Based on this model, we predicted that stimulation of purinergic and muscarinic receptors with the agonists ATP and carbachol (CCh), respectively in the LM5 cells, should sensitize AC. Surprisingly we found that only stimulation of the purinergic receptors in these cells caused a sensitization of PGE$\sb1$-stimulated AC measured in cell-free assays.^ We hypothesized that ATP-and CCh-stimulated differential DAG production contributes to the effectiveness of these two agonists to sensitize PGE$\sb1$-stimulated AC activity. To test this hypothesis directly, we performed a combined high-performance liquid chromatography and gas-liquid chromatography analysis of the DAG produced in the LM5 cells in response to stimulation with ATP and CCh.^ We found that both ATP and CCh increased levels of 23 species of DAG. Relative to the control levels (0.261 nmol DAG/100 nmol phospholipid) the CCh-induced increase in DAG levels was 280% (0.738 $\pm$ 0.051 nmol DAG/100 nmol phospholipid) whereas the ATP-induced levels increased 180% (0.441 t 0.006 nmol DAG/100 nmol phospholipid). Neither agonist created new species or eliminated the existing ones. The major species which comprised $\approx$50% of the total cellular DAG in all of the groups were 16:0-18:1, 18:0-18:1, 18:1-18:1, and 18:0-20:4. CCh was more effective than ATP at stimulating these major DAG species.^ It is concluded that factor(s) other than DAG contribute(s) to the differences between ATP-and CCh-sensitization of PGE$\sb1$-stimulated AC activity in the LM5 cells. ^

Presence of three pesticides in rural drinking water sources in Kenya

A cross-sectional study on the use of three pesticides and their presence in drinking water sources was conducted in Githunguri/Kiaria community between January 1994-March 1995. The main objective of the study was to determine the extent to which some of the pesticides used by the Githunguri/Kiaria agricultural community were polluting their drinking water sources. Due to monetary and physical limitations, only DDT, its isomers and metabolites, carbofuran and carbaryl pesticides were identified and used as surrogates of pollution for the other pesticides.^ The study area was divided into high and low lying geographic surface areas. Thirty-four and 38 water sampling sites were randomly selected respectively. During wet and dry seasons, a total of 144 water samples were collected and analyzed at the Kenya Bureau of Standards Laboratory in Nairobi. Gas chromatography was used to analyze samples for possible presence of DDT, its isomers and metabolites, while high pressure liquid chromatography was used to analyze samples for carbofuran and carbaryl pesticides.^ Six sites testing positively for DDT, its isomers and metabolites represented 19.4% of the total sampled sites, with a mean concentration of 0.00310 ppb in the dry season and 0.0130 ppb in the wet season. All the six sites testing positively for the same pesticide exceeded the European maximum contaminant limit (MCL) in the wet season, and only one site exceeded the European MCL in the dry season.^ Those sites testing positively for carbofuran and carbaryl represented 5.6% of the total sampled sites. The mean concentration for the carbofuran at the sites was 2.500 ppb and 1.590 ppb in the dry and wet seasons respectively. Similarly, the mean concentration for carbaryl at the sites was 0.281 ppb in the dry season and 0.326 ppb in the wet season.^ One site testing positively for carbofuran exceeded the European MCL and WHO set limit in the wet season, while one site testing positively for the same pesticide exceeded the USA, Canada, European and WHO MCLs in the dry season. Similarly, one site which tested positively for carbaryl pesticide exceeded the European MCL in both seasons.^ Out of the 2,587 community members in the study area, 333 (13%) were exposed through their drinking water sources to the three pesticides investigated by this study. As a public health measure, integrated pest management approaches (IPM), protection of the wells and education of the community is necessary to minimize the pollution of the environment and safeguard the drinking water sources from pollution by the pesticides. ^