Cytotoxicity of selected metal oxide nanoparticles(MNPs)(ZnO,CuO,Co 3 O 4 and TiO 2)was investigated in Escherichia coli both under light and dark conditions.Cytotoxicity experiments were conducted with spread pla...Cytotoxicity of selected metal oxide nanoparticles(MNPs)(ZnO,CuO,Co 3 O 4 and TiO 2)was investigated in Escherichia coli both under light and dark conditions.Cytotoxicity experiments were conducted with spread plate counting and the LC 50 values were calculated.We determined the mechanism of toxicity via measurements of oxidative stress,reduced glutathione,lipid peroxidation,and metal ions.The overall ranking of the LC 50 values was in the order of ZnO 〈 CuO 〈 Co 3 O 4 〈 TiO 2 under dark condition and ZnO 〈 CuO 〈 TiO 2 〈 Co 3 O 4 under light condition.ZnO MNPs were the most toxic among the tested nanoparticles.Our results indicate depletion of reduced glutathione level and elevation of malondialdehyde level correlated with the increase in oxidative stress.Released metal ions were found to have partial effect on the toxicity of MNPs to E.coli.In summary,the dynamic interactions of multiple mechanisms lead to the toxicity of the tested MNPs to E.coli.展开更多
The effect of a terrestrial humic acid (HA) and Suwannee River HA on the cytotoxicity of engineered zinc oxide nanoparticles (ZnONPs) and titanium dioxide nanoparticles (TiO2NPs) to natural aquatic bacterial ass...The effect of a terrestrial humic acid (HA) and Suwannee River HA on the cytotoxicity of engineered zinc oxide nanoparticles (ZnONPs) and titanium dioxide nanoparticles (TiO2NPs) to natural aquatic bacterial assemblages was measured with spread plate counting. The effect of HA (10 and 40 ppm) on the cytotoxicity of ZnONPs and TiO2NPs was tested factorially in the presence and absence of natural sunlight (light irradiation (LI)). The experiment was of full factorial, completely randomized design and the results were analyzed using the General Linear Model in SAS analytical software. The method of least squares means was used to separate the means or combinations of means. We determined the mechanism of toxicity via measurements of oxidative stress and metal ions. The toxicity of ZnONPs and TiO2NPs to natural aquatic bacterial assemblages appears to be concentration dependent. Moreover, the cytotoxicity of ZnONPs and TiO2NPs appeared to be affected by HA concentration, the presence of sunlight irradiation, and the dynamic multiple interactions among these factors. With respect to light versus darkness in the control group, the data indicate that bacterial viability was inhibited more in the light exposure than in the darkness exposure. The same was true in the HA treatment groups. With respect to terrestrial versus Suwanee River HA for a given nanoparticle, in light versus darkness, bacterial viability was more inhibited in the light treatment groups containing the terrestrial HA than in those containing Suwanee River HA. Differences in the extent of reactive oxygen species formation, adsorption/binding of ZnONPs/TiO2NPs by HA, and the levels of free metal ions were speculated to account for the observed cytotoxicity. TEM images indicate the attachment and binding of the tested nanoparticles to natural bacterial assemblages. Besides the individual parameter, significant effects on bacterial viability count were also observed in the following combined treatments: HA-ZnONPs, HA-LI, ZnONPs-LI, and HA-ZnONPs-LI. The main effects of all independent variables, plus interaction effects in all cases were significant with TiO2NPs.展开更多
Titanium dioxide nanoparticles(TiO_(2)NPs)are among the most widely manufactured nanomaterials on a global scale.However,prudent and vigilant surveillance,incumbent upon the scientific community with the advent of new...Titanium dioxide nanoparticles(TiO_(2)NPs)are among the most widely manufactured nanomaterials on a global scale.However,prudent and vigilant surveillance,incumbent upon the scientific community with the advent of new technologies,has revealed potentially undesirable effects of TiO2 NPs on biological systems and the natural environment during their application and discharge.Such effects are likely best evaluated by first assessing the fate of the TiO2 NPs in natural environments.In this study,the effects of terrestrial humic acid(HA)and tannic acid(TA),two major members of the collective:dissolved organic matter(DOM),on the cytotoxicity of TiO2 NPs to Escherichia coli were investigated in the presence and absence of natural sunlight.Qualitative(transmission electron microscopy(TEM))and quantitative(LCso)analyses were employed in this study.In addition,the production of reactive oxygen species(ROS)in the form of.OH was further assessed-as HA or TA increased the production of ROS decreased.The inhibition of bacterial viability in the light treatment groups,with respective treatment organics at concentrations of 10 ppm,was less in TA than in terrestrial HA.SAS was used to analyze the treatment effect of individual factors of light irradiation,DOM,and concentration of TiO2 NPs.展开更多
In this study,the cytotoxicity of two different crystal phases of TiO2 nanoparticles,with surface modification by humic acid(HA),to Escherichia coli,was assessed.The physicochemical properties of TiO2 nanoparticles ...In this study,the cytotoxicity of two different crystal phases of TiO2 nanoparticles,with surface modification by humic acid(HA),to Escherichia coli,was assessed.The physicochemical properties of TiO2 nanoparticles were thoroughly characterized.Three different initial concentrations,namely 50,100,and 200 ppm,of HA were used for synthesis of HA coated TiO2 nanoparticles(denoted as A/RHA50,A/RHA100,and A/RHA200,respectively).Results indicate that rutile(LC50(concentration that causes 50%mortality compared the control group)=6.5)was more toxic than anatase(LC50=278.8)under simulated sunlight(SSL)irradiation,possibly due to an extremely narrow band gap.It is noted that HA coating increased the toxicity of anatase,but decreased that of rutile.Additionally,AHA50 and RHA50had the biggest differences compared to uncoated anatase and rutile with LC50of 201.9 and21.6,respectively.We then investigated the formation of reactive oxygen species(ROS)by TiO2 nanoparticles in terms of hydroxyl radicals(OH)and superoxide anions(O2^-).Data suggested that O2^- was the main ROS that accounted for the higher toxicity of rutile upon SSL irradiation.We also observed that HA coating decreased the generation of OH and O2^- on rutile,but increased O2^- formation on anatase.Results from TEM analysis also indicated that HA coated rutile tended to be attached to the surface of E.coli more than anatase.展开更多
基金NSF-SBIR grant # IIP-0823040NSF-CREST program with grant # HRD-0833178Strengthening the Environmental Science Ph.D program in instruction,grant # P031B090210-11
文摘Cytotoxicity of selected metal oxide nanoparticles(MNPs)(ZnO,CuO,Co 3 O 4 and TiO 2)was investigated in Escherichia coli both under light and dark conditions.Cytotoxicity experiments were conducted with spread plate counting and the LC 50 values were calculated.We determined the mechanism of toxicity via measurements of oxidative stress,reduced glutathione,lipid peroxidation,and metal ions.The overall ranking of the LC 50 values was in the order of ZnO 〈 CuO 〈 Co 3 O 4 〈 TiO 2 under dark condition and ZnO 〈 CuO 〈 TiO 2 〈 Co 3 O 4 under light condition.ZnO MNPs were the most toxic among the tested nanoparticles.Our results indicate depletion of reduced glutathione level and elevation of malondialdehyde level correlated with the increase in oxidative stress.Released metal ions were found to have partial effect on the toxicity of MNPs to E.coli.In summary,the dynamic interactions of multiple mechanisms lead to the toxicity of the tested MNPs to E.coli.
基金supported by NSF-SBIR grant # IIP-0823040NSF-CREST Program with grant # HRD-0833178Strengthening the Environmental Science Ph.D Program in instruction, grant # P031B090210-11
文摘The effect of a terrestrial humic acid (HA) and Suwannee River HA on the cytotoxicity of engineered zinc oxide nanoparticles (ZnONPs) and titanium dioxide nanoparticles (TiO2NPs) to natural aquatic bacterial assemblages was measured with spread plate counting. The effect of HA (10 and 40 ppm) on the cytotoxicity of ZnONPs and TiO2NPs was tested factorially in the presence and absence of natural sunlight (light irradiation (LI)). The experiment was of full factorial, completely randomized design and the results were analyzed using the General Linear Model in SAS analytical software. The method of least squares means was used to separate the means or combinations of means. We determined the mechanism of toxicity via measurements of oxidative stress and metal ions. The toxicity of ZnONPs and TiO2NPs to natural aquatic bacterial assemblages appears to be concentration dependent. Moreover, the cytotoxicity of ZnONPs and TiO2NPs appeared to be affected by HA concentration, the presence of sunlight irradiation, and the dynamic multiple interactions among these factors. With respect to light versus darkness in the control group, the data indicate that bacterial viability was inhibited more in the light exposure than in the darkness exposure. The same was true in the HA treatment groups. With respect to terrestrial versus Suwanee River HA for a given nanoparticle, in light versus darkness, bacterial viability was more inhibited in the light treatment groups containing the terrestrial HA than in those containing Suwanee River HA. Differences in the extent of reactive oxygen species formation, adsorption/binding of ZnONPs/TiO2NPs by HA, and the levels of free metal ions were speculated to account for the observed cytotoxicity. TEM images indicate the attachment and binding of the tested nanoparticles to natural bacterial assemblages. Besides the individual parameter, significant effects on bacterial viability count were also observed in the following combined treatments: HA-ZnONPs, HA-LI, ZnONPs-LI, and HA-ZnONPs-LI. The main effects of all independent variables, plus interaction effects in all cases were significant with TiO2NPs.
基金supported by the National Science Foundation-Centers of Research Excellence in Science and Technology(NSF-CREST)(No.HRD-0833178)the National Institutes of Health(NIH)Research Initiative for Scientific Enhancement(RISE)Program(No.5R25GM067122)
文摘Titanium dioxide nanoparticles(TiO_(2)NPs)are among the most widely manufactured nanomaterials on a global scale.However,prudent and vigilant surveillance,incumbent upon the scientific community with the advent of new technologies,has revealed potentially undesirable effects of TiO2 NPs on biological systems and the natural environment during their application and discharge.Such effects are likely best evaluated by first assessing the fate of the TiO2 NPs in natural environments.In this study,the effects of terrestrial humic acid(HA)and tannic acid(TA),two major members of the collective:dissolved organic matter(DOM),on the cytotoxicity of TiO2 NPs to Escherichia coli were investigated in the presence and absence of natural sunlight.Qualitative(transmission electron microscopy(TEM))and quantitative(LCso)analyses were employed in this study.In addition,the production of reactive oxygen species(ROS)in the form of.OH was further assessed-as HA or TA increased the production of ROS decreased.The inhibition of bacterial viability in the light treatment groups,with respective treatment organics at concentrations of 10 ppm,was less in TA than in terrestrial HA.SAS was used to analyze the treatment effect of individual factors of light irradiation,DOM,and concentration of TiO2 NPs.
基金supported in part by the NSF-REU program(National Science Foundation-Research Experiences for Undergraduates,No.#CHE-1156111)the NSF-CREST program(National Science Foundation-Centers of Research Excellencein Science and Technology,No.#HRD-0833178)
文摘In this study,the cytotoxicity of two different crystal phases of TiO2 nanoparticles,with surface modification by humic acid(HA),to Escherichia coli,was assessed.The physicochemical properties of TiO2 nanoparticles were thoroughly characterized.Three different initial concentrations,namely 50,100,and 200 ppm,of HA were used for synthesis of HA coated TiO2 nanoparticles(denoted as A/RHA50,A/RHA100,and A/RHA200,respectively).Results indicate that rutile(LC50(concentration that causes 50%mortality compared the control group)=6.5)was more toxic than anatase(LC50=278.8)under simulated sunlight(SSL)irradiation,possibly due to an extremely narrow band gap.It is noted that HA coating increased the toxicity of anatase,but decreased that of rutile.Additionally,AHA50 and RHA50had the biggest differences compared to uncoated anatase and rutile with LC50of 201.9 and21.6,respectively.We then investigated the formation of reactive oxygen species(ROS)by TiO2 nanoparticles in terms of hydroxyl radicals(OH)and superoxide anions(O2^-).Data suggested that O2^- was the main ROS that accounted for the higher toxicity of rutile upon SSL irradiation.We also observed that HA coating decreased the generation of OH and O2^- on rutile,but increased O2^- formation on anatase.Results from TEM analysis also indicated that HA coated rutile tended to be attached to the surface of E.coli more than anatase.
