Validity of spatial models of arsenic concentrations in private well water

Meliker, Jaymie R.; AvRuskin, Gillian A.; Slotnick, Melissa J.; Goovaerts, Pierre; Schottenfeld, David; Jacquez, Geoffrey M.; Nriagu, Jerome O.

doi:10.1016/j.envres.2007.09.001

Cited by 32 publications

(33 citation statements)

References 36 publications

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“…Recent studies suggest that arsenic concentrations in groundwater may be spatially positively correlated. 19,21,44 We developed spatial statistical models that borrow information from nearby wells to estimate arsenic levels in nondetect and nonsampled wells. Spatial modeling also helps identify spatial patterns in the determinants, which affect not only arsenic levels in a well but also levels in neighboring wells.…”

Section: Methodsmentioning

confidence: 99%

Spatial Modeling for Groundwater Arsenic Levels in North Carolina

Kim

Miranda

Tootoo

et al. 2011

Environ. Sci. Technol.

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To examine environmental and geologic determinants of arsenic in groundwater, detailed geologic data were integrated with well water arsenic concentration data and well construction data for 471 private wells in Orange County, NC, via a geographic information system. For the statistical analysis, the geologic units were simplified into four generalized categories based on rock type and interpreted mode of deposition/emplacement. The geologic transitions from rocks of a primary pyroclastic origin to rocks of volcaniclastic sedimentary origin were designated as polylines. The data were fitted to a left-censored regression model to identify key determinants of arsenic levels in groundwater. A Bayesian spatial random effects model was then developed to capture any spatial patterns in groundwater arsenic residuals into model estimation. Statistical model results indicate (1) wells close to a transition zone or fault are more likely to contain detectible arsenic; (2) welded tuffs and hydrothermal quartz bodies are associated with relatively higher groundwater arsenic concentrations and even higher for those proximal to a pluton; and (3) wells of greater depth are more likely to contain elevated arsenic. This modeling effort informs policy intervention by creating three-dimensional maps of predicted arsenic levels in groundwater for any location and depth in the area.

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Section: Methodsmentioning

confidence: 99%

Spatial Modeling for Groundwater Arsenic Levels in North Carolina

Kim

Miranda

Tootoo

et al. 2011

Environ. Sci. Technol.

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“…The geostatistical model predicts arsenic concentration for 500 × 500 m 2 pixels. This model was validated using a separate test dataset of 371 well water measurements, and showed a Pearson’s correlation r = 0.61; predicting above or below a 10 µg/L threshold resulted in sensitivity = 0.62, specificity = 0.80, and 75% agreement [31]. …”

Section: Methodsmentioning

confidence: 99%

Lifetime exposure to arsenic in drinking water and bladder cancer: a population-based case–control study in Michigan, USA

Meliker

Slotnick

AvRuskin

et al. 2010

Cancer Causes Control

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Objective Arsenic in drinking water has been linked with the risk of urinary bladder cancer, but the dose–response relationships for arsenic exposures below 100 µg/L remain equivocal. We conducted a population-based case–control study in southeastern Michigan, USA, where approximately 230,000 people were exposed to arsenic concentrations between 10 and 100 µg/L. Methods This study included 411 bladder cancer cases diagnosed between 2000 and 2004, and 566 controls recruited during the same period. Individual lifetime exposure profiles were reconstructed, and residential water source histories, water consumption practices, and water arsenic measurements or modeled estimates were determined at all residences. Arsenic exposure was estimated for 99% of participants’ person-years. Results Overall, an increase in bladder cancer risk was not found for time-weighted average lifetime arsenic exposure >10 µg/L when compared with a reference group exposed to <1 µg/L (odds ratio (OR) = 1.10; 95% confidence interval (CI): 0.65, 1.86). Among ever-smokers, risks from arsenic exposure >10 µg/L were similarly not elevated when compared to the reference group (OR = 0.94; 95% CI: 0.50, 1.78). Conclusions We did not find persuasive evidence of an association between low-level arsenic exposure and bladder cancer. Selecting the appropriate exposure metric needs to be thoughtfully considered when investigating risk from low-level arsenic exposure.

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“…Before machine learning algorithms can be executed in the manner that will best explain the phenomena in question, data must first be appropriately prepared (Pyle 1999). Machine learning algorithms such as k-nearest neighbor have been proposed to solve environmental problems from soil water retention (Nemes et al 2008), to arsenic in well-water (Meliker et al 2008), to forest mapping (McRoberts et al 2007). Other popular techniques employed in data-driven modeling efforts are illustrated in the context of river basin management (Solomatine & Ostfeld 2008).…”

Section: Hypoxic Conditions Were First Observed In Corpusmentioning

confidence: 99%

Understanding and forecasting hypoxia using machine learning algorithms

Coopersmith

Minsker

Montagna

2010

Journal of Hydroinformatics

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This study's primary objective lies in short-term forecasting of where and when hypoxia may transpire to enable observing its effects in real time, focusing on a case study in Corpus Christi Bay (Texas). Dissolved oxygen levels in this bay can be characterized by three temporal trends (daily, seasonal, and long-term). To predict hypoxic events, these three mathematical trends are isolated and extracted to obtain unbiased forecasts using a sequential normalization approach.Next, machine learning algorithms are constructed employing the continuous, normalized values from a variety of sensor locations. By including latitude and longitude coordinates as additional variables, a spatial depiction of hypoxic conditions can be illustrated effectively, allowing for more efficient summer data collection and more accurate, near-real-time projections. Using k-nearest neighbor and regression tree algorithms, approximate probabilities of observing hypoxia the following day were calculated, and estimates of dissolved oxygen levels were also computed.During periods in which hypoxia was observed, forecast probabilities of hypoxia exceeded 80%.Conversely, during periods in which no hypoxia was observed, the model's estimate remained below 20%. These results indicate that the modeling approach produces reasonable forecasts for this case study.

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Validity of spatial models of arsenic concentrations in private well water

Cited by 32 publications

References 36 publications

Spatial Modeling for Groundwater Arsenic Levels in North Carolina

Spatial Modeling for Groundwater Arsenic Levels in North Carolina

Lifetime exposure to arsenic in drinking water and bladder cancer: a population-based case–control study in Michigan, USA

Understanding and forecasting hypoxia using machine learning algorithms

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