Modelling spatial concordance between Rocky Mountain spotted fever disease incidence and habitat probability of its vector Dermacentor variabilis (American dog tick)

Atkinson, Samuel F.; Sarkar, Sahotra; Avina, Aldo; Schuermann, Jim A.; Williamson, Phillip

doi:10.4081/gh.2012.108

Cited by 18 publications

(13 citation statements)

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“…distribution are poorly understood, as is their range of host species [44, 81]. Yet, it has previously been found that spotted fever incidence in humans, caused by R. ricketsii , is highest in suboptimal tick habitats [82]. This is in line with our findings and suggests that Rickettsia spp.…”

Section: Discussionsupporting

confidence: 90%

Human pathogen co-occurrence in Ixodes ricinus ticks: effects of landscape topography, climatic factors and microbiota interactions

Aivelo

Norberg

Tschirren

2019

Preprint

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Section: Discussionsupporting

confidence: 90%

Human pathogen co-occurrence in Ixodes ricinus ticks: effects of landscape topography, climatic factors and microbiota interactions

Aivelo

Norberg

Tschirren

2019

Preprint

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“…Geographically weighted regression (GWR) can be used for these two considerations and can often produce improved models that enable better spatial inference and prediction. Recent studies have applied GWR modeling to drug-resistant tuberculosis versus risk factors (Liu et al, 2011); environmental factors versus typhoid fever (Dewan et al, 2013); local climate and population distribution versus hand, foot, and mouth disease (Hu et al, 2012); and environmental factors and tick-borne disease (Atkinson et al, 2012; Atkinson et al, 2014; Wimberly, Baer & Yabsley, 2008; Wimberly et al, 2008), all showing that predictor variables varied spatially across large geographic regions, implying that the results for such studies may be improved using GWR.…”

Section: Introductionmentioning

confidence: 99%

A comparison of least squares regression and geographically weighted regression modeling of West Nile virus risk based on environmental parameters

Kala

Tiwari

Mikler

et al. 2017

PeerJ

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BackgroundThe primary aim of the study reported here was to determine the effectiveness of utilizing local spatial variations in environmental data to uncover the statistical relationships between West Nile Virus (WNV) risk and environmental factors. Because least squares regression methods do not account for spatial autocorrelation and non-stationarity of the type of spatial data analyzed for studies that explore the relationship between WNV and environmental determinants, we hypothesized that a geographically weighted regression model would help us better understand how environmental factors are related to WNV risk patterns without the confounding effects of spatial non-stationarity.MethodsWe examined commonly mapped environmental factors using both ordinary least squares regression (LSR) and geographically weighted regression (GWR). Both types of models were applied to examine the relationship between WNV-infected dead bird counts and various environmental factors for those locations. The goal was to determine which approach yielded a better predictive model.ResultsLSR efforts lead to identifying three environmental variables that were statistically significantly related to WNV infected dead birds (adjusted R2 = 0.61): stream density, road density, and land surface temperature. GWR efforts increased the explanatory value of these three environmental variables with better spatial precision (adjusted R2 = 0.71).ConclusionsThe spatial granularity resulting from the geographically weighted approach provides a better understanding of how environmental spatial heterogeneity is related to WNV risk as implied by WNV infected dead birds, which should allow improved planning of public health management strategies.

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“…Manuscript to be reviewed tuberculosis versus risk factors (Liu et al 2011); environmental factors versus typhoid fever (Dewan et al 2013); local climate and population distribution versus hand, foot, and mouth disease (Hu et al 2012); and environmental factors and tick-borne disease (Atkinson et al 2012;Atkinson et al 2014;Wimberly et al 2008a;Wimberly et al 2008b), all showing that predictor variables varied spatially across large geographic regions, implying that the results for such studies may be improved using GWR.…”

Section: Introductionmentioning

confidence: 99%

Peer Review #1 of "A comparison of least squares regression and geographically weighted regression modeling of West Nile virus risk based on environmental parameters (v0.1)"

Hemming-Schroeder¹

2017

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Background. The primary aim of the study reported here was to determine the effectiveness of utilizing local spatial variations in environmental data to uncover the statistical relationships between West Nile Virus (WNV) risk and environmental factors. Because least squares regression methods do not account for spatial autocorrelation and non-stationarity of the type of spatial data analyzed for studies that explore the relationship between WNV and environmental determinants, we hypothesized that a geographically weighted regression model would help us better understand how environmental factors are related to WNV risk patterns without the confounding effects of spatial non-stationarity. Methods. We examined commonly mapped environmental factors using both ordinary least squares regression (LSR) and geographically weighted regression (GWR). Both types of models were applied to examine the relationship between WNV-infected dead bird counts and various environmental factors for those locations. The goal was to determine which approach yielded a better predictive model. Results. LSR efforts lead to identifying three environmental variables that were statistically significantly related to WNV infected dead birds (adjusted R 2 =0.61): stream density, road density, and land surface temperature. GWR efforts increased the explanatory value of these three environmental variables with better spatial precision (adjusted R 2 = 0.71). Conclusions. The spatial granularity resulting from the geographically weighted approach provides a better understanding of how environmental spatial heterogeneity is related to WNV risk as implied by WNV infected dead birds, which should allow improved planning of public health management strategies.

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Modelling spatial concordance between Rocky Mountain spotted fever disease incidence and habitat probability of its vector Dermacentor variabilis (American dog tick)

Cited by 18 publications

References 36 publications

Human pathogen co-occurrence in Ixodes ricinus ticks: effects of landscape topography, climatic factors and microbiota interactions

Human pathogen co-occurrence in Ixodes ricinus ticks: effects of landscape topography, climatic factors and microbiota interactions

A comparison of least squares regression and geographically weighted regression modeling of West Nile virus risk based on environmental parameters

Peer Review #1 of "A comparison of least squares regression and geographically weighted regression modeling of West Nile virus risk based on environmental parameters (v0.1)"

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