6 results on '"Judith Webber"'
Search Results
2. Use of Sonication for Enhanced Sampling of Attached Microbes from Groundwater Systems
- Author
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Judith Webber, Travis Grace, Louise Weaver, Pierre-Yves Dupont, Kimberly Thien Huynh, Graham D. Fenwick, Eliza Cowey, Simon Howard, Phil Abraham, Bronwyn Humphries, and Murray E. Close
- Subjects
geography ,geography.geographical_feature_category ,Water Wells ,Microorganism ,Sonication ,0208 environmental biotechnology ,Sampling (statistics) ,Sediment ,02 engineering and technology ,Pulp and paper industry ,Bacterial counts ,020801 environmental engineering ,Data sequences ,Environmental science ,Computers in Earth Sciences ,Groundwater ,New Zealand ,Water Science and Technology ,Water well - Abstract
The vast majority of microorganisms in aquifers live as biofilms on sediment surfaces, which presents significant challenges for sampling as only the suspended microbes will be sampled through normal pumping. The use of a down-well low frequency sonicator has been suggested as a method of detaching microbes from the biofilm and allowing rapid sampling of this community. We developed a portable, easy to use, low-frequency electric sonicator and evaluated its performance for a range of well depths (tested up to 42 m below ground level) and casing types. Three sonicators were characterized in laboratory experiments using a 1 m long tank filled with pea gravel. These included a commercially available pneumatic sonicator, a rotating flexible shaft sonicator, and the prototype electric sonicator. The electric sonicator detached between 56 and 74% of microbes grown on gravel-containing biobags at distances ranging between 2 and 50 cm from the sonicator. The field testing comprises of a total of 55 sampling events from 48 wells located in 4 regions throughout New Zealand. Pre- and post-sonication samples showed an average 33 times increase in bacterial counts. Microbial sequence data showed that the same classes are present in pre- and post-sonicated samples and only slight differences were seen in the proportions present. The sampling process was rapid and the significant increases in bacterial counts mean that microbial samples can be quickly obtained from wells, which permits more detailed analysis than previously possible.
- Published
- 2020
3. Laboratory-scale waste stabilisation pond development
- Author
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Bronwyn Humphries, Louise Weaver, Judith Webber, Matthew Ashworth, and Amanda R Inglis
- Subjects
Scale (chemistry) ,0208 environmental biotechnology ,Indicator bacteria ,02 engineering and technology ,General Medicine ,010501 environmental sciences ,Laboratory scale ,Pulp and paper industry ,01 natural sciences ,020801 environmental engineering ,Wastewater ,Microbial population biology ,Environmental Chemistry ,Environmental science ,Sewage treatment ,Waste Management and Disposal ,Scale model ,Effluent ,0105 earth and related environmental sciences ,Water Science and Technology - Abstract
The present study describes the development of a laboratory-scale waste stabilisation pond (WSP) system, undertaken in order to investigate the effects of hydraulic, physicochemical, microbial and physical parameters on wastewater treatment. Previous studies have focused predominantly on hydraulic characteristics. This system was engineered at a scale much smaller than had previously been seen in the literature. The scale of the model used here allows for improved optimisation at a shorter time scale that would be seen for larger pilot-scale systems. Additionally, with the addition of viruses, a smaller scale model allows for more control over viral concentration used. Once constructed, the system was dosed with wastewater from a wastewater treatment plant and both the influent and effluent were monitored using common testing methods as well as direct viral analysis. Successful wastewater treatment was seen in terms of reduction of indicator bacteria and virus, as determined by culture-based methods. This treatment and the associated stabilisation of physicochemical parameters such as dissolved oxygen and pH, indicates the successful development of a microbial community within the laboratory-scale WSP.
- Published
- 2021
4. Comparison of faecal indicator and viral pathogen light and dark disinfection mechanisms in wastewater treatment pond mesocosms
- Author
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Louise Weaver, Wendy M. Williamson, Rupert J. Craggs, Jason B.K. Park, Margaret Mackenzie, Robert J. Davies-Colley, Rebecca Stott, Susan Lin, Erin McGill, and Judith Webber
- Subjects
Environmental Engineering ,Ultraviolet Rays ,viruses ,0208 environmental biotechnology ,02 engineering and technology ,010501 environmental sciences ,Management, Monitoring, Policy and Law ,01 natural sciences ,Water Purification ,Mesocosm ,Bacteriophage ,Algae ,Escherichia coli ,Humans ,Ponds ,Waste Management and Disposal ,Pathogen ,0105 earth and related environmental sciences ,Sunlight ,Indicator organism ,biology ,Chemistry ,General Medicine ,biology.organism_classification ,020801 environmental engineering ,Disinfection ,Environmental chemistry ,Sewage treatment ,sense organs ,Water Microbiology ,Bacteria - Abstract
This study compared light and dark disinfection of faecal bacteria/viral indicator organisms (E. coli and MS2 (fRNA) bacteriophage) and human viruses (Echovirus and Norovirus) in Wastewater Treatment Pond (WTP) mesocosms. Stirred pond mesocosms were operated in either outdoor sunlight-exposed or laboratory dark conditions in two experiments during the austral summer. To investigate wavelength-dependence of sunlight disinfection, three optical filters were used: (1) polyethylene film (light control: transmitting all solar UV and visible wavelengths), (2) acrylic (removing most UVB 5-log E. coli and MS2 phage removal (from ~1.0 × 106 to
- Published
- 2021
5. Microbial pathogen removal from domestic effluent using coral sand in Kiribati
- Author
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Bronwyn Humphries, Lee Burbery, Louise Weaver, Judith Webber, Jan Gregor, and Leanne K. Morgan
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Veterinary medicine ,viruses ,media_common.quotation_subject ,Coral ,Sewage ,Septic tank ,medicine.disease_cause ,Applied Microbiology and Biotechnology ,Waste Disposal, Fluid ,Water Purification ,03 medical and health sciences ,Sand ,medicine ,Animals ,Water Pollutants ,Effluent ,030304 developmental biology ,media_common ,0303 health sciences ,biology ,Bacteria ,030306 microbiology ,business.industry ,Chemistry ,General Medicine ,biology.organism_classification ,Anthozoa ,Viruses ,Norovirus ,Sewage treatment ,Coral sand ,Adsorption ,business ,Biotechnology ,Micronesia - Abstract
AIM Infiltration experiments aimed to show the effectivity of coral sand to remove micro-organisms in septic tank wastewater treatment system, in South Tarawa, Kiribati. METHODS AND RESULTS Laboratory experiments evaluated effective microbial removal properties of a packed bed of coral beach sand conditioned with domestic effluent. Bacterial and viral indicators Escherichia coli J6-2, Enterococci faecalis and f-RNA (MS2) bacteriophage, along with viral pathogens adenovirus, echovirus, norovirus and rotavirus, were dosed (at 106 -107 CFU, PFU or genome copies per ml concentration) with effluent to unsaturated coral sand-packed columns. For the conditions simulated, all organisms showed removal efficiencies of >4-Log Removal Values (LRVs) (i.e. >99·99% effective reduction in number). Results revealed that the conditioned coral sand had a higher affinity for attenuating viruses than the bacteria tested. MS2 phage, adenovirus, echovirus, norovirus and rotavirus were absent in leachate from the base of the sand columns. E. coli J6-2 and E. faecalis were recovered at 100 -101 CFU (colony forming units) per ml in the column effluent, following a dosage of 106 CFU per ml. Destructive sampling of the columns after experiments revealed that a high proportion of viral pathogens were retained in the top 30 mm of the sand. CONCLUSIONS On the basis of the relative spatial distribution of trace organisms in the sand, we speculate that adsorption processes likely dominated attenuation of the viral pathogens, more so than physical straining effects. Further study is required to fully elucidate the removal mechanisms. SIGNIFICANCE AND IMPACT OF THE STUDY To the best of our knowledge this is the first study of the effective microbial removal capacity of coral sand under unsaturated conditions. The work represents an initial exploratory step of developing some standardized design practice of on-site wastewater treatment systems in Kiribati, to offer enhanced protection of groundwater resources and reduce diarrhoeal disease.
- Published
- 2019
6. Biofilm resilience to desiccation in groundwater aquifers: A laboratory and field study
- Author
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Louise Weaver, P.M. Abraham, Murray E. Close, A.C. Hickson, and Judith Webber
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Hydrology ,geography ,Environmental Engineering ,geography.geographical_feature_category ,Environmental engineering ,Biofilm ,Aquifer ,Contamination ,Pollution ,Fight-or-flight response ,Groundwater abstraction ,Water Supply ,Biofilms ,Environmental Chemistry ,Environmental science ,Groundwater resources ,Desiccation ,Laboratories ,Groundwater ,Waste Management and Disposal ,Environmental Monitoring - Abstract
Groundwater is used as a precious resource for drinking water worldwide. Increasing anthropogenic activity is putting increasing pressure on groundwater resources. One impact of increased groundwater abstraction coupled with increasing dry weather events is the lowering of groundwater levels within aquifers. Biofilms within groundwater aquifers offer protection to the groundwater by removing contaminants entering the aquifer systems from land use activities. The study presented investigated the impact of desiccation events on the biofilms present in groundwater aquifers using field and laboratory experiments. In both field and laboratory experiments a reduction in enzyme activity (glucosidase, esterase and phosphatase) was seen during desiccation compared to wet controls. However, comparing all the data together no significant differences were seen between either wet or desiccated samples or between the start and end of the experiments. In both field and laboratory experiments enzyme activity recovered to start levels after return to wet conditions. The study shows that biofilms within groundwater systems are resilient and can withstand periods of desiccation (4 months).
- Published
- 2015
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