Your search keyword '"Marc A. Demeter"' showing total 6 results

1. Removal and biodegradation of naphthenic acids by biochar and attached environmental biofilms in the presence of co-contaminating metals

Author

David B. Layzell, Raymond J. Turner, Marc A. Demeter, Tazul Islam Bhuiyan, Josephine M. Hill, Mathew L. Frankel, Andrei Veksha, and Robert Helleur

Subjects

Softwood, Environmental Engineering, Co-contamination, 0208 environmental biotechnology, Microbial Consortia, Carboxylic Acids, Industrial Waste, Bioengineering, 02 engineering and technology, 010501 environmental sciences, Bacterial growth, 01 natural sciences, Alberta, Oil sands process water, Biochar, Oil and Gas Fields, Waste Management and Disposal, 0105 earth and related environmental sciences, Renewable Energy, Sustainability and the Environment, Chemistry, Biofilm, General Medicine, Contamination, Biodegradation, Wood, 6. Clean water, 020801 environmental engineering, Biodegradation, Environmental, Microbial population biology, Metals, Environmental chemistry, Biofilms, Charcoal, Oil sands, Naphthenic acids, Water Pollutants, Chemical

Abstract

This study evaluated the efficacy of using a combined biofilm-biochar approach to remove organic (naphthenic acids (NAs)) and inorganic (metals) contaminants from process water (OSPW) generated by Canada’s oil sands mining operations. A microbial community sourced from an OSPW sample was cultured as biofilms on several carbonaceous materials. Two biochar samples, from softwood bark (SB) and Aspen wood (N3), facilitated the most microbial growth (measured by protein assays) and were used for NA removal studies performed with and without biofilms, and in the presence and absence of contaminating metals. Similar NA removal was seen in 6-day sterile N3 and SB assays (>30%), while biodegradation by SB-associated biofilms increased NA removal to 87% in the presence of metals. Metal sorption was also observed, with up to four times more immobilization of Fe, Al, and As on biofilm-associated biochar. These results suggest this combined approach may be a promising treatment for OSPW.

Published

2016

2. Evaluating the Metal Tolerance Capacity of Microbial Communities Isolated from Alberta Oil Sands Process Water

Author

Mathew L. Frankel, Raymond J. Turner, Marc A. Demeter, and Joseph Lemire

Subjects

0301 basic medicine, lcsh:Medicine, Social Sciences, Marine and Aquatic Sciences, Metal toxicity, Toxicology, Pathology and Laboratory Medicine, Biochemistry, chemistry.chemical_compound, Mathematical and Statistical Techniques, Sociology, Consortia, Medicine and Health Sciences, lcsh:Science, Multidisciplinary, Ecology, Cupriavidus, Tailings, Lipids, 6. Clean water, Petroleum, Environmental chemistry, Physical Sciences, Oil sands, Regression Analysis, Biological Cultures, Water Microbiology, Statistics (Mathematics), Research Article, Cell Culturing Techniques, Biofilm Culture, 030106 microbiology, Microbial Consortia, Biology, Linear Regression Analysis, Research and Analysis Methods, Microbiology, 03 medical and health sciences, Metals, Heavy, Statistical Methods, Ponds, Toxicity, Cupriavidus metallidurans, lcsh:R, Extraction (chemistry), Biofilm, Biology and Life Sciences, Bacteriology, Bodies of Water, biology.organism_classification, 030104 developmental biology, chemistry, 13. Climate action, Biofilms, Earth Sciences, lcsh:Q, Bacterial Biofilms, Oils, Mathematics

Abstract

Anthropogenic activities have resulted in the intensified use of water resources. For example, open pit bitumen extraction by Canada's oil sands operations uses an estimated volume of three barrels of water for every barrel of oil produced. The waste tailings-oil sands process water (OSPW)-are stored in holding ponds, and present an environmental concern as they are comprised of residual hydrocarbons and metals. Following the hypothesis that endogenous OSPW microbial communities have an enhanced tolerance to heavy metals, we tested the capacity of planktonic and biofilm populations from OSPW to withstand metal ion challenges, using Cupriavidus metallidurans, a known metal-resistant organism, for comparison. The toxicity of the metals toward biofilm and planktonic bacterial populations was determined by measuring the minimum biofilm inhibitory concentrations (MBICs) and planktonic minimum inhibitory concentrations (MICs) using the MBEC ™ assay. We observed that the OSPW community and C. metallidurans had similar tolerances to 22 different metals. While thiophillic elements (Te, Ag, Cd, Ni) were found to be most toxic, the OSPW consortia demonstrated higher tolerance to metals reported in tailings ponds (Al, Fe, Mo, Pb). Metal toxicity correlated with a number of physicochemical characteristics of the metals. Parameters reflecting metal-ligand affinities showed fewer and weaker correlations for the community compared to C. metallidurans, suggesting that the OSPW consortia may have developed tolerance mechanisms toward metals present in their environment.

Published

2015

3. Culturing oil sands microbes as mixed species communities enhances ex situ model naphthenic acid degradation

Author

Gordon Yue, Raymond J. Turner, Howard Ceri, Joseph Lemire, and Marc A. Demeter

Subjects

Microbiology (medical), oil sands, Oil sands tailings ponds, Microorganism, Population, lcsh:QR1-502, Biology, Microbiology, lcsh:Microbiology, chemistry.chemical_compound, bioreactor, Bioremediation, bioremediation, Naphthenic acid, education, Original Research, education.field_of_study, business.industry, Biofilm, biology.organism_classification, Biotechnology, chemistry, Microbial population biology, Environmental chemistry, Biofilms, Naphthenic acids, business, Rhodococcus

Abstract

Oil sands surface mining for bitumen results in the formation of oil sands process water (OSPW), containing acutely toxic naphthenic acids (NAs). Potential exists for OSPW toxicity to be mitigated by aerobic degradation of the NAs by microorganisms indigenous to the oil sands tailings ponds, the success of which is dependent on the methods used to exploit the metabolisms of the environmental microbial community. Having hypothesized that the xenobiotic tolerant biofilm mode-of-life may represent a feasible way to harness environmental microbes for ex situ treatment of OSPW NAs, we aerobically grew OSPW microbes as single and mixed species biofilm and planktonic cultures under various conditions for the purpose of assaying their ability to tolerate and degrade NAs. The NAs evaluated were a diverse mixture of eight commercially available model compounds. Confocal microscopy confirmed the ability of mixed and single species OSPW cultures to grow as biofilms in the presence of the NAs evaluated. qPCR enumeration demonstrated that the addition of supplemental nutrients at concentrations of 1 g L(-1) resulted in a more numerous population than 0.001 g L(-1) supplementation by approximately 1 order of magnitude. GC-FID analysis revealed that mixed species cultures (regardless of the mode of growth) are the most effective at degrading the NAs tested. All constituent NAs evaluated were degraded below detectable limits with the exception of 1-adamantane carboxylic acid (ACA); subsequent experimentation with ACA as the sole NA also failed to exhibit degradation of this compound. Single species cultures degraded select few NA compounds. The degradation trends highlighted many structure-persistence relationships among the eight NAs tested, demonstrating the effect of side chain configuration and alkyl branching on compound recalcitrance. Of all the isolates, the Rhodococcus spp. degraded the greatest number of NA compounds, although still less than the mixed species cultures. Overall, these observations lend support to the notion that harnessing a community of microorganisms as opposed to targeted isolates can enhance NA degradation ex situ. Moreover, the variable success caused by NA structure related persistence emphasized the difficulties associated with employing bioremediation to treat complex, undefined mixtures of toxicants such as OSPW NAs.

Published

2015

4. Protocols for Harvesting a Microbial Community Directly as a Biofilm for the Remediation of Oil Sands Process Water

Author

Raymond J. Turner, Marc A. Demeter, and Joseph Lemire

Subjects

Waste management, Microbial population biology, Environmental remediation, Process (engineering), Biofilm, Environmental engineering, Environmental science, Oil sands

Published

2015

5. Harnessing oil sands microbial communities for use in ex situ naphthenic acid bioremediation

Author

Iain George, Joseph Lemire, Marc A. Demeter, Howard Ceri, Raymond J. Turner, and Gordon Yue

Subjects

Environmental Engineering, Health, Toxicology and Mutagenesis, Carboxylic Acids, Biology, Waste Disposal, Fluid, Gas Chromatography-Mass Spectrometry, Alberta, chemistry.chemical_compound, Bioremediation, Naphthenic acid, Bioreactor, Environmental Chemistry, Oil and Gas Fields, Waste management, Public Health, Environmental and Occupational Health, Biofilm, General Medicine, General Chemistry, biology.organism_classification, Pollution, Tailings, Hydrocarbons, Hot water extraction, Biodegradation, Environmental, chemistry, Environmental chemistry, Oil sands, Bacteria, Water Pollutants, Chemical

Abstract

The caustic hot water extraction process used to release bitumen from the Alberta oil sands generates large volumes of tailings waste, or oil sands process water (OSPW). OSPW contains several components of environmental concern including diluents, polyaromatic hydrocarbons, heavy metals, and naphthenic acids (NAs); the latter are of particular concern as they are acutely toxic to aquatic organisms and mammals. Studies have demonstrated that the naturally occurring OSPW bacteria are capable of metabolizing the NAs. However, this in situ process takes place over hundreds of years, and is incomplete, leaving a recalcitrant fraction of NAs intact. In this study we explore options for recovering and harnessing the naturally occurring OSPW bacteria for potential future use in an aerobic ex situ OSPW treatment system. Here we evaluate our recovered microbes on their ability to degrade two model NAs, cyclohexane carboxylic acid and cyclohexane acetic acid. Using OSPW as a source for a bacterial inoculum, we were able to compare single and multispecies OSPW cultures, grown as either a biofilm, or as a planktonic suspension. Furthermore, we examined the effect of available nutrients on the ability of these cultures to degrade NAs. All biofilms were grown using the Calgary Biofilm Device. GC–MS, and GC-FID reveal that multispecies biofilm and planktonic cultures are each capable of degrading both NAs; a trait not observed for single species cultures. Moreover, complementary carbon sources have a tangible effect on the ability of the cultures to initiate the degradation of the NAs.

Published

2013

6. Culturing oil sands microbes as mixed species communities enhances ex situ model naphthenic acid degradation

Author

Marc A Demeter, Joe eLemire, Gordon eYue, Howard eCeri, and Raymond J Turner

Subjects

Biofilms, bioremediation, bioreactor, oil sands, Naphthenic acids, Microbiology, QR1-502

Abstract

Oil sands surface mining for bitumen results in the formation of oil sands process water (OSPW), containing acutely toxic naphthenic acids (NAs). Potential exists for OSPW toxicity to be mitigated by aerobic degradation of the NAs by microorganisms indigenous to the oil sands tailings ponds, the success of which is dependent on the methods used to exploit the metabolisms of the environmental microbial community. Having hypothesized that the xenobiotic tolerant biofilm mode-of-life may represent a feasible way to harness environmental microbes for ex situ treatment of OSPW NAs, we aerobically grew OSPW microbes as single and mixed species biofilm and planktonic cultures under various conditions for the purpose of assaying their ability to tolerate and degrade NAs. The NAs evaluated were a diverse mixture of 8 commercially available model compounds. Confocal microscopy confirmed the ability of mixed and single species OSPW cultures to grow as biofilms in the presence of the NAs evaluated. qPCR enumeration demonstrated that the addition of supplemental nutrients at concentrations of 1 g L-1 resulted in a more numerous population than 0.001 g L-1 supplementation by approximately 1 order of magnitude. GC-FID analysis revealed that mixed species cultures (regardless of the mode of growth) are the most effective at degrading the NAs tested. All constituent NAs evaluated were degraded below detectable limits with the exception of 1-Adamantane carboxylic acid (ACA); subsequent experimentation with ACA as the sole NA also failed to exhibit degradation of this compound. Single species cultures degraded select few NA compounds. The degradation trends highlighted many structure-persistence relationships among the 8 NAs tested, demonstrating the effect of side chain configuration and alkyl branching on compound recalcitrance. Of all the isolates, the Rhodococcus spp. degraded the greatest number of NA compounds, although still less than the mixed species cultures. Overall, these observations lend support to the notion that harnessing a community of microorganisms as opposed to targeted isolates can enhance NA degradation ex situ. Moreover, the variable success caused by NA structure related persistence emphasized the difficulties associated with employing bioremediation to treat complex, undefined mixtures of toxicants such as OSPW NAs.

Published

2015