Bioprocess development for removal of nitrogenous compounds from precious metal refinery wastewater

Manipura, Walappuly Mudiyanselage Janakasiri Aruna Shantha Bandara

January 2008

Removal of nitrogenous compounds from precious metal refinery (PMR) wastewater is important in terms of avoiding eutrophication (environmental protection), metal recovery (increased overall process efficiency and value recovery) and reuse of treated water (maximum use of natural resources). Extreme pH conditions (4 to 13 depending on the wastewater stream), high chemical oxygen demand (> 10,000 mg/I), numerous metals and high concentrations of those metals (> 20 mg/l of platinum group metals) in the wastewater are the main challenges for biological removal of nitrogenous compounds from PMR wastewater. Nitrogenous compounds such as NH₄⁺-N and N0₃-N are strong metal ligands, which make it difficult to recover metals from the wastewater. Therefore, a bioprocess was developed for removal of nitrogenous compounds from carefully simulated PMR wastewater. A preliminary investigation of metal wastewater was carried out to determine its composition and physico-chemical properties, the ability to nitrify and denitrify under different pH conditions and denitrification with different carbon Source compounds and amounts. Even at pH 4, nitrification could be carried out. A suitable hydraulic retention time was found to be 72 hours. There was no significant difference between sodium acetate and sodium lactate as carbon sources for denitrification. Based on these results, a reactor comparison study was carried out using simulated PMR wastewater in three types of reactors: continuously stirred tank reactor (CSTR), packed-bed reactor (PBR) and airlift suspension reactor (ALSR). These reactors were fed with 30 mg/l of Rh bound in an NH₄⁺ based compound (Claus salt: pentaaminechlororhodium (III) dichloride). Total nitrogen removal efficiencies of > 68 % , > 79 % and > 45 % were obtained in the CSTR, PBR and ALSR, respectively. Serially connected CSTR-PBR and PBR-CSTR reactor configurations were then studied to determine the best configuration for maximum removal of nitrogenous compounds from the wastewater. The PBR-CSTR configuration gave consistent biomass retention and automatic pH control in the CSTR. Ammonium removal efficiencies > 95 % were achieved in both reactors. As poor nitrate removal was observed a toxicity study was carried out using respirometry and the half saturation inhibition coefficients for Pt, Pd, Rh and Ru were found to be 15.81, 25.00, 33.34 and 39.25 mg/l, respectively. A mathematical model was developed to describe the nitrogen removal in PMR wastewater using activated sludge model number 1 (ASMl), two step nitrification and metal toxicity. An operational protocol was developed based on the literature review, experimental work and simulation results. The optimum reactor configuration under the set conditions (20 mg/I of Rh and < 100 mg/I of NH₄⁺-N) was found to be PBR-CSTR-PBR process, which achieved overall NH₄⁺-N and N0₃⁻-N removal efficiencies of > 90 % and 95 %, respectively. Finally, a rudimentary microbial characterisation was carried out on subsamples from the CSTR and PBRsecondary. It was found that the CSTR biomass consisted of both rods and cocci while PBRsecondary consisted of rods only. Based on these experimental works, further research needs and recommendations were made for optimisation of the developed bioprocess for removal of nitrogenous compounds from PMR wastewater.

Factory and trade waste

Metals -- Absorption and adsorption

Metals -- Environmental aspects

Water quality management

Water reuse

Metals -- Refining

Microbiology -- Research

Investigation of the potential bacterial proteasome homologue Anbu

Suknaic, Stephen R.

08 September 2014

Indiana University-Purdue University Indianapolis (IUPUI) / Anbu is a bacterial protein with significant homology to the sub-units of the 20S proteasome and is predicted to be a novel bacterial proteasome. The goal of this project was to determine if the recombinant Anbu protein from Pseudomonas aeruginosa is a proteasome. Anbu from P. aeruginosa was successfully cloned, expressed and purified. In order to determine the catalytic activity of Anbu, the purified protein was tested with a variety of substrates and conditions. The targets analyzed included fluorescently-labeled substrates, denatured proteins, diubiquitin, and a peptide library in the hopes of obtaining a useful model substrate. Experiments were also conducted to determine what role Anbu has in the cell. Western analysis was performed on the cell lysate of wild type P. aeruginosa and insertional mutants to detect Anbu expression. The level of biofilm formation was compared between the wild type and mutants. Cultures were grown under stress conditions including the oxidative stress of diamide and the nitrosative stress of S-nitrosoglutathione. Growth rates were monitored in an attempt to detect a phenotypic difference between the wild type and the mutants lacking Anbu, HslV, and the other proteins of interest. While a substrate for Anbu has yet to be found, this protein was found to assemble into a larger structure and P. aeruginosa lacking Anbu was sensitive to the oxidative stress of diamide and the nitrosative stress of S-nitrosoglutathione.

Proteasome

Biochemistry

Microbiology

Pseudomonas aeruginosa -- Research

Pathogenic bacteria

Microbiology -- Research

Recombinant protease inhibitors

Protease inhibitors

Biofilms

Nitric-oxide synthase

Glutathione

Ubiquitin

Oxidative stress

Catalysis

The food safety knowledge and microbial hazards awareness of consumers of ready-to-eat street-vended foods and their exposure to microbiological hazard

Asiegbu, Chioma Vivian

14 October 2016

In many countries, the authorities face extreme difficulties in monitoring and ensuring that food sold on the street is safe, that is, fit for human consumption. This is particularly the case in urban areas, where people buy food on the street because it is readily available and relatively inexpensive. The objective of this study was to determine the food safety knowledge and microbial hazard awareness of street food consumers, and to assess the bacteriological quality of selected ready-to-eat foods sold by street vendors in the Johannesburg municipality. A cross-sectional survey study was conducted and a total of 402 respondents who buy and consume street-vended foods were randomly selected at various street food vending locations. A total of 315 various street-vended samples were purchased from randomly selected street food vendors at different vending locations in Johannesburg metropolis, in order to investigate the bacteriological quality of street-vended foods. Results of the bacteriological analysis revealed that total aerobic counts ranged from 0.3*102 - 0.4*105 cfu/g in cereals and grain-based foods; 0.4*102 - 0.5*105 cfu/g in meat-, dairy- and fish-based foods and 0.7*102 - 0.9*104 cfu/g in fruit- and vegetable-based foods. None of the food samples tested positive for Salmonella spp and Staphylococcus aureus. Results of the survey showed that the majority of respondents were black males younger than 35 years. Individuals of different gender, race, level of education and monthly income groups significantly (p<0.05) differed in their responses regarding the frequency of purchasing and confidence in the safety of street-vended food. Better taste followed closely by affordability and accessibility were the most cited reasons for purchasing street-vended food / Life and Consumer Sciences / M. Sc. (Life Sciences)

Street-vended

Ready-to-eat

Food safety

Knowledge

Hazard

Awareness

Consumer

Johannesburg

Pathogen

Microbial

Foodborne disease

RAPD-PCR

363.1920968221

Monitoring, characterizing, and preventing microbial degradation of ignitable liquids on soil

Turner, Dee Ann

January 2013

Indiana University-Purdue University Indianapolis (IUPUI) / Organic-rich substrates such as soil provide an excellent carbon source for bacteria. However, hydrocarbons such as those found in various ignitable liquids can also serve as a source of carbon to support bacterial growth. This is problematic for fire debris analysis as samples may be stored at room temperature for extended periods before they are analyzed due to case backlog. As a result, selective loss of key components due to bacterial metabolism can make identifying and classifying ignitable liquid residues by their chemical composition and boiling point range very difficult. The ultimate goal of this project is to preserve ignitable liquid residues against microbial degradation as efficiently and quickly as possible. Field and laboratory studies were conducted to monitor microbial degradation of gasoline and other ignitable liquids in soil samples. In addition to monitoring degradation in potting soil, as a worst case scenario, the effect of soil type and season were also studied. The effect of microbial action was also compared to the effect of weathering by evaporation (under nitrogen in the laboratory and by the passive headspace analysis of the glass fragments from the incendiary devices in the field studies). All studies showed that microbial degradation resulted in the significant loss of n-alkanes and lesser substituted alkylbenzenes predominantly and quickly, while more highly substituted alkanes and aromatics were not significantly affected. Additionally, the residential soil during the fall season showed the most significant loss of these compounds over the course of 30 days. To combat this problem, a chemical solution is to be immediately applied to the samples as they are collected. Various household and commercial products were tested for their efficacy at low concentrations to eliminate all living bacteria in the soil. Triclosan (2% (w/v) in NaOH) proved to be the most effective at preserving ignitable liquid residues for at least 30 days.

microbial degradation

ignitable liquids

preservation

triclosan

fire debris

chemometrics

Organic compounds -- Biodegradation

Hydrocarbons -- Research

Soil disinfection

Microbial metabolism

Chemometrics

Bacteriology, Agricultural

Anti-infective agents

Extraction (Chemistry) -- Research

Evaporation -- Physiological effect

Chemistry, Forensic -- Research