Your search keyword '"Francis Hassard"' showing total 47 results

1. Impact of carbon sources in airport de-icing compounds on the growth of Sphaerotilus natans

Author

Benjamin Exton, Francis Hassard, Angel Medina-Vaya, and Robert C. Grabowski

Subjects

undesirable river biofilm, airport de-icer, Sphaerotilus natans, microcosm, growth kinetics, sewage fungus, Microbiology, QR1-502

Abstract

Airport de-icing has been linked with the growth of undesirable river biofilms (URBs, formerly “sewage fungus”), a manifestation of organic pollution causing long-term ecological damage to watercourses. URBs are a polymicrobial community, with one key taxon standing out in literature: Sphaerotilus natans, a filamentous bacterium also found in sewage treatment and activated sludges. An industry often implicated in causing URBs is airport de-icing, with large biofilms often developing downstream of airport discharges in winter months. However, it is not yet clear which de-icers may cause URBs and how they influence growth. Therefore, specific objectives were to (i) determine which freeze-point depressants (FPDs) can be utilized by S. natans; (ii) examine differences in the growth kinetics between FPDs; and (iii) compare pure-FPDs to commercial airport de-icers (CADs) as carbon sources, to determine impacts of additives. This study employed a turbidimetric micro-batch culture design to conduct microbial growth experiments, using S. natans and a minimal medium supplemented with airport de-icer as the carbon source. Equimolar carbon concentrations were used to compare the effects of common FPDs and CADs – each containing a specific FPD. Growth was assessed via optical density (OD600) measurements, from which time-to-detection, maximum rate of change, and maximum optical density were derived and kinetics inferred. S. natans was found to grow effectively on all FPDs tested, although the microbial yield was heavily dependent on the carbon concentration for all FPDs and CADs. Sodium acetate generated the quickest growth, with the lowest TTD (lag-time) for all but the lowest concentrations tested. Propylene glycol produced the greatest maxOD (total growth), whereas ethylene glycol had a higher limiting concentration for maxROC (growth rate). The mixture of compounds and additives in commercial products did not significantly impact the growth of S. natans. This research provides evidence from controlled laboratory experiments that airport de-icers support the growth of S. natans. The differences in growth kinetics observed for the FPDs and CADs could inform improved mitigation or treatment to reduce the incidence and ecological impacts of URBs.

Published

2024

2. Comparison of gene targets and sampling regimes for SARS-CoV-2 quantification for wastewater epidemiology in UK prisons

Author

Kelly Jobling, Marcos Quintela-Baluja, Francis Hassard, Panagiota Adamou, Adrian Blackburn, Term Research Team, Shannon McIntyre-Nolan, Oscar O'Mara, Jesus L. Romalde, Mariachiara Di Cesare, and David W. Graham

Subjects

covid-19, health monitoring, prisons, rt-qpcr, sars-cov-2, wastewater-based epidemiology, Public aspects of medicine, RA1-1270

Abstract

Prisons are high-risk settings for infectious disease transmission, due to their enclosed and semi-enclosed environments. The proximity between prisoners and staff, and the diversity of prisons reduces the effectiveness of non-pharmaceutical interventions, such as social distancing. Therefore, alternative health monitoring methods, such as wastewater-based epidemiology (WBE), are needed to track pathogens, including SARS-CoV-2. This pilot study assessed WBE to quantify SARS-CoV-2 prevalence in prison wastewater to determine its utility within a health protection system for residents. The study analysed 266 samples from six prisons in England over a 12-week period for nucleoprotein 1 (N1 gene) and envelope protein (E gene) using quantitative reverse transcriptase-polymerase chain reaction. Both gene assays successfully detected SARS-CoV-2 fragments in wastewater samples, with both genes significantly correlating with COVID-19 case numbers across the prisons (p < 0.01). However, in 25% of the SARS-positive samples, only one gene target was detected, suggesting that both genes be used to reduce false-negative results. No significant differences were observed between 14- and 2-h composite samples, although 2-h samples showed greater signal variance. Population normalisation did not improve correlations between the N1 and E genes and COVID-19 case data. Overall, WBE shows considerable promise for health protection in prison settings. HIGHLIGHTS Wastewater epidemiology is effective in flagging COVID-19 cases in prison settings.; SARS-CoV-2 levels were quantified using N1 and E gene targets.; Both targets should be used in routine analysis to reduce false negatives.; COVID-19 case numbers significantly correlated with both wastewater gene targets across all samples.; Each prison is different – local activities are important when designing sampling programmes.;

Published

2024

3. Undesirable river biofilms: The composition, environmental drivers, and occurrence of sewage fungus

Author

Ben Exton, Francis Hassard, Angel Medina-Vaya, and Robert C. Grabowski

Subjects

Sphaerotilus natans, Periphyton, Organic pollution, Water quality, Ecological impacts, Bioindicator, Ecology, QH540-549.5

Abstract

Sewage fungus is a classic bioindicator of organic pollution in streams and rivers. However, it has received limited scientific interest in recent decades, despite persistent occurrence in lotic ecosystems. The aim of this review is to provide an up-to-date assessment of sewage fungus, its composition and structure, and the environmental factors that influence its growth to support future research and mitigation interventions. We advocate for the term “undesirable river biofilm” (URB) to more accurately characterise the composition, location, and environmental consequences of sewage fungus. These filamentous or gelatinous growths found on the banks and beds of flowing watercourses are composed predominantly of bacteria, not fungi. Based on modern genomic analyses, we now know that URBs are composed of a diversity of microbial taxa, including those that have long been associated with sewage fungus (e.g. Sphaerotilus, Beggiatoa, and Zoogloea) and newer associated taxa (e.g. Rhodoferax and Thiothrix). While organic pollution is generally considered the main trigger, this review highlights the importance of other environmental factors, such as water velocity, river substrate, pollutant composition and loading, and shading, in the occurrence and persistence of URBs. To illustrate the widespread and continued presence of URBs in rivers, environmental surveillance data for England's rivers were analysed. Between 2000 and 2020, environment officers documented 6,025 occurrences of URBs as part of a wider water quality incident reporting programme. Thus, URBs persist even in countries with stringent water quality standards and comprehensive wastewater infrastructure, suggesting they may continue to be a significant issue globally, despite limited public or scientific focus. We argue that in addition to tackling point discharge of organic pollutants, greater emphasis should be placed on understanding the impact of intermittent and diffuse pollution and altered environmental conditions on river ecosystems. To safeguard river ecosystems, a holistic approach is needed that considers pollution in combination with wider river functioning (e.g. river hydrology, geomorphology, biogeochemical processing, and riparian zones) and climate change. Future areas for study into the URB phenomenon are suggested, including more comprehensive monitoring of URBs specifically and river biofilm health generally.

Published

2024

4. Biodegradation of (Aminomethyl)phosphonic acid (AMPA) by isolated microbial consortia extracted from biological filters at drinking water treatment plants

Author

Laura Pickering, Miles Folkes, Barrie Holden, Peter Jarvis, Pablo Campo, and Francis Hassard

Subjects

Aminomethylphosphonic acid (AMPA), Micropollutant removal, Pesticide, Selective Isolation, Enrichment, Drinking Water Treatment, Biotechnology, TP248.13-248.65

Abstract

The widespread use of glyphosate has significantly increased its presence in drinking water sources. Aminomethylphosphonic Acid (AMPA), a breakdown product of glyphosate, is challenging to remove from water using conventional treatment methods, posing risks to public health and environmental safety. This work investigates the biodegradation of AMPA by bacteria isolated from three environmental sources, with a focus on determining their potential application in water treatment systems. Two samples were collected from granular activated carbon (GAC) filters of different operational durations at a water treatment facility, and one sample was taken from soil that had historically been treated with glyphosate-based herbicides. Bacterial isolates capable of degrading AMPA were identified from these samples through selective enrichment, and kinetic degradation experiments were then conducted to assess their effectiveness. In environmental samples, after 48 hrs AMPA removal was > 70 % using GAC from an active treatment plant and soil samples removed 19 %. After bacterial isolation a consortium was isolated and from these four isolates were identified, comprising three species, including novel AMPA degraders M−S3 and M−SS (Myroides sp. mNGS23), and P-S92 (Pseudochrobactrum saccharolyticum). Within both minimal media supplemented with AMPA and raw untreated showing substrate concentrations above 10 mg/L whilst the specific degradation rates saw a decrease in substrate concentrations above 100 mg/L. AMPA removal occured in pilot scale sand filters augmented with P-S92 but removal was inconsistent. These findings show the potential of using biodegradation as an effective treatment strategy for AMPA removal from water. The identification of AMPA-degrading bacteria offers a promising solution for enhancing the removal of this persistent pollutant from contaminated waters. Further research is recommended to explore the full-scale application of these isolates in water treatment processes. This study contributes to the development of sustainable water treatment technologies by harnessing the natural degradative capacities of environmental bacteria.

Published

2024

5. Polybacterial shift in benthic river biofilms attributed to organic pollution – a prospect of a new biosentinel?

Author

Benjamin Exton, Francis Hassard, Angel Medina Vaya, and Robert C. Grabowski

Subjects

16s rrna amplicon analysis, bioindicator, rhodoferax, sewage fungus, sphaerotilus, water quality, River, lake, and water-supply engineering (General), TC401-506, Physical geography, GB3-5030

Abstract

Organic pollution continues to contaminate river water and degrade aquatic ecosystems worldwide. In heavily modified river systems with high organic loading, sewage fungus, a heterotrophic biofilm, can form on the riverbed. The aim of this study was to determine how the polybacterial community of riverbed biofilms changes prior to and during a sewage fungus outbreak to inform the development of novel biomonitoring approaches. Riverbed biofilm samples were collected from a site that experienced sewage fungus outbreaks previously and an upstream control, following a BACI design. The polybacterial community was characterized using targeted amplicon sequencing (16s rRNA). The results indicate that the community became dominated by two genera prior to and during the sewage fungus outbreak, Rhodoferax and Sphaerotilus, which accounted for 32.8 and 14.2% of the relative abundance. When aggregated at a higher taxonomic level, the genetic data show that the community was comprised largely of bacteria from a single family, Comamonadaceae, totalling 64.1% of the relative abundance. Statistically significant differences in the polybacterial community over time and between impact and control sites provide initial evidence that genetic-based fingerprinting could be a promising biosentinel approach to identify organic pollution inputs and monitor their ecological impact. HIGHLIGHTS Riverbed biofilm community was monitored using 16s rDNA in a BACI design.; Visible sewage fungus outbreak dominated by genera Rhodoferax and Sphaerotilus.; A single family, Comamonadaceae, accounted for 64.1% of the relative abundance during the outbreak.; Significant changes in community occurred before the sewage fungus appeared.; Potential for riverbed biofilm to act as biosentinels for organic river pollution;

Published

2023

6. Can wastewater monitoring protect public health in schools?

Author

Francis Hassard, Suniti Singh, Frédéric Coulon, and Zhugen Yang

Subjects

Public aspects of medicine, RA1-1270

Published

2023

7. Wastewater monitoring for detection of public health markers during the COVID-19 pandemic: Near-source monitoring of schools in England over an academic year.

Author

Francis Hassard, Milan Vu, Shadi Rahimzadeh, Victor Castro-Gutierrez, Isobel Stanton, Beata Burczynska, Dirk Wildeboer, Gianluca Baio, Mathew R Brown, Hemda Garelick, Jan Hofman, Barbara Kasprzyk-Hordern, Azeem Majeed, Sally Priest, Hubert Denise, Mohammad Khalifa, Irene Bassano, Matthew J Wade, Jasmine Grimsley, Lian Lundy, Andrew C Singer, and Mariachiara Di Cesare

Subjects

Medicine, Science

Abstract

BackgroundSchools are high-risk settings for infectious disease transmission. Wastewater monitoring for infectious diseases has been used to identify and mitigate outbreaks in many near-source settings during the COVID-19 pandemic, including universities and hospitals but less is known about the technology when applied for school health protection. This study aimed to implement a wastewater surveillance system to detect SARS-CoV-2 and other public health markers from wastewater in schools in England.MethodsA total of 855 wastewater samples were collected from 16 schools (10 primary, 5 secondary and 1 post-16 and further education) over 10 months of school term time. Wastewater was analysed for SARS-CoV-2 genomic copies of N1 and E genes by RT-qPCR. A subset of wastewater samples was sent for genomic sequencing, enabling determination of the presence of SARS-CoV-2 and emergence of variant(s) contributing to COVID-19 infections within schools. In total, >280 microbial pathogens and >1200 AMR genes were screened using RT-qPCR and metagenomics to consider the utility of these additional targets to further inform on health threats within the schools.ResultsWe report on wastewater-based surveillance for COVID-19 within English primary, secondary and further education schools over a full academic year (October 2020 to July 2021). The highest positivity rate (80.4%) was observed in the week commencing 30th November 2020 during the emergence of the Alpha variant, indicating most schools contained people who were shedding the virus. There was high SARS-CoV-2 amplicon concentration (up to 9.2x106 GC/L) detected over the summer term (8th June - 6th July 2021) during Delta variant prevalence. The summer increase of SARS-CoV-2 in school wastewater was reflected in age-specific clinical COVID-19 cases. Alpha variant and Delta variant were identified in the wastewater by sequencing of samples collected from December to March and June to July, respectively. Lead/lag analysis between SARS-CoV-2 concentrations in school and WWTP data sets show a maximum correlation between the two-time series when school data are lagged by two weeks. Furthermore, wastewater sample enrichment coupled with metagenomic sequencing and rapid informatics enabled the detection of other clinically relevant viral and bacterial pathogens and AMR.ConclusionsPassive wastewater monitoring surveillance in schools can identify cases of COVID-19. Samples can be sequenced to monitor for emerging and current variants of concern at the resolution of school catchments. Wastewater based monitoring for SARS-CoV-2 is a useful tool for SARS-CoV-2 passive surveillance and could be applied for case identification and containment, and mitigation in schools and other congregate settings with high risks of transmission. Wastewater monitoring enables public health authorities to develop targeted prevention and education programmes for hygiene measures within undertested communities across a broad range of use cases.

Published

2023

8. Detection and characterization of bioaerosol emissions from wastewater treatment plants: Challenges and opportunities

Author

Jianghan Tian, Cheng Yan, Sonia Garcia Alcega, Francis Hassard, Sean Tyrrel, Frederic Coulon, and Zaheer Ahmad Nasir

Subjects

bioaerosol, wastewater treatment plant, real time detection, emission characteristics, in situ measurement, Microbiology, QR1-502

Abstract

Rapid population growth and urbanization process have led to increasing demand for wastewater treatment capacity resulting in a non-negligible increase of wastewater treatment plants (WWTPs) in several cities around the world. Bioaerosol emissions from WWTPs may pose adverse health risks to the sewage workers and nearby residents, which raises increasing public health concerns. However, there are still significant knowledge gaps on the interplay between process-based bioaerosol characteristics and exposures and the quantification of health risk which limit our ability to design effective risk assessment and management strategies. This review provides a critical overview of the existing knowledge of bioaerosol emissions from WWTPs including their nature, magnitude and size distribution, and highlights the shortcoming associated with existing sampling and analysis methods. The recent advancements made for rapid detection of bioaerosols are then discussed, especially the emerging real time detection methods to highlight the directions for future research needs to advance the knowledge on bioaerosol emissions from WWTPs.

Published

2022

9. First insights into the prokaryotic community structure of Lake Cote, Costa Rica: Influence on nutrient cycling

Author

Laura Brenes-Guillén, Daniela Vidaurre-Barahona, Lidia Avilés-Vargas, Victor Castro-Gutierrez, Eddy Gómez-Ramírez, Kaylen González-Sánchez, Marielos Mora-López, Gerardo Umaña-Villalobos, Lorena Uribe-Lorío, and Francis Hassard

Subjects

volcanic lake, stratification, hypolimnion, epilimnion, oligotrophic, nutrient cycling, Microbiology, QR1-502

Abstract

Prokaryotic diversity in lakes has been studied for many years mainly focusing on community structure and how the bacterial assemblages are driven by physicochemical conditions such as temperature, oxygen, and nutrients. However, little is known about how the composition and function of the prokaryotic community changes upon lake stratification. To elucidate this, we studied Lake Cote in Costa Rica determining prokaryotic diversity and community structure in conjunction with physicochemistry along vertical gradients during stratification and mixing periods. Of the parameters measured, ammonium, oxygen, and temperature, in that order, were the main determinants driving the variability in the prokaryotic community structure of the lake. Distinct stratification of Lake Cote occurred (March 2018) and the community diversity was compared to a period of complete mixing (March 2019). The microbial community analysis indicated that stratification significantly altered the bacterial composition in the epi-meta- and hypolimnion. During stratification, the Deltaproteobacteria, Chloroflexi, Bacteroidetes, Nitrospirae, and Euryarchaeota were dominant in the hypolimnion yet largely absent in surface layers. Among these taxa, strict or facultative anaerobic bacteria were likely contributing to the lake nitrogen biogeochemical cycling, consistent with measurements of inorganic nitrogen measurements and microbial functional abundance predictions. In general, during both sampling events, a higher abundance of Alphaproteobacteria, Betaproteobacteria, Actinobacteria, and Cyanobacteria was found in the oxygenated layers. Lake Cote had a unique bacterial diversity, with 80% of Amplicon Sequence Variant (ASV) recovered similar to unclassified/uncultured strains and exhibits archetypal shallow lake physicochemical but not microbial fluctuations worthy of further investigation. This study provides an example of lake hydrodynamics impacts to microbial community and their function in Central American lakes with implications for other shallow, upland, and oligotrophic lake systems.

Published

2022

10. Coliphages as viral indicators of sanitary significance for drinking water

Author

Suniti Singh, Robert Pitchers, and Francis Hassard

Subjects

coliphage, somatic coliphage, drinking water quality, online monitoring, drinking water treatment, F+ coliphage, Microbiology, QR1-502

Abstract

Coliphages are virus that infect coliform bacteria and are used in aquatic systems for risk assessment for human enteric viruses. This mini-review appraises the types and sources of coliphage and their fate and behavior in source waters and engineered drinking water treatment systems. Somatic (cell wall infection) and F+ (male specific) coliphages are abundant in drinking water sources and are used as indicators of fecal contamination. Coliphage abundances do not consistently correlate to human enteric virus abundance, but they suitably reflect the risks of exposure to human enteric viruses. Coliphages have highly variable surface characteristics with respect to morphology, size, charge, isoelectric point, and hydrophobicity which together interact to govern partitioning and removal characteristics during water treatment. The groups somatic and F+ coliphages are valuable for investigating the virus elimination during water treatment steps and as indicators for viral water quality assessment. Strain level analyses (e.g., Qβ or GA-like) provide more information about specific sources of viral pollution but are impractical for routine monitoring. Consistent links between rapid online monitoring tools (e.g., turbidity, particle counters, and flow cytometry) and phages in drinking water have yet to be established but are recommended as a future area of research activity. This could enable the real-time monitoring of virus and improve the process understanding during transient operational events. Exciting future prospects for the use of coliphages in aquatic microbiology are also discussed based on current scientific evidence and practical needs.

Published

2022

11. Monitoring occurrence of SARS-CoV-2 in school populations: A wastewater-based approach.

Author

Victor Castro-Gutierrez, Francis Hassard, Milan Vu, Rodrigo Leitao, Beata Burczynska, Dirk Wildeboer, Isobel Stanton, Shadi Rahimzadeh, Gianluca Baio, Hemda Garelick, Jan Hofman, Barbara Kasprzyk-Hordern, Rachel Kwiatkowska, Azeem Majeed, Sally Priest, Jasmine Grimsley, Lian Lundy, Andrew C Singer, and Mariachiara Di Cesare

Subjects

Medicine, Science

Abstract

Clinical testing of children in schools is challenging, with economic implications limiting its frequent use as a monitoring tool of the risks assumed by children and staff during the COVID-19 pandemic. Here, a wastewater-based epidemiology approach has been used to monitor 16 schools (10 primary, 5 secondary and 1 post-16 and further education) in England. A total of 296 samples over 9 weeks have been analysed for N1 and E genes using qPCR methods. Of the samples returned, 47.3% were positive for one or both genes with a detection frequency in line with the respective local community. WBE offers a low cost, non-invasive approach for supplementing clinical testing and can provide longitudinal insights that are impractical with traditional clinical testing.

Published

2022

12. Multifunctional Heterogeneous Ion-Exchange Membranes for Ion and Microbe Removal in Low-Salinity Water

Author

Fulufhelo Hope Mudau, Francis Hassard, Machawe Mxolisi Motsa, and Lueta-Ann De Kock

Subjects

heterogenous ion exchange membranes, ultrafiltration, silver nanoparticles, copper nanoparticles, intermatix synthesis, surface water treatment, Organic chemistry, QD241-441

Abstract

Here, multifunctional heterogeneous ion-exchange metal nanocomposite membranes were prepared for surface water desalination and bacterial inactivation under low-pressure (0.05 MPa) filtration conditions. Ultrafiltration (UF) heterogeneous ion exchange membranes (IEMs) were modified with different concentrations of AgNO3 and CuSO4 solutions using the intermatrix synthesis (IMS) technique to produce metal nanocomposite membranes. Scanning electron microscopy (SEM) images revealed that the metal nanoparticles (MNPs) (Ag and Cu) were uniformly distributed on the surface and the interior of the nanocomposite membranes. With increasing metal precursor solution concentration (0.01 to 0.05 mol·L−1), the metal content of Ag and Cu nanocomposite membranes increased from 0.020 to 0.084 mg·cm−2 and from 0.031 to 0.218 m·cm−2 respectively. Results showed that the hydrodynamic diameter diameters of Ag and Cu nanoparticles (NPs) increased from 62.42 to 121.10 nm and from 54.2 to 125.7 nm respectively, as the metal precursor concentration loaded increased. The leaching of metals from metal nanocomposite membranes was measured in a dead-end filtration system, and the highest leaching concentration levels were 8.72 ppb and 5.32 ppb for Ag and Cu, respectively. The salt rejection studies indicated that ionic selectivity was improved with increasing metal content. Bacterial filtration showed higher antibacterial activity for metal nanocomposite membranes, reaching 3.6 log bacterial inactivation.

Published

2023

13. Resin-Loaded Heterogeneous Polyether Sulfone Ion Exchange Membranes for Saline Groundwater Treatment

Author

Fulufhelo Mudau, Machawe Motsa, Francis Hassard, and Lueta-Ann de Kock

Subjects

heterogeneous ion exchange membranes, ultrafiltration, ion exchange resin loading, ion exchange capacity, groundwater treatment, salt rejections, Chemical technology, TP1-1185, Chemical engineering, TP155-156

Abstract

Arid areas often contain brackish groundwater that has a salinity exceeding 500 mg/L. This poses several challenges to the users of the water such as a salty taste and damage to household appliances. Desalination can be one of the key solutions to significantly lower the salinity and solute content of the water. However, the technology requires high energy inputs as well as managing waste products. This paper presents the fabrication of ultrafiltration heterogeneous ion exchange membranes for brackish groundwater treatment. Scanning electron microscopy (SEM) images showed a relatively uniform resin particle distribution within the polymer matrix. The mean roughness of the cation exchange membrane (CEM) and anion exchange membrane (AEM) surfaces increased from 42.12 to 317.25 and 68.56 to 295.95 nm, respectively, when resin loading was increased from 1 to 3.5 wt %. Contact angle measures suggested a more hydrophilic surface (86.13 to 76.26° and 88.10 to 74.47° for CEM and AEM, respectively) was achieved with greater resin loading rates. The ion exchange capacity (IEC) of the prepared membranes was assessed using synthetic groundwater in a dead-end filtration system and removal efficiency of K+, Mg2+, and Ca2+ were 56.0, 93.5, and 85.4%, respectively, for CEM with the highest resin loading. Additionally, the anion, NO3− and SO42− removal efficiency was 84.2% and 52.4%, respectively, for the AEM with the highest resin loading. This work demonstrates that the prepared ultrafiltration heterogeneous ion exchange membranes have potential for selective removal for of ions by ion exchange, under filtration conditions at low pressure of 0.05 MPa.

Published

2022

14. Risk factors and transmission pathways associated with infant Campylobacter spp. prevalence and malnutrition: A formative study in rural Ethiopia.

Author

Sophie Budge, Megan Barnett, Paul Hutchings, Alison Parker, Sean Tyrrel, Francis Hassard, Camila Garbutt, Mathewos Moges, Fitsume Woldemedhin, and Mohammedyasin Jemal

Subjects

Medicine, Science

Abstract

Early infection from enteropathogens is recognised as both a cause and effect of infant malnutrition. Specifically, evidence demonstrates associations between growth shortfalls and Campylobacter infection, endemic across low-income settings, with poultry a major source. Whilst improvements in water, sanitation and hygiene (WASH) should reduce pathogen transmission, interventions show inconsistent effects on infant health. This cross-sectional, formative study aimed to understand relationships between infant Campylobacter prevalence, malnutrition and associated risk factors, including domestic animal husbandry practices, in rural Ethiopia. Thirty-five households were visited in Sidama zone, Southern Nations, Nationalities and Peoples' region. Infant and poultry faeces and domestic floor surfaces (total = 102) were analysed for presumptive Campylobacter spp. using selective culture. Infant anthropometry and diarrhoeal prevalence, WASH facilities and animal husbandry data were collected. Of the infants, 14.3% were wasted, 31.4% stunted and 31.4% had recent diarrhoea. Presumptive Campylobacter spp. was isolated from 48.6% of infant, 68.6% of poultry and 65.6% of floor surface samples. Compared to non-wasted infants, wasted infants had an increased odds ratio (OR) of 1.41 for a Campylobacter-positive stool and 1.81 for diarrhoea. Positive infant stools showed a significant relationship with wasting (p = 0.026) but not stunting. Significant risk factors for a positive stool included keeping animals inside (p = 0.027, OR 3.5), owning cattle (p = 0.018, OR 6.5) and positive poultry faeces (p

Published

2020

15. Physicochemical Factors Influence the Abundance and Culturability of Human Enteric Pathogens and Fecal Indicator Organisms in Estuarine Water and Sediment

Author

Francis Hassard, Anthony Andrews, Davey L. Jones, Louise Parsons, Vera Jones, Brian A. Cox, Peter Daldorph, Howard Brett, James E. McDonald, and Shelagh K. Malham

Subjects

sediment, fecal indicator organisms, pathogen, elemental analysis, viable but non-culturable bacteria, Microbiology, QR1-502

Abstract

To assess fecal pollution in coastal waters, current monitoring is reliant on culture-based enumeration of bacterial indicators, which does not account for the presence of viable but non-culturable or sediment-associated micro-organisms, preventing effective quantitative microbial risk assessment (QMRA). Seasonal variability in viable but non-culturable or sediment-associated bacteria challenge the use of fecal indicator organisms (FIOs) for water monitoring. We evaluated seasonal changes in FIOs and human enteric pathogen abundance in water and sediments from the Ribble and Conwy estuaries in the UK. Sediments possessed greater bacterial abundance than the overlying water column, however, key pathogenic species (Shigella spp., Campylobacter jejuni, Salmonella spp., hepatitis A virus, hepatitis E virus and norovirus GI and GII) were not detected in sediments. Salmonella was detected in low levels in the Conwy water in spring/summer and norovirus GII was detected in the Ribble water in winter. The abundance of E. coli and Enterococcus spp. quantified by culture-based methods, rarely matched the abundance of these species when measured by qPCR. The discrepancy between these methods was greatest in winter at both estuaries, due to low CFU's, coupled with higher gene copies (GC). Temperature accounted for 60% the variability in bacterial abundance in water in autumn, whilst in winter salinity explained 15% of the variance. Relationships between bacterial indicators/pathogens and physicochemical variables were inconsistent in sediments, no single indicator adequately described occurrence of all bacterial indicators/pathogens. However, important variables included grain size, porosity, clay content and concentrations of Zn, K, and Al. Sediments with greater organic matter content and lower porosity harbored a greater proportion of non-culturable bacteria (including dead cells and extracellular DNA) in winter. Here, we show the link between physicochemical variables and season which govern culturability of human enteric pathogens and FIOs. Therefore, knowledge of these factors is critical for accurate microbial risk assessment. Future water quality management strategies could be improved through monitoring sediment-associated bacteria and non-culturable bacteria. This could facilitate source apportionment of human enteric pathogens and FIOs and direct remedial action to improve water quality.

Published

2017

16. Application of Ultraviolet Light-Emitting Diodes (UV-LED) to Full-Scale Drinking-Water Disinfection

Author

Peter Jarvis, Olivier Autin, Emma H. Goslan, and Francis Hassard

Subjects

disinfection, Cryptosporidium, UV-LED, bacteriophage, chemical actinometry, drinking water, Hydraulic engineering, TC1-978, Water supply for domestic and industrial purposes, TD201-500

Abstract

Ultraviolet light-emitting diodes (UV-LEDs) have recently emerged as a viable technology for water disinfection. However, the performance of the technology in full-scale drinking-water treatment systems remains poorly characterised. Furthermore, current UV disinfection standards and protocols have been developed specifically for conventional mercury UV systems and so do not necessarily provide an accurate indication of UV-LED disinfection performance. Hence, this study aimed to test the hypothesis that a full-scale UV-LED reactor can match the Cryptosporidium inactivation efficiency of conventional mercury UV reactors. Male-specific bacteriophage (MS2) was used as the Cryptosporidium spp. surrogate microorganism. The time-based inactivation efficiency of the full-scale reactor was firstly compared to that of a bench-scale (batch-type) UV-LED reactor. This was then related to mercury UV reactors by comparing the fluence-based efficiency of the bench-scale reactor to the USEPA 90% prediction interval range of expected MS2 inactivation using mercury UV lamps. The results showed that the full-scale UV-LED reactor was at least as effective as conventional mercury UV reactors at the water-quality and drive-current conditions considered. Nevertheless, comparisons between the bench- and full-scale UV-LED reactors indicated that improvements in the hydraulic flow profile and power output of the full-scale reactor could help to further improve the efficiency of UV-LED reactors for municipal drinking water disinfection. This represents the world’s first full-scale UV-LED reactor that can be applied at municipal water treatment works for disinfection of pathogenic microorganisms from drinking water.

Published

2019

17. Abundance and distribution of enteric bacteria and viruses in coastal and estuarine sediments – a review.

Author

Francis Hassard, Ceri L Gwyther, Kata Farkas, Anthony Andrews, Vera Jones, Brian Cox, Howard Brett, Davey L Jones, James E McDonald, and Shelagh K Malham

Subjects

Survival, Biofilm, sediment, resuspension, Faecal indicator organisms, Viable but non-culturable bacteria, Microbiology, QR1-502

Abstract

The long term survival of faecal indicator organisms (FIOs) and human pathogenic microorganisms in sediments is important from a water quality, human health and ecological perspective. Typically, both bacteria and viruses strongly associate with particulate matter present in freshwater, estuarine and marine environments. This association tends to be stronger in finer textured sediments and is strongly influenced by the type and quantity of clay minerals and organic matter present. Binding to particle surfaces promotes the persistence of bacteria in the environment by offering physical and chemical protection from biotic and abiotic stresses. How bacterial and viral viability and pathogenicity is influenced by surface attachment requires further study. Typically, long-term association with surfaces including sediments induces bacteria to enter a viable-but-non-culturable (VBNC) state. Inherent methodological challenges of quantifying VBNC bacteria may lead to the frequent under-reporting of their abundance in sediments. The implications of this in a quantitative risk assessment context remain unclear. Similarly, sediments can harbour significant amounts of enteric viruses, however, the factors regulating their persistence remains poorly understood. Quantification of viruses in sediment remains problematic due to our poor ability to recover intact viral particles from sediment surfaces (typically

Published

2016

18. Underwater Remote Skimming of Slow Sand Filters for Sustainable Water Production

Author

Francis Hassard, Tolulope Elemo, Michael Chipps, Andrew Turner, Bruce Jefferson, and Nigel Graham

Subjects

Bacteria, Chemistry (miscellaneous), Biofilms, Environmental Chemistry, Chemical Engineering (miscellaneous), Water treatment, Layers, Separation science, Water Science and Technology

Abstract

Slow sand filters (SSF) are a simple water treatment technology providing an important alternative to conventional drinking water treatment. SSF are extensive in terms of carbon cost and chemical use but require a large land area and are complex to operate, as periodic cleaning is required to prevent filter clogging. Therefore, redundant SSF beds are required to enable water production to occur during long cleaning downtimes. Underwater skimming (UWS) is a cleaning innovation where the foulant layer (containing sand and particles) is removed using a skimmer consisting of a shrouded blade mounted on a vehicle platform. Sand, particles, and biofilm are skimmed prior to ex situ washing of the recovered sand. In this Viewpoint, we posit that the introduction of an in situ underwater skimmer operated remotely can substantially help to offset the aforementioned challenge of downtime, with its associated loss of production, enabling the technology to operate more efficiently and remain a pertinent and advantageous process option within modern water treatment facilities or possibly resource constrained settings. Otherwise, this resilient biotechnological process could be replaced by chemical and energy-intensive processes which increase the entropy of water treatment more than SSF. The anticipated benefits and challenges of UWS of SSF are discussed.

Published

2022

19. Polybacterial shift in benthic river biofilms attributed to organic pollution – prospect of a new biosentinel?

Author

Benjamin Exton, Francis Hassard, Angel Medina Vaya, and Robert C. Grabowski

Subjects

16s rRNA amplicon analysis, bioindicator, Rhodoferax, Sphaerotilus, water quality, sewage fungus, Water Science and Technology

Abstract

Organic pollution continues to contaminate river water and degrade aquatic ecosystems worldwide. In heavily modified river systems with high organic loading, sewage fungus, a heterotrophic biofilm, can form on the riverbed. The aim of this study was to determine how the polybacterial community of riverbed biofilms changes prior to and during a sewage fungus outbreak to inform the development of novel biomonitoring approaches. Riverbed biofilm samples were collected from a site that experienced sewage fungus outbreaks previously and an upstream control, following a BACI design. The polybacterial community was characterized using targeted amplicon sequencing (16s rRNA). The results indicate that the community became dominated by two genera prior to and during the sewage fungus outbreak, Rhodoferax and Sphaerotilus, which accounted for 32.8 and 14.2% of the relative abundance. When aggregated at a higher taxonomic level, the genetic data show that the community was comprised largely of bacteria from a single family, Comamonadaceae, totalling 64.1% of the relative abundance. Statistically significant differences in the polybacterial community over time and between impact and control sites provide initial evidence that genetic-based fingerprinting could be a promising biosentinel approach to identify organic pollution inputs and monitor their ecological impact.

Published

2023

20. Inhibitory mechanisms on dry anaerobic digestion: Ammonia, hydrogen and propionic acid relationship

Author

Ildefonso Rocamora, Stuart T. Wagland, Francis Hassard, Raffaella Villa, Miriam Peces, Edmon W. Simpson, Oliver Fernández, and Yadira Bajón-Fernández

Subjects

Syntrophic acetogenic oxidation, Methanoculleus, Butyric accumulation, Hydrogen inhibition, High solids digestion, Waste Management and Disposal, Propionic accumulation

Abstract

open access article Inhibitory pathways in dry anaerobic digestion are still understudied and current knowledge on wet processes cannot be easily transferred. This study forced instability in pilot-scale digesters by operating at short retention times (40 and 33 days) in order to understand inhibition pathways over long term operation (145 days). The first sign of inhibition at elevated total ammonia concentrations (8 g/l) was a headspace hydrogen level over the thermodynamic limit for propionic degradation, causing propionic accumulation. The combined inhibitory effect of propionic and ammonia accumulation resulted in further increased hydrogen partial pressures and n-butyric accumulation. The relative abundance of Methanosarcina increased while that of Methanoculleus decreased as digestion deteriorated. It was hypothesized that high ammonia, total solids and organic loading rate inhibited syntrophic acetate oxidisers, increasing their doubling time and resulting in its wash out, which in turn inhibited hydrogenotrophic methanogenesis and shifted the predominant methanogenic pathway towards acetoclastic methanogenesis at free ammonia over 1.5 g/l. C/N increases to 25 and 29 reduced inhibitors accumulation but did not avoid inhibition or the washout of syntrophic acetate oxidising bacteria.

Published

2023

21. Dissemination of metaldehyde catabolic pathways is driven by mobile genetic elements in Proteobacteria

Author

Víctor Castro-Gutierrez, Edward Fuller, María Pilar Garcillán-Barcia, Thorunn Helgason, Francis Hassard, James Moir, Universidad de Cantabria, Universidad de Costa Rica, York University, Ministerio de Ciencia, Innovación y Universidades (España), and Agencia Estatal de Investigación (España)

Subjects

insertion sequence, Metaldehyde, Gene Transfer, Horizontal, Evolution, Insertion sequence, General Medicine, pesticides, Plasmid, Sphingomonadaceae, bioremediation, plasmid, Proteobacteria, evolution, DNA Transposable Elements, Escherichia coli, Pesticides, metaldehyde, Bioremediation, Plasmids

Abstract

Bioremediation of metaldehyde from drinking water using metaldehyde-degrading strains has recently emerged as a promising alternative. Whole-genome sequencing was used to obtain full genomes for metaldehyde degraders Acinetobacter calcoaceticus E1 and Sphingobium CMET-H. For the former, the genetic context of the metaldehyde-degrading genes had not been explored, while for the latter, none of the degrading genes themselves had been identified. In A. calcoaceticus E1, IS91 and IS6-family insertion sequences (ISs) were found surrounding the metaldehyde-degrading gene cluster located in plasmid pAME76. This cluster was located in closely-related plasmids and associated to identical ISs in most metaldehyde-degrading β- and γ-Proteobacteria, indicating horizontal gene transfer (HGT). For Sphingobium CMET-H, sequence analysis suggested a phytanoyl-CoA family oxygenase as a metaldehyde-degrading gene candidate due to its close homology to a previously identified metaldehyde-degrading gene known as mahX. Heterologous gene expression in Escherichia coli alongside degradation tests verified its functional significance and the degrading gene homolog was henceforth called mahS. It was found that mahS is hosted within the conjugative plasmid pSM1 and its genetic context suggested a crossover between the metaldehyde and acetoin degradation pathways. Here, specific replicons and ISs responsible for maintaining and dispersing metaldehyde-degrading genes in α, β and γ-Proteobacteria through HGT were identified and described. In addition, a homologous gene implicated in the first step of metaldehyde utilisation in an α-Proteobacteria was uncovered. Insights into specific steps of this possible degradation pathway are provided., VCG was supported by the University of Costa Rica with a Scholarship for Doctoral Studies Abroad and the University of York with a Scholarship for Overseas Students. MPG-B is supported by grant PID2020-117923GB-I00 from the Spanish Ministry of Science and Innovation. JM is grateful for NERC award (NE/N009061/1) and Thames Water for supporting a scholarship for EF.

Published

2022

22. Managing full-scale dry anaerobic digestion: semi-continuous and batch operation

Author

Ildefonso Rocamora, Stuart T. Wagland, Mónica Rivas Casado, Francis Hassard, Raffaella Villa, Miriam Peces, Edmon W. Simpson, Oliver Fernández, and Yadira Bajón-Fernández

Subjects

Process Chemistry and Technology, Operational parameters, Bulking agent, Compost addition, Chemical Engineering (miscellaneous), Regression tree, Pollution, Waste Management and Disposal, Hydrogenotrophic archaea, Percolate recirculation

Abstract

open access article Dry anaerobic digestion usually results in inhibitors accumulation, which can be solved by adapting operation. Multiple strategies targeting increased stability are implemented in full-scale, but impacts are poorly documented. Two full-scale dry AD plants treating organic fraction of municipal solid waste (OFMSW) were investigated: a semi-continuous plant with compost addition and a batch plant testing different percolate recirculation strategies and inoculum to substrate ratios. Regression tree analysis was used to evaluate the effect of these strategies on methane yields and inhibitors accumulation. Compost addition in the semi-continuous plant reduced volatile fatty acids content but dropped methane flow up to 10 % when compost constituted over 10.1 % in weight of the incoming feedstock. This reduction was linked to the limited availability of easily degradable material in the compost. In batch dry AD, methane yields increased as percolate recirculated raised up to a range of 182–197 m3 (0.342–0.363 m3/t of biomass mix). Recirculation of higher percolate volumes reduced methane production, probably linked to pile compaction and inhibitors accumulation. The ratio of OFMSW, digestate and woodchip (bulking agent) fed was determinant, and methane production was higher when digestate was over 43.1 %, waste between 45 % and 47.5 % and woodchip over 8.2 % in weight in as received basis. Woodchip influenced percolation through the pile and supported reduced total ammonia levels of 3.2 g/l when kept over 8.2 %, which raised to 5.2 g/l for lower values.

Published

2022

23. Wastewater surveillance for rapid identification of infectious diseases in prisons

Author

Francis Hassard, Theodore R Smith, Alexandria B Boehm, Shannon Nolan, Oscar O'Mara, Mariachiara Di Cesare, and David Graham

Subjects

Microbiology (medical), Wastewater-Based Epidemiological Monitoring, Infectious Diseases, Prisoners, Prisons, Virology, Humans, Wastewater, Communicable Diseases, Microbiology

Published

2022

24. Molecular Insights Informing Factors Affecting Low Temperature Anaerobic Applications: Diversity, Collated Core Microbiomes and Complexity Stability Relationships

Author

Suniti Singh, Ciara Keating, Umer Ijazd, and Francis Hassard

Subjects

History, Polymers and Plastics, Business and International Management, Industrial and Manufacturing Engineering

Published

2022

25. Wastewater-based epidemiology and group privacy: the elephant in the sewer?

Author

Rachel Kwiatkowska, Anouk Ruhaak, Barbara Kasprzyk-Hordern, Francis Hassard, Lian Lundy, Mariachiara Di Cesare, Matthew Hickman, and Andrew Singer

Abstract

Pre-print of a viewpoint submitted to Environmental Science & Technology

Published

2021

26. Probe-based qPCR assay enables the rapid and specific detection of bacterial degrading genes for the pesticide metaldehyde in soil

Author

Víctor M. Castro-Gutierrez, Francis Hassard, and James W.B. Moir

Subjects

Microbiology (medical), Metaldehyde, Drinking Water, Degrading gene, Acetaldehyde, Microbiology, qPCR, Soil, Biodegradation, Environmental, PESTICIDES, BACTERIA, Soil Pollutants, Pesticides, Molecular Biology, Soil Microbiology, Water Pollutants, Chemical

Abstract

Metaldehyde, a molluscicide pesticide, has been identified as a pollutant of concern due to its repeated detection in drinking water, thereby generating numerous compliance failures for water utilities. Biological degradation potential for metaldehyde is widespread in soils, occurring at different rates, but to date, no molecular methods for its assessment have been reported. Here, three genes belonging to a shared metaldehyde-degrading gene cluster present in bacteria were used as candidates for development of a quantitative PCR (qPCR) assay for assessing the metaldehyde-degrading potential in soil. Screening of gene targets, primer pairs and optimization of reaction conditions led to the development of a sensitive and specific probe-based qPCR method for quantifying the mahY metaldehyde-degrading gene from soil. The technique was tested across 8 soils with different compositions and origins. The degrading pathway was detected in 4/8 soils, in which a higher number of gene copies correlated with periods of greater metaldehyde removal. Additionally, swift elimination of the pesticide was observed in soils with an elevated initial number of mahY gene copies. The gene cluster was not detected in other soils, even though metaldehyde removal occurred, indicating that other biological degrading pathways are also important in nature. The method described here is the first one available to estimate the microbial metaldehyde degradation potential and activity in soils, and can also be used to detect degrading microorganisms in systems such as sand filters for water purification or to monitor degrading strains in engineered processes. Previous article in issue Universidad de Costa Rica/[]/UCR/Costa Rica Universidad de York/[]/UY/Reino Unido UCR::Vicerrectoría de Investigación::Unidades de Investigación::Ciencias Básicas::Centro en Investigación en Contaminación Ambiental (CICA)

Published

2021

27. Role of filtration in managing the risk from Cryptosporidium in commercial swimming pools – a review

Author

Martin Wood, Jitka MacAdam, Francis Hassard, Lester P. Simmonds, Peter Jarvis, and Rachel M. Chalmers

Subjects

Microbiology (medical), Biocide, 0208 environmental biotechnology, Cryptosporidiosis, Cryptosporidium, Particle (ecology), 02 engineering and technology, 010501 environmental sciences, 01 natural sciences, law.invention, Swimming Pools, law, swimming pools, medicine, Animals, Waste Management and Disposal, Filtration, 0105 earth and related environmental sciences, Water Science and Technology, filtration, Suspended solids, biology, particle counting, Oocysts, Public Health, Environmental and Occupational Health, Environmental engineering, Waterborne diseases, biology.organism_classification, medicine.disease, Cryptosporidium oocysts, turbidity, 020801 environmental engineering, Infectious Diseases, Environmental science, Water treatment, Water quality, Water Microbiology

Abstract

Most commercial swimming pools use pressurised filters, typically containing sand media, to remove suspended solids as part of the water treatment process designed to keep water attractive, clean and safe. The accidental release of faecal material by bathers presents a poorly quantified risk to the safety of swimmers using the pool. The water treatment process usually includes a combination of maintaining a residual concentration of an appropriate biocide in the pool together with filtration to physically remove particles, including microbial pathogens, from the water. However, there is uncertainty about the effectiveness of treatment processes in removing all pathogens, and there has been growing concern about the number of reported outbreaks of the gastrointestinal disease cryptosporidiosis, caused by the chlorine-resistant protozoan parasite Cryptosporidium. A number of interacting issues influence the effectiveness of filtration for the removal of Cryptosporidium oocysts from swimming pools. This review explains the mechanisms by which filters remove particles of different sizes (including oocyst-sized particles, typically 4–6 μm), factors that affect the efficiency of particle removal (such as filtration velocity), current recommended management practices, and identifies further work to support the development of a risk-based management approach for the management of waterborne disease outbreaks from swimming pools. This article has been made Open Access thanks to the generous support of a global network of libraries as part of the Knowledge Unlatched Select initiative.

Published

2019

28. Titania containing natural clay doped with carbon nanotubes for enhanced natural photocatalytic discoloration of wastewater

Author

Adolph Anga Muleja, Mukuna Patrick Mubiayi, Francis Hassard, and Bhekie B. Mamba

Subjects

Materials science, Radical, chemistry.chemical_element, Bioengineering, 02 engineering and technology, Carbon nanotube, 010402 general chemistry, 01 natural sciences, Mineralization (biology), Nanocomposites, law.invention, law, General Materials Science, Photocatalysis, Fourier transform infrared spectroscopy, Dyes, Nanocomposite, Mechanical mixing, General Chemistry, 021001 nanoscience & nanotechnology, Condensed Matter Physics, Atomic and Molecular Physics, and Optics, 0104 chemical sciences, chemistry, Modeling and Simulation, Heterojunction, Absorption (chemistry), African clay, 0210 nano-technology, Carbon, Nuclear chemistry

Abstract

Water contamination with dyes is harmful to humans and the environment. This study investigated the photocatalytic activity of natural clay (GOL) mixed with carbon nanotubes (CNT) for removal of brilliant black (BB) in wastewater. The materials were characterized with FESEM-EDS, XRD, XRF, FTIR and UV-vis DRS. The natural clay contains 2.34 % TiO2 which is 75% more than most natural clays. SEM showed that CNT were well dispersed and mixed with clay. DRS spectra showed two absorption bands above 380 nm. CNT in GOL has decreased significantly the energy band gaps from 2.75 and 3.25 eV to 1.53 and 2.90 eV for GOL and 10% CNT–GOL, respectively. Photocatalytic activity was enhanced with degradation of BB increased from 66 to 95% with GOL and 10% CNT–GOL respectively after 45 min of visible light irradiation. The improvement can be attributed to the synergy of the interface heterojunction of clay and CNT. The presence of CNT reduces the e− and h+ (e− / h+) pairs recombination and facilitates the production of reactive oxygen species responsible for the decay of dye. The addition of H2O2 to the experiment (2 mmoL) confirmed the role of holes and hydroxyl radicals. Eighty-five percent of BB carbon content was removed with 10% CNT–GOL suggesting that mineralization occurred. After 45 min of visible light irradiation, the degradation kinetic studies followed a second-order reaction with a R2 = 0.997. Therefore, natural clay–CNT nanocomposites can be applied to treat dyes containing wastewaters.

Published

2021

29. Monitoring occurrence of SARS-CoV-2 in school populations: a wastewater-based approach

Author

Francis Hassard, Gianluca Baio, Andrew C. Singer, Shadi Rahimzadeh, Azeem Majeed, Jan Hofman, Dirk Wildeboer, Barbara Kasprzyk-Hordern, Beata Burczynska, Rachel Kwiatkowska, Jasmine M. S. Grimsley, Hemda Garelick, Sally J. Priest, Isobel C. Stanton, Mariachiara Di Cesare, Victor Castro Gutierrez, Milan Vu, Rodrigo Leitao, and Lian Lundy

Subjects

Wastewater, Coronavirus disease 2019 (COVID-19), business.industry, Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), Environmental health, Pandemic, Medicine, Wastewater based epidemiology, Limiting, business, Monitoring tool, Frequent use

Abstract

Clinical testing of children in schools is challenging, with economic implications limiting its frequent use as a monitoring tool of the risks assumed by children and staff during the COVID-19 pandemic. Here, a wastewater based epidemiology approach has been used to monitor 16 schools (10 primary, 5 secondary and 1 post-16 and further education for a total of 17 sites) in England. A total of 296 samples over 9 weeks have been analysed for N1 and E genes using qPCR methods. Of the samples returned, 47.3% were positive for one or both genes with a frequency of detection in line with the respective community. WBE offers a promising low cost, non-invasive approach for supplementing clinical testing and can offer longitudinal insights that are impractical with traditional clinical testing.

Published

2021

30. Making Waves: Collaboration in the time of SARS-CoV-2 - rapid development of an international co-operation and wastewater surveillance database to support public health decision-making

Author

Félix Hernández, Maria Viklander, Jose Antonio Baz-Lomba, Francisco Javier Escobar Martínez, Andrea Soltysova, Frederic Been, Kelly Hill, Maria Blanca Sanchez, Věra Očenášková, Tomáš Mackuľak, Despo Fatta-Kassinos, Juan A. Vallejo, Mohammed Nasser, Annelie Hedström, Leonor Nozal, Genevieve Deviller, Vassie C. Ware, Veronika Janska, Dimitrios Papadopoulos, Popi Karaolia, Foon Yin Lai, Francis Hassard, Nikolaos S. Thomaidis, Manuela Barneo, Marianna Cichova, Adrienn Micsinai, Kristen L. Jellison, Lorena Martinez-Garcia, Jan Hofman, Beatriz Peinado, Valeria Dulio, Nikiforos A. Alygizakis, Gertjan Medema, Pei-Ying Hong, Andrej Ficek, Jaroslav Slobodnik, Rosa de Llanos, Norbert Kreuzinger, Erica Donner, Sara Castiglioni, Soraya Rumbo-Feal, Margarita Poza, Lian Lundy, Alexander L.N. van Nuijs, Lubertus Bijlsma, Mette Myrmel, Lubos Cirka, Harald Niederstätter, Herbert Oberacher, Anna J. Székely, Dimitra A. Lambropoulou, Ján Krahulec, Barbara Kasprzyk-Hordern, Leslie Ogorzaly, Tarja Pitkänen, Stoimir Kolarević, Kelly Conde-Pérez, Adrian Covaci, Institut National de l'Environnement Industriel et des Risques (INERIS), Lundy, Lian, Fatta-Kassinos, Despo, Slobodnik, Jaroslav, Karaolia, Popi, Donner, Erica, Viklander, Maria, Helsinki One Health (HOH), Waterborne pathogens, and Food Hygiene and Environmental Health

Subjects

0208 environmental biotechnology, 02 engineering and technology, 010501 environmental sciences, Wastewater, computer.software_genre, 01 natural sciences, Upload, Resource (project management), wastewater monitoring, EPIDEMIOLOGY, Vattenteknik, Waste Management and Disposal, Water Science and Technology, 11832 Microbiology and virology, Database, Ecological Modeling, public health, Water Engineering, SARS-CoV-2 RNA, Pollution, 3142 Public health care science, environmental and occupational health, 6. Clean water, 3. Good health, Chemistry, [SDE]Environmental Sciences, RNA, Viral, Public Health, QR355 Virology, NORMAN/SCORE SARS-COV-2 in sewage (SC2S) database, Underpinning, medicine.medical_specialty, Environmental Engineering, MEDLINE, Context (language use), Article, Supply and demand, SDG 3 - Good Health and Well-being, medicine, Humans, wastewater, Biology, 0105 earth and related environmental sciences, Civil and Structural Engineering, SARS-CoV-2, Public health, COVID-19, Q Science (General), 020801 environmental engineering, Data sharing, Ecological Modelling, computer, Wastewater surveillance

Abstract

The presence of SARS-CoV-2 RNA in wastewater was first reported in March 2020. Over the subsequent months, the potential for wastewater surveillance to contribute to COVID-19 mitigation programmes has been the focus of intense national and international research activities, gaining the attention of policy makers and the public. As a new application of an established methodology, focused collaboration between public health practitioners and wastewater researchers is essential to developing a common understanding on how, when and where the outputs of this non-invasive community-level approach can deliver actionable outcomes for public health authorities. Within this context, the NORMAN SCORE “SARS-CoV-2 in sewage” database provides a platform for rapid, open access data sharing, validated by the uploading of 276 data sets from nine countries to-date. Through offering direct access to underpinning meta-data sets (and describing its use in data interpretation), the NORMAN SCORE database is a resource for the development of recommendations on minimum data requirements for wastewater pathogen surveillance. It is also a tool to engage public health practitioners in discussions on use of the approach, providing an opportunity to build mutual understanding of the demand and supply for data and facilitate the translation of this promising research application into public health practice. Validerad;2021;Nivå 2;2021-05-21 (alebob);Finansiär: För finansiärsinformation se Acknowledgements https://www.sciencedirect.com/science/article/pii/S0043135421003651?via%3Dihub#ack0001 DRIZZLE

Published

2021

31. Innovation in wastewater near-source tracking for rapid identification of COVID-19 in schools

Author

Lian Lundy, Andrew C. Singer, Francis Hassard, Jasmine M. S. Grimsley, and Mariachiara Di Cesare

Subjects

Microbiology (medical), medicine.medical_specialty, 2019-20 coronavirus outbreak, Schools, Coronavirus disease 2019 (COVID-19), SARS-CoV-2, Public health, Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), Comment, COVID-19, Context (language use), Wastewater, Microbiology, wastewater-based epidemiology, Rapid identification, Intervention (law), Infectious Diseases, Health, Virology, medicine, Humans, near-source tracking (NST), Business, Source tracking, Environmental planning

Abstract

COVID-19 is one of the biggest global public health challenges of the century with almost 42 million cases and more than a million deaths to date. Until a COVID-19 vaccine or effective pharmaceutical intervention is developed, alternative tools for the rapid identification, containment, and mitigation of the spread of severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) are of paramount importance for managing community transmission. Within this context, school closure has been one of the strategies implemented to reduce spread at local and national levels. [...]

Published

2021

32. Chlorine disinfection of drinking water assessed by flow cytometry : New insights

Author

Graeme Moore, Francis Hassard, Peter Jarvis, Andreas Nocker, Ryan Cheswick, and Bruce Jefferson

Subjects

0208 environmental biotechnology, Dose dependence, Soil Science, chemistry.chemical_element, 02 engineering and technology, Plant Science, 010501 environmental sciences, medicine.disease_cause, 01 natural sciences, Flow cytometry, Chlorine, medicine, Escherichia coli, Chlorination, Drinking water, Food science, 0105 earth and related environmental sciences, General Environmental Science, biology, medicine.diagnostic_test, Treated water, Bacteria, biology.organism_classification, 020801 environmental engineering, Disinfection, chemistry, Pure culture, Water treatment, Biologie

Abstract

The efficacy of chlorine disinfection was assessed for the first time over a range of disinfection conditions using flow cytometry (FCM) to provide new insights into disinfection processes. Inactivation was assessed for pure culture bacteria (Escherichia coli) and micro-organisms in real treated water from operational water treatment works (WTWs). A dose dependent increase in inactivation rate (k) was observed for both test matrices, with values of 0.03 to 0.26 and 0.32 to 3.14 L/mg min for the WTW bacteria and E. coli, respectively. After 2 min, E. coli was reduced by 2 log for all chlorine doses (0.12 to 1.00 mg/L). In the case of the WTW filtrate bacteria, after 2 min log reductions were between 0.54 and 1.14 with increasing chlorine concentration, reaching between 1.32 and 2.33 after 30 min. A decrease in disinfection efficacy was observed as temperature decreased from 19 to 5 °C for both microbial populations. With respect to chlorination at different pH (pH 6, 7, 8), membrane damage was more pronounced at higher pH. This was not consistent with the higher disinfection efficacy seen at lower pH. when culture based methods are used to assess bacterial reductions. This provides evidence that more understanding into the fundamental mechanisms of chlorine disinfection are required and that methodological alterations may be required (e.g. pH standardisation) to fully utilise FCM over the entire range of chlorination conditions observed in operational environments.

Published

2020

33. Turbidity composition and the relationship with microbial attachment and UV inactivation efficacy

Author

Charlotte Farrell, Peter Jarvis, Tangui Léziart, Francis Hassard, Bruce Jefferson, and Andreas Nocker

Subjects

Environmental Engineering, Ultraviolet Rays, 0208 environmental biotechnology, chemistry.chemical_element, 02 engineering and technology, Manganese, 010501 environmental sciences, Ferric Compounds, 01 natural sciences, Inactivation, Enterococcus faecalis, Water Purification, Turbidity, chemistry.chemical_compound, UV disinfection, Escherichia coli, Environmental Chemistry, Waste Management and Disposal, Humic Substances, 0105 earth and related environmental sciences, Faecal indicator organism, biology, E. coli, Contamination, biology.organism_classification, Pollution, 020801 environmental engineering, Disinfection, Water quality, chemistry, E. faecalis, Environmental chemistry, Hydroxide, Composition (visual arts), Water treatment, Water Microbiology, Biologie, Water Pollutants, Chemical

Abstract

Turbidity in water can be caused by a range of different turbidity causing materials (TCM). Here the characteristics and attachment of bacteria to TCMs was assessed and the resultant impact on UV disinfection determined. TCMs represent potential vehicles for bacterial penetration of water treatment barriers, contamination of potable supplies and impact on subsequent human health. The TCMs under investigation were representative of those that may be present in surface and ground waters, both from the source and formed in the treatment process. The TCMs were chalk, Fe (III) hydroxide precipitate, kaolin clay, manganese dioxide and humic acids, at different turbidity levels representative of source waters (0, 0.1, 0.2, 0.4, 1, 2, and 5 NTU). Escherichia coli and Enterococcus faecalis attachment followed the order of Fe(III) > chalk, with little to no attachment seen for MnO2, humic acids and clay. The attachment was postulated to be due to chalk and Fe(III) particles having a more neutral surface charge resulting in elevated aggregation with bacteria compared to other TCMs. The humic acids and Fe(III) were the TCMs which influenced inactivation of E. coli and E. faecalis due to decreasing UV transmittance (UVT) with increasing TCM concentration. The presence of the Fe(III) TCM at 0.2 NTU resulted in the poorest E. coli inactivation, with 2.5 log10 reduction at UV dose of 10 mJ cm− 2 (kd of − 0.23 cm2 mJ− 1) compared to a 3.9 log10 reduction in the absence of TCMs. E. faecalis had a greater resistance to UV irradiation than E. coli for all TCMs. Effective disinfection of drinking water is a priority for ensuring high public health standards. Uniform regulations for turbidity levels for waters pre-disinfection by UV light set by regulators may not always be appropriate and efficacy is dependent on the type, as well as the amount, of turbidity present in the water.

Published

2018

34. Critical Review on the Public Health Impact of Norovirus Contamination in Shellfish and the Environment: A UK Perspective

Author

Jasmine H. Sharp, Lewis LeVay, Helen E. Taft, David L. Jones, James E. McDonald, Francis Hassard, James M. Wilson, Shelagh K. Malham, Karen E. Tuson, and John P. Harris

Subjects

0301 basic medicine, Oyster, Epidemiology, Health, Toxicology and Mutagenesis, 030106 microbiology, Population, Food Contamination, Aquaculture, Biology, medicine.disease_cause, Food safety, 03 medical and health sciences, stomatognathic system, Virology, biology.animal, medicine, Animals, Humans, education, Shellfish, Environmental quality, Caliciviridae Infections, Review Paper, education.field_of_study, business.industry, Ecology, Norovirus, food and beverages, Contamination, bacterial infections and mycoses, United Kingdom, Fishery, Norwalk, Public Health, Water Microbiology, business, Food Science

Abstract

We review the risk of norovirus (NoV) infection to the human population from consumption of contaminated shellfish. From a UK perspective, risk is apportioned for different vectors of NoV infection within the population. NoV spreads mainly by person-to-person contact or via unsanitary food handling. NoV also enters the coastal zone via wastewater discharges resulting in contamination of shellfish waters. Typically, NoV persists in the marine environment for several days, with its presence strongly linked to human population density, wastewater discharge rate, and efficacy of wastewater treatment. Shellfish bioaccumulate NoV and current post-harvest depuration is inefficient in its removal. While NoV can be inactivated by cooking (e.g. mussels), consumption of contaminated raw shellfish (e.g. oysters) represents a risk to human health. Consumption of contaminated food accounts for 3-11% of NoV cases in the UK (~74,000 cases/year), of which 16% are attributable to oyster consumption (11,800 cases/year). However, environmental and human factors influencing NoV infectivity remain poorly understood. Lack of standard methods for accurate quantification of infective and non-infective (damaged) NoV particles represent a major barrier, hampering identification of an appropriate lower NoV contamination limit for shellfish. Future management strategies may include shellfish quality assessment (at point of harvest or at point of supply) or harvesting controls. However, poor understanding of NoV inactivation in shellfish and the environment currently limits accurate apportionment and risk assessment for NoV and hence the identification of appropriate shellfish or environmental quality standards.

Published

2017

35. From full-scale biofilters to bioreactors: engineering biological metaldehyde removal

Author

Bruce Jefferson, Francis Hassard, Adam Brookes, Gregg Iceton, Raffaella Villa, Catherine Rolph, and Andoni Choya

Subjects

Environmental Engineering, 010504 meteorology & atmospheric sciences, Acetaldehyde, 010501 environmental sciences, acclimation, 01 natural sciences, Slow sand filter, law.invention, Water Purification, chemistry.chemical_compound, Bioreactors, law, Bioreactor, Environmental Chemistry, metaldehyde, Waste Management and Disposal, Filtration, 0105 earth and related environmental sciences, Pollutant, fluidised-bed reactor, Chemistry, micropollutant removal, Drinking Water, slow-sand filter, Sorption, Fluidised-bed reactor, Biodegradation, Pollution, Biodegradation, Environmental, Environmental chemistry, Biofilter, Metaldehyde, Water Pollutants, Chemical

Abstract

The file attached to this record is the author's final peer reviewed version. The Publisher's final version can be found by following the DOI link. Polar, low molecular weight pesticides such as metaldehyde are challenging and costly to remove from drinking water using conventional treatment methods. Although biological treatments can be effective at treating micropollutants, through biodegradation and sorption processes, only some operational biofilters have shown the ability to remove metaldehyde. As sorption plays a minor role for such polar organic micropollutants, biodegradation is therefore likely to be the main removal pathway. Here, the biodegradation of metaldehyde was monitored, and assessed, in an operational slow sand filter. Long-term data showed that metaldehyde degradation improved when inlet concentrations increased. A comparison of inactive and active sand batch reactors showed that metaldehyde removal happened mainly through biodegradation and that the removal rates were greater after the biofilm was acclimated through exposure to high metaldehyde concentrations. This suggested that metaldehyde removal was reliant on enrichment and that the process could be engineered to decrease treatment times (from days to hours). Through-flow experiments using fluidised bed reactors, showed the same behaviour following metaldehyde acclimation. A 40% increase in metaldehyde removal was observed in acclimated compared with non-acclimated columns. This increase was sustained for more than 40 days, achieving an average of 80% removal and compliance (< 0.1 µ L-1) for more than 20 days. An initial microbial analysis of the acclimated and non-acclimated biofilm from the same filter materials, showed that the microbial community in acclimated sand was significantly different. This work presents a novel conceptual template for a faster, chemical free, low cost, biological treatment of metaldehyde and other polar pollutants in drinking water. In addition, this is the first study to report kinetics of metaldehyde degradation in an active microbial biofilm at a WTW.

Published

2019

36. Achieving drinking water compliance levels for metaldehyde with an acclimated sand bioreactor

Author

Francis Hassard, Adam Brookes, Catherine Rolph, Bruce Jefferson, and Raffaella Villa

Subjects

Environmental Engineering, Acclimatization, 0208 environmental biotechnology, Water source, 02 engineering and technology, Acetaldehyde, 010501 environmental sciences, Laboratory scale, 01 natural sciences, Water Purification, chemistry.chemical_compound, Bioreactors, Sand, Bioreactor, Effective treatment, Pesticides, Upflow fluidised sand bioreactor, Waste Management and Disposal, 0105 earth and related environmental sciences, Water Science and Technology, Civil and Structural Engineering, Continuous flow, Ecological Modeling, Drinking Water, Pilot scale, Pulp and paper industry, Pollution, 020801 environmental engineering, chemistry, Environmental science, Metaldehyde, Micropollutant removal, Selective enrichment, Acclimation, Water Pollutants, Chemical

Abstract

The file attached to this record is the author's final peer reviewed version. The Publisher's final version can be found by following the DOI link. Metaldehyde removal was delivered to below the 0.1 µg L-1 regulatory concentration in a laboratory scale continuous upflow fluidised sand bioreactor that had undergone acclimation through selective enrichment for metaldehyde degradation. This is the first reported case of successful continuous flow biological treatment of metaldehyde from real drinking water sources treating environmentally realistic metaldehyde concentrations. The impact of the acclimation process was impermanent, with the duration of effective treatment directly related to the elevated concentration of metaldehyde used during the enrichment process. The efficacy of the approach was demonstrated in continuous flow columns at both laboratory and pilot scale enabling degradation rates of between 0.1 and 0.2 mg L-1 h-1. Future work needs to focus on optimisation of the sand bioreactor and the acclimation process to ensure viability and feasibility of the approach at full scale.

Published

2019

37. A comprehensive adsorption study of 1-Hydroxy-2-Naphthoic acid using cost effective engineered materials

Author

Lueta-Ann De Kock, Muhammad Aamer Hussain, Muhammad Aurang Zeb, Francis Hassard, Ralph Muvhiiwa, Khadija Tul Kubra, and Ghulam Murtaza

Subjects

Environmental remediation, 0211 other engineering and technologies, Soil Science, 02 engineering and technology, Plant Science, 010501 environmental sciences, 01 natural sciences, chemistry.chemical_compound, Adsorption, Biochar, Zeolite, 0105 earth and related environmental sciences, General Environmental Science, Magnetite, 1-Hydroxy-2-Naphthoic Acid, 021110 strategic, defence & security studies, Phenanthrene, Decomposition, Poly aromatic hydrocarbons, Enriched adsorbents, Montmorillonite, chemistry, Environmental chemistry, Organic pollutants

Abstract

The naphthoic acids are challenging and costly to remove from water and soil. 1-Hydroxy-2-Naphthoic acid (HNA) is a phenanthrene decomposition product from petroleum-contaminated environments during the aerobic decomposition of polyaromatic hydrocarbons. The hydrogeological mobility of hydrocarbon breakdown products represent a pollution risk (e.g. for drinking water sources). Adsorption to biochar produced from agricultural by-products is a useful strategy to remediate contaminated wastewaters. Here, we examine the controls on the HNA adsorption to the adsorbents magnetite, clay minerals, biochar and magnetite enriched companion materials, namely the influence of contact time, contaminant concentration and ionization effects at different pH. The adsorption of HNA was investigated using low-cost and readily available adsorbents: (i) wheat straw biochar, (ii) rice husk biochar, (iii) sugarcane biochar, (iv) zeolite, (v) montmorillonite, (vi) magnetite and their enriched magnetic companions. Magnetite enriched biochar exhibited greater adsorption rates compared with their nonmagnetic analogs for HNA. The maximum adsorption capacity of the magnetite enriched compounds (initial water concentration of 0.32 mmol HNA.L − 1 ) was 0.45 mmol.HNA.g − 1 of enriched zeolite. The magnetite enriched biochar and conventional biochar showed similar adsorption kinetics although magnetite enrichment improved the efficacy of adsorption. The adsorption fitted the pseudo-second order model in all cases, suggesting the dominant mechanism of adsorption was chemisorption. The magnetite enrichment reduced intra-particle diffusion, possibly due to fouling or blocking of pores within the particles, as evidenced by the decrease in diffusion rate constants. Overall, HNA adsorption improved after magnetic enrichment due to magnetite competing with inhibition sites on the biochar carriers. These findings translate into equivalence between magnetite and magnetic biochars, suggesting cheaper alternative materials could be synthesized in situ with the biochar acting as both an adsorbent and carrier, increasing the prospect of designer biochars for targeted pollutant removal. This approach has the potential to be used for wastewater treatment or for application as a soil additive for remediation of runoff from contaminated soils.

Published

2020

38. Biosolids recycling impact on biofilm extracellular enzyme activity and performance of hybrid rotating biological reactors

Author

Elise Cartmell, Francis Hassard, Jeremy R. Biddle, Frederic Coulon, and Tom Stephenson

Subjects

Bioaugmentation, Rotating biofilm contactor, Environmental Engineering, Denitrification, 010504 meteorology & atmospheric sciences, Biosolids, Nitrogen, 010501 environmental sciences, Waste Disposal, Fluid, 01 natural sciences, Biostimulation, Bioreactors, Environmental Chemistry, Waste Management and Disposal, 0105 earth and related environmental sciences, Total suspended solids, Sewage, Hybrid biological process, Chemistry, Biofilm, Pulp and paper industry, Pollution, Activated sludge, Biofilms, Sewage treatment, Microbial extracellular enzyme activity

Abstract

Biological processes for wastewater treatment is limited by extracellular enzyme activity (EEA) of the biofilm on polymeric substrates. The efficiency of biodegradation / biosorption mechanisms causing EEA and organic load removal in biofilms remains unknown. Our hypothesis was that the limiting step of biological process can be overcome by biostimulation and/or bioaugmentation of the return sludge in hybrid biofilm reactors, which leads to competition between suspended and attached bacteria and lower effective substrate to microrganism ratio. Therefore, we considered more active biosolids to perform best at enhancing reactor removal rate. To test this, the efficacy of recycling distinct bio-solids types considered to have different bacterial activity such as final effluent (FE), humus solids (HS) and recycle activated sludge (RAS) on performance improvements of rotating biofilm reactors (RBRs). These bio-solids were investigated under high organic loading rates (OLR) and solids loading rates (SLR) using pilot scale reactors receiving real municipal wastewaters. Controlled overloading of RBRs revealed that EEA improved with increasing OLR/SLR. High SLR (>3.3 kg Total Suspended Solids m−2 d−1) delayed and decreased the reduction of organic and inorganic removal rates in the biological processes which commonly occurs under high OLRs. This effect was more pronounced in the highest activity solids (RAS > HS > FE) suggesting the activity and function of bio-solids was critical to improve performance of RBRs. High OLR and SLR induced efficient denitrification and organics removal within the biofilm reactor at residence times of

Published

2020

39. Nitrogen oxidation consortia dynamics influence the performance of full-scale rotating biological contactors

Author

Bruce Jefferson, D. Freeman, Boyd A. McKew, Dave R. Clark, Corinne Whitby, Francis Hassard, Frederic Coulon, Y. Bajón Fernández, and A. Wilson

Subjects

010504 meteorology & atmospheric sciences, Nitrogen, Microorganism, Wastewater treatment, 010501 environmental sciences, Rotating biological contactor, 01 natural sciences, Ammonia, RNA, Ribosomal, 16S, Ammonia oxidising bacteria, Nitrogen cycle, lcsh:Environmental sciences, Soil Microbiology, Ammonia oxidising archaea, 0105 earth and related environmental sciences, General Environmental Science, lcsh:GE1-350, biology, Chemistry, Biofilm, hemic and immune systems, biology.organism_classification, Archaea, Nitrification, Microbial population biology, Environmental chemistry, Oxidation-Reduction, Bacteria, circulatory and respiratory physiology

Abstract

Ammonia oxidising microorganisms (AOM) play an important role in ammonia removal in wastewater treatment works (WWTW) including rotating biological contactors (RBCs). Environmental factors within RBCs are known to impact the performance of key AOM, such that only some operational RBCs have shown ability for elevated ammonia removal. In this work, long-term treatment performance of seven full-scale RBC systems along with the structure and abundance of the ammonia oxidising bacteria (AOB) and archaea (AOA) communities within microbial biofilms were examined. Long term data showed the dominance of AOB in most RBCs, although two RBCs had demonstrable shift toward an AOA dominated AOM community. Next Generation Sequencing of the 16S rRNA gene revealed diverse evolutionary ancestry of AOB from RBC biofilms while nitrite-oxidising bacteria (NOBs) were similar to reference databases. AOA were more abundant in the biofilms subject to lower organic loading and higher oxygen concentration found at the distal end of RBC systems. Modelling revealed a distinct nitrogen cycling community present within high performing RBCs, linked to efficient control of RBC process variables (retention time, organic loading and oxygen concentration). We present a novel template for enhancing the resilience of RBC systems through microbial community analysis which can guide future strategies for more effective ammonia removal. To best of the author’s knowledge, this is the first comparative study reporting the use of next generation sequencing data on microbial biofilms from RBCs to inform effluent quality of small WWTW. Keywords: Biofilm, Rotating biological contactor, Nitrification, Wastewater treatment, Ammonia oxidising bacteria, Ammonia oxidising archaea

Published

2020

40. Metaldehyde removal from drinking water by adsorption onto filtration media: mechanisms and optimisation

Author

Catherine Rolph, Francis Hassard, Raffaella Villa, and Bruce Jefferson

Subjects

Environmental Engineering, Cost effectiveness, Chemistry, Biosorption, Biodegradation, Thermal hydrolysis, chemistry.chemical_compound, Adsorption, Environmental chemistry, medicine, Freundlich equation, Metaldehyde, Water Science and Technology, Activated carbon, medicine.drug

Abstract

Trace micropollutants should be removed during drinking water production without increasing the disinfection-by-product formation potential or energy demand of the treatment process. We demonstrate the efficacy of different filtration media to remove metaldehyde through controlled batch experiments on water augmented with metaldehyde. Equilibrium concentrations of metaldehyde and surrogate organics were successfully described by the Freundlich isotherm. Metaldehyde can be attenuated to varying degrees with activated carbon and sand with an active and inactive biofilm with kf values ranging from 0.006–0.3 (mg g−1)(L mg−1)1/n. The presence of the active biofilm improved metaldehyde adsorption by sand media, due to additional biosorption mechanisms, a greater surface area or biodegradation. Baseline levels of competing natural organic matter surrogates (NOM) reduced overall adsorption efficacy but increasing concentrations of NOM did not impact metaldehyde removal efficacy in a significant way. Biological activated carbon was identified as the most suitable adsorbent of metaldehyde (94% removal) but sand with an acclimated biofilm was capable of acting as a bio-adsorbent of metaldehyde even under environmentally relevant concentrations (41% adsorption from 0.002.5 mg L−1). Moreover, we observed that thermal hydrolysis of metaldehyde occurred at 60 °C, suggesting that thermal regeneration of GAC for this pesticide was possible at relatively low temperatures. Biological adsorption and thermal hydrolysis approaches presented herein offered a way forward to increase efficiency and cost effectiveness of existing treatments for metaldehyde.

Published

2018

41. Physicochemical Factors Influence the Abundance and Culturability of Human Enteric Pathogens and Fecal Indicator Organisms in Estuarine Water and Sediment

Author

Anthony Andrews, Vera Jones, Peter Daldorph, Brian A. Cox, Francis Hassard, James E. McDonald, Louise Parsons, Davey L. Jones, Howard Brett, and Shelagh K. Malham

Subjects

0301 basic medicine, Microbiology (medical), Veterinary medicine, Elemental analysis, 030106 microbiology, lcsh:QR1-502, 010501 environmental sciences, medicine.disease_cause, 01 natural sciences, Microbiology, lcsh:Microbiology, Fecal indicator organisms, 03 medical and health sciences, Water column, Abundance (ecology), fecal indicator organisms, medicine, Shigella, Organic matter, 14. Life underwater, Original Research, 0105 earth and related environmental sciences, chemistry.chemical_classification, Indicator organism, viable but non-culturable bacteria, biology, Pathogen, Ecology, elemental analysis, biology.organism_classification, 6. Clean water, Salinity, sediment, chemistry, 13. Climate action, Sediment, Water quality, Viable but non-culturable bacteria, Bacteria, pathogen

Abstract

To assess fecal pollution in coastal waters, current monitoring is reliant on culture-based enumeration of bacterial indicators, which does not account for the presence of viable but non-culturable or sediment-associated micro-organisms, preventing effective quantitative microbial risk assessment (QMRA). Seasonal variability in viable but non-culturable or sediment-associated bacteria challenge the use of fecal indicator organisms (FIOs) for water monitoring. We evaluated seasonal changes in FIOs and human enteric pathogen abundance in water and sediments from the Ribble and Conwy estuaries in the UK. Sediments possessed greater bacterial abundance than the overlying water column, however, key pathogenic species (Shigella spp., Campylobacter jejuni, Salmonella spp., hepatitis A virus, hepatitis E virus and norovirus GI and GII) were not detected in sediments. Salmonella was detected in low levels in the Conwy water in spring/summer and norovirus GII was detected in the Ribble water in winter. The abundance of E. coli and Enterococcus spp. quantified by culture-based methods, rarely matched the abundance of these species when measured by qPCR. The discrepancy between these methods was greatest in winter at both estuaries, due to low CFU's, coupled with higher gene copies (GC). Temperature accounted for 60% the variability in bacterial abundance in water in autumn, whilst in winter salinity explained 15% of the variance. Relationships between bacterial indicators/pathogens and physicochemical variables were inconsistent in sediments, no single indicator adequately described occurrence of all bacterial indicators/pathogens. However, important variables included grain size, porosity, clay content and concentrations of Zn, K, and Al. Sediments with greater organic matter content and lower porosity harbored a greater proportion of non-culturable bacteria (including dead cells and extracellular DNA) in winter. Here, we show the link between physicochemical variables and season which govern culturability of human enteric pathogens and FIOs. Therefore, knowledge of these factors is critical for accurate microbial risk assessment. Future water quality management strategies could be improved through monitoring sediment-associated bacteria and non-culturable bacteria. This could facilitate source apportionment of human enteric pathogens and FIOs and direct remedial action to improve water quality.

Published

2017

42. Microbial extracellular enzyme activity affects performance in a full-scale modified activated sludge process

Author

Francis, Hassard, Jeremy, Biddle, Richard, Harnett, and Tom, Stephenson

Subjects

Bioreactors, Sewage, Biofilms, Biomass, Wastewater, Waste Disposal, Fluid

Abstract

The rate-limiting step of wastewater treatment is the breakdown of polymers by extracellular enzyme activity (EEA). The efficacy of EEA on biomass from full scale conventional activated sludge (AS) and modified AS with bench scale and full scale rotating biofilm reactors (RBR) was compared. The maximum amino-peptidase EEA was 394 ± 34 μmolL

Published

2017

43. Microbiome and infectivity studies reveal complex polyspecies tree disease in Acute Oak Decline

Author

Francis Hassard, Kelly Scarlett, Jack Forster, Sandra Denman, Andrew R Griffiths, Emma Ransom-Jones, Susan E Kirk, Martin Broberg, Nathan Brown, Maciej Kaczmarek, James Doonan, Andrew Peace, Sarah Plummer, Peter N. Golyshin, John Kenny, and James E. McDonald

Subjects

0301 basic medicine, Agrilus, Agrilus biguttatus, ved/biology.organism_classification_rank.species, Virulence, Zoology, Disease, Microbiology, 03 medical and health sciences, Pathosystem, Necrosis, Quercus, Microbial ecology, Enterobacteriaceae, Animals, Microbiome, Ecology, Evolution, Behavior and Systematics, Phylogeny, Plant Diseases, biology, Environmental microbiology, ved/biology, Microbiota, Systems Biology, Infectious-disease diagnostics, biology.organism_classification, Coleoptera, 030104 developmental biology, Metagenome, Rahnella, Original Article, Tree health, Forest ecology, Molecular ecology, Transcriptome, Algorithms, Genome, Bacterial, Genome, Plant

Abstract

Decline-diseases are complex and becoming increasingly problematic to tree health globally. Acute Oak Decline (AOD) is characterized by necrotic stem lesions and galleries of the bark-boring beetle, Agrilus biguttatus, and represents a serious threat to oak. Although multiple novel bacterial species and Agrilus galleries are associated with AOD lesions, the causative agent(s) are unknown. The AOD pathosystem therefore provides an ideal model for a systems-based research approach to address our hypothesis that AOD lesions are caused by a polymicrobial complex. Here we show that three bacterial species, Brenneria goodwinii, Gibbsiella quercinecans and Rahnella victoriana, are consistently abundant in the lesion microbiome and possess virulence genes used by canonical phytopathogens that are expressed in AOD lesions. Individual and polyspecies inoculations on oak logs and trees demonstrated that B. goodwinii and G. quercinecans cause tissue necrosis and, in combination with A. biguttatus, produce the diagnostic symptoms of AOD. We have proved a polybacterial cause of AOD lesions, providing new insights into polymicrobial interactions and tree disease. This work presents a novel conceptual and methodological template for adapting Koch’s postulates to address the role of microbial communities in disease.

Published

2017

44. Evaluation of Molecular Methods for the Detection and Quantification of Pathogen-Derived Nucleic Acids in Sediment

Author

Shelagh K. Malham, Kata Farkas, James E. McDonald, Davey L. Jones, and Francis Hassard

Subjects

0301 basic medicine, Microbiology (medical), 030106 microbiology, norovirus, medicine.disease_cause, Microbiology, 03 medical and health sciences, medicine, nucleic acid extraction, Digital polymerase chain reaction, Original Research, Vibrio, Chromatography, biology, dPCR, Extraction (chemistry), Nucleic acid methods, qRT-PCR, biology.organism_classification, pathogen detection, Molecular biology, DNA extraction, Real-time polymerase chain reaction, sediment, 13. Climate action, Nucleic acid, Norovirus

Abstract

The accurate detection of pathogens in environmental matrices, such as sediment, is critical in understanding pathogen fate and behavior in the environment. In this study we assessed the usefulness of methods for the detection and quantification of Vibrio spp. and norovirus (NoV) nucleic acids in sediment. For bacteria, a commonly used direct method using hexadecyltrimethylammonium bromide (CTAB) and phenol-chloroform-isoamyl alcohol (PCI) extraction was optimized, whereas for NoV, direct and indirect (virus elution – concentration) methods were evaluated. For quantification, commercially available quantitative PCR (qPCR) and reverse transcription qPCR (RT-qPCR) kits were tested alongside a digital PCR (dPCR) approach. CTAB-based extraction combined with 16 h polyethylene glycol 6000 (PEG6000) precipitation was found to be suitable for the direct extraction of high abundance bacterial and viral nucleic acids. For the indirect extraction of viral RNA, beef extract-based elution followed by PEG6000 precipitation and extraction using the NucliSENS® MiniMag® Nucleic Acid Purification System and the PowerViral® Environmental RNA/DNA Isolation Kit and qRT-PCR resulted in 83 – 112% and 63 – 69% recoveries of NoV, respectively. dPCR resulted in lower viral recoveries (47% and 9%) and approx. four orders of magnitude lower Vibrio concentrations (3.6 – 4.6 log10 gc/100 g sediment) than was observed using qPCR. The use of internal controls during viral quantification revealed that the RT step was more affected by inhibitors than the amplification. The methods described here are suitable for the enumeration of viral and/or bacterial pathogens in sediment, however the use of internal controls to assess efficiency is recommended.

Published

2017

45. Performance of permeable media rotating reactors used for pretreatment of wastewaters

Author

Elise Cartmell, Jeremy R. Biddle, Francis Hassard, and Tom Stephenson

Subjects

High rate, Inert, Environmental Engineering, Bacteria, Nitrogen, Environmental engineering, High loading, Pulp and paper industry, Waste Disposal, Fluid, Ammonia, chemistry.chemical_compound, Bioreactors, chemistry, Wastewater, Biofilms, Bench scale, Loading rate, Oxidation-Reduction, Water Science and Technology

Abstract

The impact of organic loading rate (OLR) on carbonaceous materials and ammonia removal was assessed in bench scale rotating media biofilm reactors treating real wastewater. Media composition influences biofilm structure and therefore performance. Here, plastic mesh, reticulated coarse foam and fine foam media were operated concurrently at OLRs of 15, 35 and 60 g sCOD m(-2)d(-1) in three bench scale shaft mounted advanced reactor technology (SMART) reactors. The sCOD removal rate increased with loading from 6 to 25 g sCOD m(-2)d(-1) (P0.001). At 35 g BOD5m(-2)d(-1), more than double the arbitrary OLR limit of normal nitrifying conditions (15 g BOD5m(-2)d(-1)); the removal efficiency of NH(4)-N was 82 ± 5, 27 ± 19 and 39 ± 8% for the mesh, coarse foam and fine foam media, respectively. Increasing the OLR to 35 gm(-2)d(-1) decreased NH(4)-N removal efficiency to 38 ± 6, 21 ± 4 and 21 ± 6%, respectively. The mesh media achieved the highest stable NH(4)(+)-N removal rate of 6.5 ± 1.6 gm(-2)d(-1) at a sCOD loading of 35 g sCOD m(-2)d(-1). Viable bacterial numbers decreased with increasing OLR from 2 × 10(10)-4 × 10(9) cells per ml of biofilm from the low to high loading, suggesting an accumulation of inert non-viable biomass with higher OLR. Increasing the OLR in permeable media is of practical benefit for high rate carbonaceous materials and ammonia removal in the pretreatment of wastewater.

Published

2014

46. Rotating biological contactors for wastewater treatment - A review

Author

Tom Stephenson, Francis Hassard, Elise Cartmell, Bruce Jefferson, Sean Tyrrel, and Jeremy R. Biddle

Subjects

Environmental Engineering, Denitrification, Microbial fuel cell, Chemistry, General Chemical Engineering, Trickling filter, Biofilm, Environmental engineering, Biological wastewater treatment, Rotating biological contactor, Modelling, Enhanced biological phosphorus removal, Bioaugmentation, Wastewater, Environmental Chemistry, Sewage treatment, Nitrification, Biological nitrogen removal, Safety, Risk, Reliability and Quality

Abstract

Rotating biological contactors (RBCs) for wastewater treatment began in the 1970s. Removal of organic matter has been targeted within organic loading rates of up to 120 g m−2 d−1 with an optimum at around 15 g m−2 d−1 for combined BOD and ammonia removal. Full nitrification is achievable under appropriate process conditions with oxidation rates of up to 6 g m−2 d−1 reported for municipal wastewater. The RBC process has been adapted for denitrification with reported removal rates of up to 14 g m−2 d−1 with nitrogen rich wastewaters. Different media types can be used to improve organic/nitrogen loading rates through selecting for different bacterial groups. The RBC has been applied with only limited success for enhanced biological phosphorus removal and attained up to 70% total phosphorus removal. Compared to other biofilm processes, RBCs had 35% lower energy costs than trickling filters but higher demand than wetland systems. However, the land footprint for the same treatment is lower than these alternatives. The RBC process has been used for removal of priority pollutants such as pharmaceuticals and personal care products. The RBC system has been shown to eliminate 99% of faecal coliforms and the majority of other wastewater pathogens. Novel RBC reactors include systems for energy generation such as algae, methane production and microbial fuel cells for direct current generation. Issues such as scale up remain challenging for the future application of RBC technology and topics such as phosphorus removal and denitrification still require further research. High volumetric removal rate, solids retention, low footprint, hydraulic residence times are characteristics of RBCs. The RBC is therefore an ideal candidate for hybrid processes for upgrading works maximising efficiency of existing infrastructure and minimising energy consumption for nutrient removal. This review will provide a link between disciplines and discuss recent developments in RBC research and comparison of recent process designs are provided (Section 2 ). The microbial features of the RBC biofilm are highlighted (Section 3 ) and topics such as biological nitrogen removal and priority pollutant remediation are discussed (Sections 4 Biological nutrient removal in RBCs , 5 Priority pollutant remediation in RBCs ). Developments in kinetics and modelling are highlighted (Section 6 ) and future research themes are mentioned.

Published

2014

47. Diagnostic investigation of steroid estrogen removal by activated sludge at varying solids retention time

Author

Bruce Petrie, Ewan J. McAdam, Elise Cartmell, John N. Lester, Francis Hassard, and Tom Stephenson

Subjects

Environmental Engineering, Time Factors, medicine.drug_class, Estrone, Health, Toxicology and Mutagenesis, Pilot Projects, Ethinyl Estradiol, Waste Disposal, Fluid, Water Purification, chemistry.chemical_compound, Estradiol Congeners, medicine, Environmental Chemistry, Chromatography, Aqueous solution, Estradiol, Sewage, Estriol, Public Health, Environmental and Occupational Health, Sorption, General Medicine, General Chemistry, Biodegradation, Pollution, Activated sludge, Pilot plant, Biodegradation, Environmental, chemistry, England, Estrogen, Water Pollutants, Chemical

Abstract

The impact of solids retention time (SRT) on estrone (E1), 17β-estradiol (E2), estriol (E3) and 17α-ethinylestradiol (EE2) removal in an activated sludge plant (ASP) was examined using a pilot plant to closely control operation. Ex situ analytical methods were simultaneously used to enable discrimination of the dominant mechanisms governing estrogen removal following transitions in SRT from short (3 d) to medium (10 d) and long (27 d) SRTs which broadly represent those encountered at full-scale. Total estrogen (∑ EST , i.e., sum of E1, E2, E3 and EE2) removals which account for aqueous and particulate concentrations were 70 ± 8, 95 ± 1 and 93 ± 2% at 3, 10 and 27 d SRTs respectively. The improved removal observed following an SRT increase from 3 to 10 d was attributable to the augmented biodegradation of the natural estrogens E1 and E2. Interestingly, estrogen biodegradation per bacterial cell increased with SRT. These were 499, 1361 and 1750 ng 10 12 viable cells −1 d −1 . This indicated an improved efficiency of the same group or the development of a more responsive group of bacteria. In this study no improvement in absolute ∑ EST removal was observed in the ASP when SRT increased from 10 to 27 d. However, batch studies identified an augmented biomass sorption capacity for the more hydrophobic estrogens E2 and EE2 at 27 d, equivalent to an order of magnitude. The lack of influence on estrogen removal during pilot plant operation can be ascribed to their distribution within activated sludge being under equilibrium. Consequently, lower wastage of excess sludge inherent of long SRT operation counteracts any improvement in sorption.

Published

2013