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Olaniran, Ademola O.,Mfumo, Nokukhanya H.,Pillay, Dorsamy,Pillay, Balakrishna The Korean Society for Biotechnology and Bioengine 2006 Biotechnology and Bioprocess Engineering Vol.11 No.3
The widespread use and distribution of chloroethylene organic compounds is of serious concern owing to their carcinogenicity and toxicity to humans and wildlife. In an effort to develop active bacterial consortia that could be useful for bioremediation of chloroethylene-contaminated sites in Africa, 16 combinations of 5 dichloroethylene (DCE)-utilizing bacteria, isolated from South Africa and Nigeria, were assessed for their ability to degrade cis- and trans- DCEs as the sole carbon source. Three combinations of these isolates were able to remove up to 72% of the compounds within 7 days. Specific growth rate constants of the bacterial consortia ranged between 0.465 and $0.716\;d^{-1}$ while the degradation rate constants ranged between 0.184 and $0.205\;d^{-1}$ with $86.36{\sim}93.53\;and\;87.47{\sim}97.12%$ of the stoichiometric-expected chloride released during growth of the bacterial consortia in cis- and trans-DCE, respectively. Succession studies of the individual isolates present in the consortium revealed that the biodegradation process was initially dominated by Achromobacter xylosoxidans and subsequently by Acinetobacter sp. and Bacillus sp., respectively. The results of this study suggest that consortia of bacteria are more efficient than monocultures in the aerobic biodegradation of DCEs, degrading the compounds to levels that are up to 60% below the maximum allowable limits in drinking water.
Ademola O. Olaniran,Nokukhanya H. Mfumo,Dorsamy Pillay,Balakrishna Pillay 한국생물공학회 2006 Biotechnology and Bioprocess Engineering Vol.11 No.3
The widespread use and distribution of chloroethylene organic compounds is of serious concern owing to their carcinogenicity and toxicity to humans and wildlife. In an effort to develop active bacterial consortia that could be useful for bioremediation of chloroethylene-contaminated sites in Africa, 16 combinations of 5 dichloroethylene (DCE)-utilizing bacteria, isolated from South Africa and Nigeria, were assessed for their ability to degrade cis- and trans-DCEs as the sole carbon source. Three combinations of these isolates were able to remove up to 72% of the compounds within 7 days. Specific growth rate constants of the bacterial consortia ranged between 0.465 and 0.716 d-1, while the degradation rate constants ranged between 0.184 and 0.205 d-1, with 86.36~93.53 and 87.47~97.12% of the stoichiometric-expected chloride released during growth of the bacterial consortia in cis- and trans-DCE, respectively. Succession studies of the individual isolates present in the consortium revealed that the biodegradation process was initially dominated by Achromobacter xylosoxidans and subsequently by Acinetobacter sp. and Bacillus sp., respectively. The results of this study suggest that consortia of bacteria are more efficient than monocultures in the aerobic biodegradation of DCEs, degrading the compounds to levels that are up to 60% below the maximum allowable limits in drinking water.
Simphiwe P. Buthelezi,Ademola O. Olaniran,Balakrishna Pillay 한국생물공학회 2010 Biotechnology and Bioprocess Engineering Vol.15 No.5
Bioflocculants produced by six bacteria obtained from activated sludge at a wastewater treatment plant were quantified, purified, and characterized. Effects of pH,temperature, cationic salt content, and specific potential inhibitors on the flocculating activities of the bioflocculants were also determined. Bioflocculants produced by the different bacterial isolates ranged between 6.33 and 27.66g/L in concentration and were composed of both carbohydrate and protein in varying amounts, as well as a relatively high concentration of uronic acid. The flocculating activity of the broth culture increased during the logarithmic phase of bacterial growth with a maximum ranging from 2.395 to 3.709/OD. Optimum pH for the flocculating activity of the bioflocculants was between 8and 9, with generally higher flocculating activity observed at 28oC. Of the cations tested, Mg2+ and Mn2+improved flocculating activity up to 5.2 fold. The stability of these bacterial bioflocculants under various environmental and nutritional conditions suggests their possible use in the industries and environmental applications. Therefore, this study details important implications in providing a safer alternative flocculation method for wastewater treatment.
Olasehinde Tosin A.,Olaniran Ademola O. 한국독성학회 2022 Toxicological Research Vol.38 No.3
In this study, the modulatory effects of anthracene (ANT) and benz[a]anthracene (BEN) on biochemical markers associated with neurodegeneration were assessed in mouse hippocampal neuronal cells (HT-22). Neuronal cells were cultured and exposed to ANT and BEN (25–125 μM) for 5 days, and the cell viability was determined via MTT assay. Morphological characteristics of the cells were assessed using a compound microscope. Biochemical parameters such as acetylcholinesterase (AChE), monoamine oxidase (MAO) and adenosine deaminase (ADA) activities as well as oxidative stress biomarkers (catalase [CAT], glutathione -S- transferase [GST] activities and Glutathione [GSH] levels) and nitric oxide [NO] levels were assessed after cells were treated with ANT and BEN for two days. The results showed that cell viability reduced with an increase in exposure time. After the fifth day of treatment, BEN and ANT (125 μM) reduced percentage viability to 41 and 38.1%, respectively. Light micrographs showed shrinkage of cells, neuronal injury and cell death in cells treated with higher concentrations of BEN and ANT (50 and 125 μM). Furthermore, AChE and MAO activities reduced significantly after treatment for 48 h with ANT and BEN. A significant decrease in CAT and GST activities and low GSH levels were observed after treatment with BEN and ANT. However, both polycyclic aromatic hydrocarbons caused a significant increase in ADA activity and NO levels. These results suggest that ANT and BEN may induce neurodegeneration in neuronal cells via oxidative stress-induced-neuronal injury, disruption of cholinergic, monoaminergic and purinergic transmission, and increased nitric oxide levels.