Your search keyword '"Alan M. Piggot"' showing total 5 results

1. Impacts of a Changing Earth on Microbial Dynamics and Human Health Risks in the Continuum between Beach Water and Sand

Author

Christopher D. Heaney, Zachery R. Staley, Alexandria B. Boehm, Luísa Jordão, Helena M. Solo-Gabriele, João Brandão, Christopher Staley, Warish Ahmed, Brian D. Badgley, Michael J. Sadowsky, Jean Pierre Nshimyimana, Jay M. Fleisher, Valerie J. Harwood, Laura J. Vogel, Lindsay Avolio, Asli Aslan, Clare Robinson, James S. Klaus, Erin M. Symonds, Julie L. Kinzelman, Kevan M. Yamahara, Päivi Meriläinen, Gregory T. Kleinheinz, Alan M. Piggot, Chelsea J. Weiskerger, Thomas A. Edge, Tarja Pitkänen, Mantha S. Phanikumar, and Richard L. Whitman

Subjects

0106 biological sciences, 0208 environmental biotechnology, 02 engineering and technology, 010501 environmental sciences, 01 natural sciences, Feces, Sand, Models, Water Quality, Waste Management and Disposal, Water Science and Technology, education.field_of_study, Ecology, Ecological Modeling, Cumulative effects, Pollution, Água e Solo, 6. Clean water, Habitat, Pathogens, Water Microbiology, Swash, Environmental Monitoring, Environmental Engineering, Climate Change, Population, Climate change, Indicator bacteria, Bathing Beaches, Agentes Microbianos e Ambiente, Extreme weather, FIB, Urbanization, Humans, Population growth, Seawater, Parasites, 14. Life underwater, education, 0105 earth and related environmental sciences, Civil and Structural Engineering, 010604 marine biology & hydrobiology, Water Pollution, fungi, Fungi, other, Water, Global change, 15. Life on land, 020801 environmental engineering, 13. Climate action, Environmental science, Water quality

Abstract

Humans may be exposed to microbial pathogens at recreational beaches via environmental sources, such as water, sand, and aerosols. Although infectious disease risk from exposure to waterborne pathogens has been an active area of research for decades, sand is a relatively unexplored reservoir of pathogens and fecal indicator bacteria (FIB). Beach sand and water habitats provide unique advantages and challenges to pathogen introduction, growth, and persistence, as well as continuous exchange between habitats. Models of FIB and pathogen fate and transport in sandy beach habitats can help predict the risk of infectious disease from recreational water use, but filling knowledge gaps such as decay rates and potential for microbial growth in beach habitats is necessary for accurate modeling. Climatic variability, whether natural or anthropogenically-induced, adds complexity to predictive modeling, but may increase human exposure to waterborne pathogens via extreme weather events, warming of water bodies and sea level rise in many regions. The popularity of human recreational beach activities, combined with predicted climate change scenarios, could amplify the risk of human exposure to pathogens and related illnesses. Other global change trends such as increased population growth and urbanization are expected to exacerbate contamination events and the predicted impacts of increasing levels of waterborne pathogens on human health. Such changes will alter microbial population dynamics in beach habitats, and will consequently affect the assumptions and relationships used in population models and quantitative microbial risk assessment (QMRA). Here, we discuss the literature on microbial population and transport dynamics in sand-water continuum habitats at beaches, how these dynamics can be modeled, and how climate change and other anthropogenic influences (e.g., land use, urbanization) should be considered when using and developing more holistic, beachshed-based models.

Published

2019

2. Effects of full-scale beach renovation on fecal indicator levels in shoreline sand and water

Author

James S. Klaus, Rafael J. Hernandez, Alan M. Piggot, Zhixuan Feng, Yasiel Hernandez, Ad Reniers, Nasly H. Jimenez, and Helena M. Solo-Gabriele

Subjects

Hydrology, Environmental Engineering, Ecological Modeling, Stormwater, Colony Count, Microbial, Sediment, Indicator bacteria, Pollution, Article, Coliform bacteria, Fecal coliform, Feces, Biofilms, Indicator species, Environmental science, Water quality, Water Microbiology, Surface runoff, Waste Management and Disposal, Enterococcus, Water Science and Technology, Civil and Structural Engineering

Abstract

Recolonization of enterococci, at a non-point source beach known to contain high background levels of bacteria, was studied after a full-scale beach renovation project. The renovation involved importation of new exogenous sand, in addition to infrastructure improvements. The study's objectives were to document changes in sand and water quality and to evaluate the relative contribution of different renovation activities towards these changes. These objectives were addressed: by measuring enterococci levels in the sand and fecal indicator bacteria levels (enterococci and fecal coliform) in the water, by documenting sediment characteristics (mineralogy and biofilm levels), and by estimating changes in observable enterococci loads. Analysis of enterococci levels on surface sand and within sediment depth cores were significantly higher prior to beach renovation (6.3 to 72 CFU/g for each sampling day) when compared to levels during and after beach renovation (0.8 CFU/g to 12 CFU/g) (p

Published

2014

3. Potential Impacts of PCBs on Sediment Microbiomes in a Tropical Marine Environment

Author

Hee Sook Kang, Elsayed M. Zahran, Ad Reniers, Naresh Kumar, Helena M. Solo-Gabriele, Adolfo Fernandez, Vassiliki H. Kourafalou, Sapna K. Deo, Leonidas G. Bachas, Sylvia Daunert, Michal Toborek, James S. Klaus, Piero R. Gardinali, and Alan M. Piggot

Subjects

0301 basic medicine, polychlorinated biphenyls, microbiome, Intertidal zone, Ocean Engineering, 010501 environmental sciences, 01 natural sciences, lcsh:Oceanography, 03 medical and health sciences, lcsh:VM1-989, PCBs, lcsh:GC1-1581, Relative species abundance, 0105 earth and related environmental sciences, Water Science and Technology, Civil and Structural Engineering, Total organic carbon, Shore, geography, geography.geographical_feature_category, lcsh:Naval architecture. Shipbuilding. Marine engineering, food and beverages, Sediment, hydrodynamics, transport, marine sediments, 030104 developmental biology, Oceanography, Microbial population biology, Tropical marine climate, Environmental science, Bay

Abstract

Within the tropical marine study site of Guánica Bay, Puerto Rico, polychlorinated biphenyls (PCBs) are subjected to coastal and oceanic currents coupled with marine microbial and geochemical processes. To evaluate these processes a hydrodynamic model was developed to simulate the transport of PCBs within nearshore and offshore marine areas of Guánica Bay. Material transport and circulation information from the model were matched with measurements from samples collected from within the bay. These samples, consisting of both intertidal and submerged sediments, were analyzed for physical characteristics (organic carbon, grain size, and mineralogy), microbial characteristics (target bacteria levels and microbial community analyses), presence of PCBs, and PCB-degrading enzymes. Results show that the bay geometry and bathymetry limit the mixing of the extremely high levels of PCBs observed in the eastern portion of the bay. Bay bottom sediments showed the highest levels of PCBs and these sediments were characterized by high organic carbon content and finer grain size. Detectable levels of PCBs were also observed within sediments found along the shore. Microbes from the bay bottom sediments showed a greater relative abundance of microbes from the Chloroflexi, phylum with close phylogenetic associations with known anaerobic PCB-degrading organisms. Based on quantitative PCR measurement of the biphenyl dioxygenase gene, the intertidal sediments showed the greatest potential for aerobic PCB degradation. These results elucidate particular mechanisms of PCB’s fate and transport in coastal, tropical marine environments.

Published

2016

4. Spatial and temporal variation in indicator microbe sampling is influential in beach management decisions

Author

Lora E. Fleming, Brian K. Haus, Amber A. Enns, Michael E. Schoor, Norma C. Salazar, Sumbul Q. Khan, Yifan Zhang, Maribeth L. Gidley, Alan M. Piggot, Nasly H. Jimenez, Noha Abdel-Mottaleb, Amir M. Abdelzaher, Helena M. Solo-Gabriele, Alexis Brown, Laura J. Vogel, Lisa R. W. Plano, Ad Reniers, Adrienne S. Dameron, Zhixuan Feng, James S. Klaus, Samir M. Elmir, and Matthew C. Phillips

Subjects

Geologic Sediments, Staphylococcus aureus, Environmental Engineering, Time Factors, Rain, Intertidal zone, Population density, Bathing Beaches, Article, Waterline, symbols.namesake, Species Specificity, Water Movements, Seawater, Waste Management and Disposal, Water Science and Technology, Civil and Structural Engineering, Hydrology, Population Density, biology, Ecology, Ecological Modeling, Sediment, Sampling (statistics), biology.organism_classification, Pollution, Enterococcus, symbols, Public Health Practice, Environmental science, Spatial variability, Sample collection

Abstract

Fecal indicator microbes, such as enterococci, are often used to assess potential health risks caused by pathogens at recreational beaches. Microbe levels often vary based on collection time and sampling location. The primary goal of this study was to assess how spatial and temporal variations in sample collection, which are driven by environmental parameters, impact enterococci measurements and beach management decisions. A secondary goal was to assess whether enterococci levels can be predictive of the presence of Staphylococcus aureus, a skin pathogen. Over a ten-day period, hydrometeorologic data, hydrodynamic data, bather densities, enterococci levels, and S. aureus levels including methicillin-resistant S. aureus (MRSA) were measured in both water and sand. Samples were collected hourly for both water and sediment at knee-depth, and every 6 h for water at waist-depth, supratidal sand, intertidal sand, and waterline sand. Results showed that solar radiation, tides, and rainfall events were major environmental factors that impacted enterococci levels. S. aureus levels were associated with bathing load, but did not correlate with enterococci levels or any other measured parameters. The results imply that frequencies of advisories depend heavily upon sample collection policies due to spatial and temporal variation of enterococci levels in response to environmental parameters. Thus, sampling at different times of the day and at different depths can significantly impact beach management decisions. Additionally, the lack of correlation between S. aureus and enterococci suggests that use of fecal indicators may not accurately assess risk for some pathogens.

Published

2011

5. Relationships between sand and water quality at recreational beaches

Author

Helena M. Solo-Gabriele, James S. Klaus, Matthew C. Phillips, Alan M. Piggot, and Yifan Zhang

Subjects

Environmental Engineering, Intertidal zone, Average level, Bathing Beaches, Article, Water Quality, Recreational water quality, parasitic diseases, Water Movements, Humans, Waste Management and Disposal, Recreation, Soil Microbiology, Water Science and Technology, Civil and Structural Engineering, Hydrology, Geography, Ecological Modeling, fungi, Sediment, biochemical phenomena, metabolism, and nutrition, Silicon Dioxide, Pollution, United States, Florida, Environmental science, United States Dept. of Health and Human Services, Water quality, Water Microbiology, human activities, geographic locations, Enterococcus

Abstract

Enterococci are used to assess the risk of negative human health impacts from recreational waters. Studies have shown sustained populations of enterococci within sediments of beaches but comprehensive surveys of multiple tidal zones on beaches in a regional area and their relationship to beach management decisions are limited. We sampled three tidal zones on eight South Florida beaches in Miami-Dade and Broward counties and found that enterococci were ubiquitous within South Florida beach sands although their levels varied greatly both among the beaches and between the supratidal, intertidal and subtidal zones. The supratidal sands consistently had significantly higher (p < 0.003) levels of enterococci (average 40 CFU/g dry sand) than the other two zones. Levels of enterococci within the subtidal sand correlated with the average level of enterococci in the water (CFU/100mL) for the season during which samples were collected (r(s) = 0.73). The average sand enterococci content over all the zones on each beach correlated with the average water enterococci levels of the year prior to sand samplings (r(s) = 0.64) as well as the average water enterococci levels for the month after sand samplings (r(s) = 0.54). Results indicate a connection between levels of enterococci in beach water and sands throughout South Florida's beaches and suggest that the sands are one of the predominant reservoirs of enterococci impacting beach water quality. As a result, beaches with lower levels of enterococci in the sand had fewer exceedences relative to beaches with higher levels of sand enterococci. More research should focus on evaluating beach sand quality as a means to predict and regulate marine recreational water quality.

Published

2011