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Charles R. Sterling - One of the best experts on this subject based on the ideXlab platform.
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A spore counting method and Cell Culture model for chlorine disinfection studies of Encephalitozoon syn. Septata intestinalis.
Applied and Environmental Microbiology, 2000Co-Authors: Donna M. Wolk, Clifford H. Johnson, Eugene W. Rice, Marilyn M. Marshall, K. F. Grahn, C. B. Plummer, Charles R. SterlingAbstract:The microsporidia have recently been recognized as a group of pathogens that have potential for waterborne transmission; however, little is known about the effects of routine disinfection on microsporidian spore viability. In this study, in vitro growth ofEncephalitozoon syn. Septata intestinalis, a microsporidium found in the human gut, was used as a model to assess the effect of chlorine on the infectivity and viability of microsporidian spores. Spore inoculum concentrations were determined by using spectrophotometric measurements (percent transmittance at 625 nm) and by traditional hemacytometer counting. To determine quantitative dose-response data for spore infectivity, we optimized a rabbit Kidney Cell Culture system in 24-well plates, which facilitated calculation of a 50% tissue Culture infective dose (TCID50) and a minimal infective dose (MID) for E. intestinalis. The TCID50 is a quantitative measure of infectivity and growth and is the number of organisms that must be present to infect 50% of the Cell Culture wells tested. The MID is as a measure of a system9s permissiveness to infection and a measure of spore infectivity. A standardized MID and a standardized TCID50 have not been reported previously for any microsporidian species. Both types of doses are reported in this paper, and the values were used to evaluate the effects of chlorine disinfection on the in vitro growth of microsporidia. Spores were treated with chlorine at concentrations of 0, 1, 2, 5, and 10 mg/liter. The exposure times ranged from 0 to 80 min at 25°C and pH 7. MID data for E. intestinalis were compared before and after chlorine disinfection. A 3-log reduction (99.9% inhibition) in the E. intestinalis MID was observed at a chlorine concentration of 2 mg/liter after a minimum exposure time of 16 min. The log10 reduction results based on percent transmittance-derived spore counts were equivalent to the results based on hemacytometer-derived spore counts. Our data suggest that chlorine treatment may be an effective water treatment for E. intestinalis and that spectrophotometric methods may be substituted for labor-intensive hemacytometer methods when spores are counted in laboratory-based chlorine disinfection studies.
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a spore counting method and Cell Culture model for chlorine disinfection studies of encephalitozoon syn septata intestinalis
Applied and Environmental Microbiology, 2000Co-Authors: Donna M. Wolk, Clifford H. Johnson, Eugene W. Rice, Marilyn M. Marshall, K. F. Grahn, C. B. Plummer, Charles R. SterlingAbstract:The microsporidia have recently been recognized as a group of pathogens that have potential for waterborne transmission; however, little is known about the effects of routine disinfection on microsporidian spore viability. In this study, in vitro growth of Encephalitozoon syn. Septata intestinalis, a microsporidium found in the human gut, was used as a model to assess the effect of chlorine on the infectivity and viability of microsporidian spores. Spore inoculum concentrations were determined by using spectrophotometric measurements (percent transmittance at 625 nm) and by traditional hemacytometer counting. To determine quantitative dose-response data for spore infectivity, we optimized a rabbit Kidney Cell Culture system in 24-well plates, which facilitated calculation of a 50% tissue Culture infective dose (TCID(50)) and a minimal infective dose (MID) for E. intestinalis. The TCID(50) is a quantitative measure of infectivity and growth and is the number of organisms that must be present to infect 50% of the Cell Culture wells tested. The MID is as a measure of a system's permissiveness to infection and a measure of spore infectivity. A standardized MID and a standardized TCID(50) have not been reported previously for any microsporidian species. Both types of doses are reported in this paper, and the values were used to evaluate the effects of chlorine disinfection on the in vitro growth of microsporidia. Spores were treated with chlorine at concentrations of 0, 1, 2, 5, and 10 mg/liter. The exposure times ranged from 0 to 80 min at 25 degrees C and pH 7. MID data for E. intestinalis were compared before and after chlorine disinfection. A 3-log reduction (99.9% inhibition) in the E. intestinalis MID was observed at a chlorine concentration of 2 mg/liter after a minimum exposure time of 16 min. The log(10) reduction results based on percent transmittance-derived spore counts were equivalent to the results based on hemacytometer-derived spore counts. Our data suggest that chlorine treatment may be an effective water treatment for E. intestinalis and that spectrophotometric methods may be substituted for labor-intensive hemacytometer methods when spores are counted in laboratory-based chlorine disinfection studies.
Donna M. Wolk - One of the best experts on this subject based on the ideXlab platform.
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A spore counting method and Cell Culture model for chlorine disinfection studies of Encephalitozoon syn. Septata intestinalis.
Applied and Environmental Microbiology, 2000Co-Authors: Donna M. Wolk, Clifford H. Johnson, Eugene W. Rice, Marilyn M. Marshall, K. F. Grahn, C. B. Plummer, Charles R. SterlingAbstract:The microsporidia have recently been recognized as a group of pathogens that have potential for waterborne transmission; however, little is known about the effects of routine disinfection on microsporidian spore viability. In this study, in vitro growth ofEncephalitozoon syn. Septata intestinalis, a microsporidium found in the human gut, was used as a model to assess the effect of chlorine on the infectivity and viability of microsporidian spores. Spore inoculum concentrations were determined by using spectrophotometric measurements (percent transmittance at 625 nm) and by traditional hemacytometer counting. To determine quantitative dose-response data for spore infectivity, we optimized a rabbit Kidney Cell Culture system in 24-well plates, which facilitated calculation of a 50% tissue Culture infective dose (TCID50) and a minimal infective dose (MID) for E. intestinalis. The TCID50 is a quantitative measure of infectivity and growth and is the number of organisms that must be present to infect 50% of the Cell Culture wells tested. The MID is as a measure of a system9s permissiveness to infection and a measure of spore infectivity. A standardized MID and a standardized TCID50 have not been reported previously for any microsporidian species. Both types of doses are reported in this paper, and the values were used to evaluate the effects of chlorine disinfection on the in vitro growth of microsporidia. Spores were treated with chlorine at concentrations of 0, 1, 2, 5, and 10 mg/liter. The exposure times ranged from 0 to 80 min at 25°C and pH 7. MID data for E. intestinalis were compared before and after chlorine disinfection. A 3-log reduction (99.9% inhibition) in the E. intestinalis MID was observed at a chlorine concentration of 2 mg/liter after a minimum exposure time of 16 min. The log10 reduction results based on percent transmittance-derived spore counts were equivalent to the results based on hemacytometer-derived spore counts. Our data suggest that chlorine treatment may be an effective water treatment for E. intestinalis and that spectrophotometric methods may be substituted for labor-intensive hemacytometer methods when spores are counted in laboratory-based chlorine disinfection studies.
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a spore counting method and Cell Culture model for chlorine disinfection studies of encephalitozoon syn septata intestinalis
Applied and Environmental Microbiology, 2000Co-Authors: Donna M. Wolk, Clifford H. Johnson, Eugene W. Rice, Marilyn M. Marshall, K. F. Grahn, C. B. Plummer, Charles R. SterlingAbstract:The microsporidia have recently been recognized as a group of pathogens that have potential for waterborne transmission; however, little is known about the effects of routine disinfection on microsporidian spore viability. In this study, in vitro growth of Encephalitozoon syn. Septata intestinalis, a microsporidium found in the human gut, was used as a model to assess the effect of chlorine on the infectivity and viability of microsporidian spores. Spore inoculum concentrations were determined by using spectrophotometric measurements (percent transmittance at 625 nm) and by traditional hemacytometer counting. To determine quantitative dose-response data for spore infectivity, we optimized a rabbit Kidney Cell Culture system in 24-well plates, which facilitated calculation of a 50% tissue Culture infective dose (TCID(50)) and a minimal infective dose (MID) for E. intestinalis. The TCID(50) is a quantitative measure of infectivity and growth and is the number of organisms that must be present to infect 50% of the Cell Culture wells tested. The MID is as a measure of a system's permissiveness to infection and a measure of spore infectivity. A standardized MID and a standardized TCID(50) have not been reported previously for any microsporidian species. Both types of doses are reported in this paper, and the values were used to evaluate the effects of chlorine disinfection on the in vitro growth of microsporidia. Spores were treated with chlorine at concentrations of 0, 1, 2, 5, and 10 mg/liter. The exposure times ranged from 0 to 80 min at 25 degrees C and pH 7. MID data for E. intestinalis were compared before and after chlorine disinfection. A 3-log reduction (99.9% inhibition) in the E. intestinalis MID was observed at a chlorine concentration of 2 mg/liter after a minimum exposure time of 16 min. The log(10) reduction results based on percent transmittance-derived spore counts were equivalent to the results based on hemacytometer-derived spore counts. Our data suggest that chlorine treatment may be an effective water treatment for E. intestinalis and that spectrophotometric methods may be substituted for labor-intensive hemacytometer methods when spores are counted in laboratory-based chlorine disinfection studies.
Sung-nain Tseng - One of the best experts on this subject based on the ideXlab platform.
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Anti-influenza drug discovery: structure-activity relationship and mechanistic insight into novel angelicin derivatives.
Journal of Medicinal Chemistry, 2010Co-Authors: Jiann-yih Yeh, Mohane Selvaraj Coumar, Jim-tong Horng, Hui-yi Shiao, Fu-ming Kuo, Hui-ling Lee, In-chun Chen, Chun Wei Chang, Wen-fang Tang, Sung-nain TsengAbstract:By using a Cell-based high throughput screening campaign, a novel angelicin derivative 6a was identified to inhibit influenza A (H1N1) virus induced cytopathic effect in Madin−Darby canine Kidney Cell Culture in low micromolar range. Detailed structure−activity relationship studies of 6a revealed that the angelicin scaffold is essential for activity in pharmacophore B, while meta-substituted phenyl/2-thiophene rings are optimal in pharmacophore A and C. The optimized lead 4-methyl-9-phenyl-8-(thiophene-2-carbonyl)-furo[2,3-h]chromen-2-one (8g, IC50 = 70 nM) showed 64-fold enhanced activity compared to the high throughput screening (HTS) hit 6a. Also, 8g was found effective in case of influenza A (H3N2) and influenza B virus strains similar to approved anti-influenza drug zanamivir (4). Preliminary mechanistic studies suggest that these compounds act as anti-influenza agents by inhibiting ribonucleoprotein (RNP) complex associated activity and have the potential to be developed further, which could form th...
Marilyn M. Marshall - One of the best experts on this subject based on the ideXlab platform.
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A spore counting method and Cell Culture model for chlorine disinfection studies of Encephalitozoon syn. Septata intestinalis.
Applied and Environmental Microbiology, 2000Co-Authors: Donna M. Wolk, Clifford H. Johnson, Eugene W. Rice, Marilyn M. Marshall, K. F. Grahn, C. B. Plummer, Charles R. SterlingAbstract:The microsporidia have recently been recognized as a group of pathogens that have potential for waterborne transmission; however, little is known about the effects of routine disinfection on microsporidian spore viability. In this study, in vitro growth ofEncephalitozoon syn. Septata intestinalis, a microsporidium found in the human gut, was used as a model to assess the effect of chlorine on the infectivity and viability of microsporidian spores. Spore inoculum concentrations were determined by using spectrophotometric measurements (percent transmittance at 625 nm) and by traditional hemacytometer counting. To determine quantitative dose-response data for spore infectivity, we optimized a rabbit Kidney Cell Culture system in 24-well plates, which facilitated calculation of a 50% tissue Culture infective dose (TCID50) and a minimal infective dose (MID) for E. intestinalis. The TCID50 is a quantitative measure of infectivity and growth and is the number of organisms that must be present to infect 50% of the Cell Culture wells tested. The MID is as a measure of a system9s permissiveness to infection and a measure of spore infectivity. A standardized MID and a standardized TCID50 have not been reported previously for any microsporidian species. Both types of doses are reported in this paper, and the values were used to evaluate the effects of chlorine disinfection on the in vitro growth of microsporidia. Spores were treated with chlorine at concentrations of 0, 1, 2, 5, and 10 mg/liter. The exposure times ranged from 0 to 80 min at 25°C and pH 7. MID data for E. intestinalis were compared before and after chlorine disinfection. A 3-log reduction (99.9% inhibition) in the E. intestinalis MID was observed at a chlorine concentration of 2 mg/liter after a minimum exposure time of 16 min. The log10 reduction results based on percent transmittance-derived spore counts were equivalent to the results based on hemacytometer-derived spore counts. Our data suggest that chlorine treatment may be an effective water treatment for E. intestinalis and that spectrophotometric methods may be substituted for labor-intensive hemacytometer methods when spores are counted in laboratory-based chlorine disinfection studies.
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a spore counting method and Cell Culture model for chlorine disinfection studies of encephalitozoon syn septata intestinalis
Applied and Environmental Microbiology, 2000Co-Authors: Donna M. Wolk, Clifford H. Johnson, Eugene W. Rice, Marilyn M. Marshall, K. F. Grahn, C. B. Plummer, Charles R. SterlingAbstract:The microsporidia have recently been recognized as a group of pathogens that have potential for waterborne transmission; however, little is known about the effects of routine disinfection on microsporidian spore viability. In this study, in vitro growth of Encephalitozoon syn. Septata intestinalis, a microsporidium found in the human gut, was used as a model to assess the effect of chlorine on the infectivity and viability of microsporidian spores. Spore inoculum concentrations were determined by using spectrophotometric measurements (percent transmittance at 625 nm) and by traditional hemacytometer counting. To determine quantitative dose-response data for spore infectivity, we optimized a rabbit Kidney Cell Culture system in 24-well plates, which facilitated calculation of a 50% tissue Culture infective dose (TCID(50)) and a minimal infective dose (MID) for E. intestinalis. The TCID(50) is a quantitative measure of infectivity and growth and is the number of organisms that must be present to infect 50% of the Cell Culture wells tested. The MID is as a measure of a system's permissiveness to infection and a measure of spore infectivity. A standardized MID and a standardized TCID(50) have not been reported previously for any microsporidian species. Both types of doses are reported in this paper, and the values were used to evaluate the effects of chlorine disinfection on the in vitro growth of microsporidia. Spores were treated with chlorine at concentrations of 0, 1, 2, 5, and 10 mg/liter. The exposure times ranged from 0 to 80 min at 25 degrees C and pH 7. MID data for E. intestinalis were compared before and after chlorine disinfection. A 3-log reduction (99.9% inhibition) in the E. intestinalis MID was observed at a chlorine concentration of 2 mg/liter after a minimum exposure time of 16 min. The log(10) reduction results based on percent transmittance-derived spore counts were equivalent to the results based on hemacytometer-derived spore counts. Our data suggest that chlorine treatment may be an effective water treatment for E. intestinalis and that spectrophotometric methods may be substituted for labor-intensive hemacytometer methods when spores are counted in laboratory-based chlorine disinfection studies.
K. F. Grahn - One of the best experts on this subject based on the ideXlab platform.
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A spore counting method and Cell Culture model for chlorine disinfection studies of Encephalitozoon syn. Septata intestinalis.
Applied and Environmental Microbiology, 2000Co-Authors: Donna M. Wolk, Clifford H. Johnson, Eugene W. Rice, Marilyn M. Marshall, K. F. Grahn, C. B. Plummer, Charles R. SterlingAbstract:The microsporidia have recently been recognized as a group of pathogens that have potential for waterborne transmission; however, little is known about the effects of routine disinfection on microsporidian spore viability. In this study, in vitro growth ofEncephalitozoon syn. Septata intestinalis, a microsporidium found in the human gut, was used as a model to assess the effect of chlorine on the infectivity and viability of microsporidian spores. Spore inoculum concentrations were determined by using spectrophotometric measurements (percent transmittance at 625 nm) and by traditional hemacytometer counting. To determine quantitative dose-response data for spore infectivity, we optimized a rabbit Kidney Cell Culture system in 24-well plates, which facilitated calculation of a 50% tissue Culture infective dose (TCID50) and a minimal infective dose (MID) for E. intestinalis. The TCID50 is a quantitative measure of infectivity and growth and is the number of organisms that must be present to infect 50% of the Cell Culture wells tested. The MID is as a measure of a system9s permissiveness to infection and a measure of spore infectivity. A standardized MID and a standardized TCID50 have not been reported previously for any microsporidian species. Both types of doses are reported in this paper, and the values were used to evaluate the effects of chlorine disinfection on the in vitro growth of microsporidia. Spores were treated with chlorine at concentrations of 0, 1, 2, 5, and 10 mg/liter. The exposure times ranged from 0 to 80 min at 25°C and pH 7. MID data for E. intestinalis were compared before and after chlorine disinfection. A 3-log reduction (99.9% inhibition) in the E. intestinalis MID was observed at a chlorine concentration of 2 mg/liter after a minimum exposure time of 16 min. The log10 reduction results based on percent transmittance-derived spore counts were equivalent to the results based on hemacytometer-derived spore counts. Our data suggest that chlorine treatment may be an effective water treatment for E. intestinalis and that spectrophotometric methods may be substituted for labor-intensive hemacytometer methods when spores are counted in laboratory-based chlorine disinfection studies.
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a spore counting method and Cell Culture model for chlorine disinfection studies of encephalitozoon syn septata intestinalis
Applied and Environmental Microbiology, 2000Co-Authors: Donna M. Wolk, Clifford H. Johnson, Eugene W. Rice, Marilyn M. Marshall, K. F. Grahn, C. B. Plummer, Charles R. SterlingAbstract:The microsporidia have recently been recognized as a group of pathogens that have potential for waterborne transmission; however, little is known about the effects of routine disinfection on microsporidian spore viability. In this study, in vitro growth of Encephalitozoon syn. Septata intestinalis, a microsporidium found in the human gut, was used as a model to assess the effect of chlorine on the infectivity and viability of microsporidian spores. Spore inoculum concentrations were determined by using spectrophotometric measurements (percent transmittance at 625 nm) and by traditional hemacytometer counting. To determine quantitative dose-response data for spore infectivity, we optimized a rabbit Kidney Cell Culture system in 24-well plates, which facilitated calculation of a 50% tissue Culture infective dose (TCID(50)) and a minimal infective dose (MID) for E. intestinalis. The TCID(50) is a quantitative measure of infectivity and growth and is the number of organisms that must be present to infect 50% of the Cell Culture wells tested. The MID is as a measure of a system's permissiveness to infection and a measure of spore infectivity. A standardized MID and a standardized TCID(50) have not been reported previously for any microsporidian species. Both types of doses are reported in this paper, and the values were used to evaluate the effects of chlorine disinfection on the in vitro growth of microsporidia. Spores were treated with chlorine at concentrations of 0, 1, 2, 5, and 10 mg/liter. The exposure times ranged from 0 to 80 min at 25 degrees C and pH 7. MID data for E. intestinalis were compared before and after chlorine disinfection. A 3-log reduction (99.9% inhibition) in the E. intestinalis MID was observed at a chlorine concentration of 2 mg/liter after a minimum exposure time of 16 min. The log(10) reduction results based on percent transmittance-derived spore counts were equivalent to the results based on hemacytometer-derived spore counts. Our data suggest that chlorine treatment may be an effective water treatment for E. intestinalis and that spectrophotometric methods may be substituted for labor-intensive hemacytometer methods when spores are counted in laboratory-based chlorine disinfection studies.
