Your search keyword '"Crank K"' showing total 11 results

1. Contribution of SARS-CoV-2 RNA shedding routes to RNA loads in wastewater

Author

Crank, K., primary, Chen, W., additional, Bivins, A., additional, Lowry, S., additional, and Bibby, K., additional

Published

2022

2. Communicating Pediatric Airway and Tracheostomy Status with Emergency Medical Services- A Quality Improvement Effort

Author

Washam, M., primary, Crank, K., additional, Gneuhs, M., additional, Hart, C., additional, and Benscoter, D., additional

Published

2019

3. Early Introductions of Candida auris Detected by Wastewater Surveillance, Utah, USA, 2022-2023.

Author

Chavez J, Crank K, Barber C, Gerrity D, Iverson T, Mongillo J, Weil A, Rider L, Lacross N, Oakeson K, and Rossi A

Subjects

Humans, Utah epidemiology, History, 21st Century, Wastewater-Based Epidemiological Monitoring, Whole Genome Sequencing, Candida genetics, Candida isolation & purification, Candida classification, Candidiasis epidemiology, Candidiasis microbiology, Candidiasis transmission, Candidiasis diagnosis, Wastewater microbiology, Candida auris genetics

Abstract

Candida auris is considered a nosocomial pathogen of high concern and is currently spreading across the United States. Infection control measures for C. auris focus mainly on healthcare facilities, yet transmission levels may already be significant in the community before outbreaks are detected in healthcare settings. Wastewater-based epidemiology (culture, quantitative PCR, and whole-genome sequencing) can potentially gauge pathogen transmission in the general population and lead to early detection of C. auris before it is detected in clinical cases. To learn more about the sensitivity and limitations of wastewater-based surveillance, we used wastewater-based methods to detect C. auris in a southern Utah jurisdiction with no known clinical cases before and after the documented transfer of colonized patients from bordering Nevada. Our study illustrates the potential of wastewater-based surveillance for being sufficiently sensitive to detect C. auris transmission during the early stages of introduction into a community.

Published

2024

4. A framework for integrating wastewater-based epidemiology and public health.

Author

Brosky H, Prasek SM, Innes GK, Pepper IL, Miranda J, Brierley PE, Slinski SL, Polashenski L, Betancourt WQ, Gronbach K, Gomez D, Neupane R, Johnson J, Weiss J, Yaglom HD, Engelthaler DM, Hepp CM, Crank K, Gerrity D, Stewart JR, and Schmitz BW

Subjects

Humans, Arizona epidemiology, Wastewater-Based Epidemiological Monitoring, SARS-CoV-2, Public Health, COVID-19 epidemiology, COVID-19 prevention & control, Wastewater

Abstract

Wastewater-based epidemiology (WBE) is an environmental approach to monitor community health through the analysis of sewage. The COVID-19 pandemic catalyzed scientists and public health professionals to revisit WBE as a tool to optimize resource allocation to mitigate disease spread and prevent outbreaks. Some studies have highlighted the value of WBE programs that coordinate with public health professionals; however, the details necessary for implementation are not well-characterized. To respond to this knowledge gap, this article documents the framework of a successful WBE program in Arizona, titled Wastewater Analysis for Tactical Epidemiological Response Systems (WATERS), detailing the developed structure and methods of communication that enabled public health preparedness and response actions. This communication illustrates how program operations were employed to reduce outbreak severity. The structure outlined here is customizable and may guide other programs in the implementation of WBE as a public health tool., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2024 Brosky, Prasek, Innes, Pepper, Miranda, Brierley, Slinski, Polashenski, Betancourt, Gronbach, Gomez, Neupane, Johnson, Weiss, Yaglom, Engelthaler, Hepp, Crank, Gerrity, Stewart and Schmitz.)

Published

2024

5. Quantitative Microbial Risk Assessment Framework Incorporating Water Ages with Legionella pneumophila Growth Rates.

Author

Clements E, Crank K, Nerenberg R, Atkinson A, Gerrity D, and Hannoun D

Subjects

Water Supply, Water Microbiology, Sanitary Engineering, Risk Assessment, Legionella pneumophila, Legionella, Drinking Water

Abstract

Water age in drinking water systems is often used as a proxy for water quality but is rarely used as a direct input in assessing microbial risk. This study directly linked water ages in a premise plumbing system to concentrations of Legionella pneumophila via a growth model. In turn, the L. pneumophila concentrations were used for a quantitative microbial risk assessment to calculate the associated probabilities of infection ( P inf ) and clinically severe illness ( P csi ) due to showering. Risk reductions achieved by purging devices, which reduce water age, were also quantified. The median annual P inf exceeded the commonly used 1 in 10,000 (10 -4 ) risk benchmark in all scenarios, but the median annual P csi was always 1-3 orders of magnitude below 10 -4 . The median annual P csi was lower in homes with two occupants (4.7 × 10 -7 ) than with one occupant (7.5 × 10 -7 ) due to more frequent use of water fixtures, which reduced water ages. The median annual P csi for homes with one occupant was reduced by 39-43% with scheduled purging 1-2 times per day. Smart purging devices, which purge only after a certain period of nonuse, maintained these lower annual P csi values while reducing additional water consumption by 45-62%.

Published

2024

6. Wastewater surveillance of high risk substances in Southern Nevada: Sucralose normalization to translate data for potential public health action.

Author

Gerrity D, Crank K, Oh EC, Quinones O, Trenholm RA, and Vanderford BJ

Subjects

Humans, United States, Nevada, Pandemics, Public Health, Wastewater-Based Epidemiological Monitoring, Wastewater

Abstract

The COVID-19 pandemic highlighted the value of wastewater surveillance in providing unbiased assessments of incidence/prevalence for infectious disease targets, ultimately leading to the development of local, state, and national programs across the United States. To address the growing epidemic of drug abuse, there have been calls to extend these programs to high risk substances (HRS) and metabolites, while leveraging the experience gained during the pandemic and from ongoing efforts in other countries. This study further advances the science of wastewater surveillance for HRS by (1) highlighting analytical and sewer transport considerations, (2) proposing sucralose normalization to adjust for varying human urine/fecal load and confounded population estimates (e.g., high tourism areas), and (3) characterizing temporal and geographic trends in HRS use. This one-year study across eight sewersheds in Southern Nevada (208 total samples) monitored concentrations of 17 pharmaceuticals and personal care products (PPCPs) and 22 HRS and metabolites, including natural, semi-synthetic, and synthetic opioids. The data indicated a ∼200 % increase in heroin and methamphetamine use since 2010, a stark increase in fentanyl consumption beginning in October 2022, and statistically significant differences in HRS consumption patterns between sewersheds and on certain dates. Notably, the latter outcome highlights the potential for wastewater surveillance data to be strategically translated into public health action to reduce and/or more rapidly respond to overdoses., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2023. Published by Elsevier B.V.)

Published

2024

7. Correspondence on "The Environmental Microbiology Minimum Information (EMMI) Guidelines: qPCR and dPCR Quality and Reporting for Environmental Microbiology".

Author

Crank K, Papp K, Barber C, Wang P, Bivins A, and Gerrity D

Published

2023

8. Quantitative risk assessment of COVID-19 aerosol transmission indoors: a mechanistic stochastic web application.

Author

Rocha-Melogno L, Crank K, Bergin MH, Gray GC, Bibby K, and Deshusses MA

Subjects

Humans, SARS-CoV-2, Pandemics, Respiratory Aerosols and Droplets, Risk Assessment, COVID-19 epidemiology

Abstract

An increasing body of literature suggests that aerosol inhalation plays a primary role in COVID-19 transmission, particularly in indoor settings. Mechanistic stochastic models can help public health professionals, engineers, and space planners understand the risk of aerosol transmission of COVID-19 to mitigate it. We developed such model and a user-friendly web application to meet the need of accessible risk assessment tools during the COVID-19 pandemic. We built our model based on the Wells-Riley model of respiratory disease transmission, using quanta emission rates obtained from COVID-19 outbreak investigations. In this report, three modelled scenarios were evaluated and compared to epidemiological studies looking at similar settings: classrooms, weddings, and heavy exercise sessions. We found that the risk of long-range aerosol transmission increased 309-332% when people were not wearing masks, and 424-488% when the room was poorly ventilated in addition to no masks being worn across the scenarios. Also, the risk of transmission could be reduced by ∼40-60% with ventilation rates of 5 ACH for 1-4 h exposure events, and ∼70% with ventilation rates of 10 ACH for 4 h exposure events. Relative humidity reduced the risk of infection (inducing viral inactivation) by a maximum of ∼40% in a 4 h exposure event at 70% RH compared to a dryer indoor environment with 25% RH. Our web application has been used by more than 1000 people in 52 countries as of September 1st, 2021. Future work is needed to obtain SARS-CoV-2 dose-response functions for more accurate risk estimates.

Published

2023

9. Community-Scale Wastewater Surveillance of Candida auris during an Ongoing Outbreak in Southern Nevada.

Author

Barber C, Crank K, Papp K, Innes GK, Schmitz BW, Chavez J, Rossi A, and Gerrity D

Subjects

Humans, Candida auris, Wastewater, Wastewater-Based Epidemiological Monitoring, Nevada epidemiology, Disease Outbreaks, Candida genetics, Candidiasis diagnosis, Candidiasis epidemiology, Candidiasis microbiology

Abstract

Candida auris is an opportunistic fungal pathogen and an emerging global public health threat, given its high mortality among infected individuals, antifungal resistance, and persistence in healthcare environments. This study explored the applicability of wastewater surveillance for C. auris in a metropolitan area with reported outbreaks across multiple healthcare facilities. Influent or primary effluent samples were collected over 10 weeks from seven sewersheds in Southern Nevada. Pelleted solids were analyzed using an adapted quantitative polymerase chain reaction (qPCR) assay targeting the ITS2 region of the C. auris genome. Positive detection was observed in 72 of 91 samples (79%), with higher detection frequencies in sewersheds serving healthcare facilities involved in the outbreak (94 vs 20% sample positivity). Influent wastewater concentrations ranged from 2.8 to 5.7 log 10 gene copies per liter (gc/L), and primary clarification achieved an average log reduction value (LRV) of 1.24 ± 0.34. Presumptive negative surface water and wastewater controls were non-detect. These results demonstrate that wastewater surveillance may assist in tracking the spread of C. auris and serve as an early warning tool for public health action. These findings provide the foundation for future application of wastewater-based epidemiology (WBE) to community- or facility-level surveillance of C. auris and other high consequence, healthcare-associated infectious agents.

Published

2023

10. Influences of pH and substrate supply on the ratio of iron to sulfate reduction.

Author

Paper JM, Flynn TM, Boyanov MI, Kemner KM, Haller BR, Crank K, Lower A, Jin Q, and Kirk MF

Subjects

Hydrogen-Ion Concentration, Oxidation-Reduction, Sulfates, Groundwater, Iron

Abstract

Iron reduction and sulfate reduction often occur simultaneously in anoxic systems, and where that is the case, the molar ratio between the reactions (i.e., Fe/SO 4 2- reduced) influences their impact on water quality and carbon storage. Previous research has shown that pH and the supply of electron donors and acceptors affect that ratio, but it is unclear how their influences compare and affect one another. This study examines impacts of pH and the supply of acetate, sulfate, and goethite on the ratio of iron to sulfate reduction in semi-continuous sediment bioreactors. We examined which parameter had the greatest impact on that ratio and whether the parameter influences depended on the state of each other. Results show that pH had a greater influence than acetate supply on the ratio of iron to sulfate reduction, and that the impact of acetate supply on the ratio depended on pH. In acidic reactors (pH 6.0 media), the ratio of iron to sulfate reduction decreased from 3:1 to 2:1 as acetate supply increased (0-1 mM). In alkaline reactors (pH 7.5 media), iron and sulfate were reduced in equal proportions, regardless of acetate supply. Secondly, a comparison of experiments with and without sulfate shows that the extent of iron reduction was greater if sulfate reduction was occurring and that the effect was larger in alkaline reactors than acidic reactors. Thus, the influence of sulfate supply on iron reduction extent also depended on pH and suggests that iron reduction grows more dependent on sulfate reduction as pH increases. Our results compare well to trends in groundwater geochemistry and provide further evidence that pH is a major control on iron and sulfate reduction in systems with crystalline (oxyhydr)oxides. pH not only affects the ratio between the reactions but also the influences of other parameters on that ratio., (Published 2021. This article is a US Government work and is in the public domain in the USA.)

Published

2021

11. CrAssphage abundance and correlation with molecular viral markers in Italian wastewater.

Author

Crank K, Li X, North D, Ferraro GB, Iaconelli M, Mancini P, La Rosa G, and Bibby K

Subjects

Biomarkers, Environmental Monitoring, Feces, Humans, Italy, Sewage, Water Microbiology, Wastewater, Water Pollution analysis

Abstract

Current fecal indicators for environmental health monitoring are primarily based on fecal indicator bacteria (FIB) which do not accurately represent viral pathogens. There is a need for highly abundant, human-associated viral fecal indicators to represent viral pathogens in sewage-contaminated water. In the present study, we evaluate the abundance of the emerging viral fecal indicator crAssphage in 156 Italian wastewater samples collected between 2014 and 2018. Samples were collected using two separate viral concentration methods, glycine-CF and PEG-dextran and qPCR assays were run for crAssphage (CPQ56) and Human Polyomavirus (HPyV) and endpoint PCR assays were run for Human Bocavirus (HBoc) and Hepatitis E Virus (HepE). CrAssphage was detected in 96% of samples and no statistically significant difference was observed in crAssphage abundance between concentration methods (p = 0.39). CrAssphage concentrations also did not correlate with location (latitude) or size (load and capacity) of the wastewater treatment plant. HPyV detection rates with the glycine-CF and PEG-dextran methods were 64% and 100%, respectively, and the concentrations of HPyV were statistically significantly influenced by the concentration method (p < 0.0001). CrAssphage was measured at significantly higher concentrations than HPyV for both concentration methods (p < 0.0001). The observed concentration ranges were 3.84-7.29 log 10 GC/100 mL for crAssphage and 3.45-5.17 log 10 GC/100 mL for HPyV. There was a strong positive correlation between crAssphage and HPyV abundance for both concentration methods; however, the slope of the correlation depended on the concentration method. CrAssphage presence correlated with the presence of HBoc in samples concentrated with glycine-CF, but did not correlate with the presence of HBoc concentrated with the PEG-dextran method or with the presence of HepE. Overall, these results demonstrate that crAssphage is an abundant viral fecal indicator in wastewater with statistically significant correlation with human viral pathogens (e.g., HPyV) and viral concentration methods influence the interpretation of fecal viral indicator detection., Competing Interests: Declaration of competing interest The authors declare the following financial interests/personal relationships which may be considered as potential competing interests: K.B. is a co-inventor on a US patent application entitled “Cross-Assembly Phage DNA Sequences, Primers and Probes for PCR-based Identification of Human Fecal Pollution Sources” (Application Number: 62/386,532). United States universities and non-profit researchers interested in using this technology must obtain a research license from the US EPA. To apply for a research license, please request additional information from ftta@epa.gov. The authors declare no other conflict of interest., (Copyright © 2020 Elsevier Ltd. All rights reserved.)

Published

2020