Exploring the role of temperature and other 5 environmental factors in West Nile virus incidence and 6 prediction in California counties from 2017-2022

Abstract


B. Background
West Nile virus (WNV) is a vector-borne flavivirus that is responsible for the most infections of any mosquito-transmitted disease in the United States [1].West Nile virus was first detected in Southern California in 2003, before quickly spreading to all 58 Californian counties within a year [2].California bears the largest burden of WNV infections, with 4,035 of the nation's 21,869 infections (18%) between 2009 and 2018 being reported in the state [3].Only 20% of infected people will show any symptoms, while less than 1% will show neurological symptoms, manifesting as West Nile neuroinvasive disease (WNND) [3].Still, despite the low symptomatic and severity rate, California reported 326 fatalities due to WNND between 2003 and 2018, as the fatality rate of WNND is about 10% [4].
Many environmental factors are known to impact WNV transmission, with most transmission occurring in non-human hosts.Humans become infected through the bite of a female mosquito from the Culex genus, though WNV cannot be spread between or from humans -they are a dead-end host [3].The enzootic cycle mainly flows through mosquitoes and certain bird species, such as corvids, finches, and sparrows, though infections of horses and chickens are also common [3].Given that WNV incidence in mosquitoes, bird, horses, and other species are an indicator of increased transmission in the enzootic cycle, high wildlife prevalence can serve as a good predictor of the transmission risk to humans [4].Additionally, certain meteorological conditions, such as temperature and rainfall, play an important role in mosquito spawning and behavior and have been shown to be positively associated with human WNV infections [5].In particular, temperature has been shown to affect mosquito life cycle traits and interactions with pathogens, in turn affecting WNV transmission [2,6,7].Prior research has highlighted the predictive power of these environmental factors on West Nile cases in the US and Canada, with the possibility that prediction models might be applied in other, higher-burdened areas [1,8].
While other studies have modeled the importance of temperature and certain other environmental factors in WNV transmission in California [9], as well as the ability of the state's warning system to determine outbreaks [4], there is sparse research that has attempted to quantify excess cases that may be associated with changing meteorological conditions.Few studies also expand further to create prediction models using currently collected data sources.
This analysis is especially important given the projected rise in temperature in California due to worldwide climate change and can help state officials plan for possible increases in future WNV transmission.To our knowledge, no other papers have used a zero-inflated regression model to examine WNV in California.In the context of West Nile virus, a zero-inflated regression model may have advantages over traditional models given the clear seasonality of human infections and the near certainty of zero cases for much of the year.The effectiveness of such a model over a normal negative binomial regression model is explored in this paper.
In our paper, we used a zero-inflated regression model and a generalized estimating equation that incorporates autoregressive structure to measure the association between temperature and WNV incidence, determine the number of excess cases that would result from an increase in temperature, as well as compare the predictions each make for future WNV transmission in California.We hypothesize that temperature will be positively associated with WNV in California after adjusting for rainfall, location, and month of year; meanwhile, meteorological conditions and environmental factors, such as infected dead birds and mosquito pool positivity rate, will be able to predict future WNV cases.

I.
Data West Nile virus is a national and state notifiable condition [10].As such, case data was collected by the California Department of Public Health as part of their surveillance program.
While weekly case incidence is reported, monthly incidence was used in the study to remove inconsistent lags in reporting.Only counties with a population over 250,000 residents and a total of 40 or more cases over the six-year period (2017-2022) were considered high-burden counties and included in the analysis.This totaled 11 counties: Fresno, Kern, Los Angeles, Merced, Orange, Riverside, Sacramento, San Bernadino, San Joaquin, Stanislaus, and Tulare.A restriction was placed on cases due to most counties having a small or zero case count of WNV over the study period, while a minimum county size was enacted to protect cases' identities in small counties.We decided to only use the most recent six-year period of case data, as this reflected a tradeoff between having a large number of observations while maintaining a sufficiently contained time range where transmission and meteorological conditions expressed similar characteristics.Average daily temperature (aggregated across the month in Fahrenheit) and rainfall (summed for the month in inches) were collected from the National Oceanic and Atmospheric Administration.Mosquito pool positivity rates (percentage of mosquito pools within a county that tested positive for WNV) and bird infection counts (count of dead birds that tested positive for WNV) were obtained through California's VectorSurv program under request number 000067.

Zero-Inflated and GEE Models for Measure of Association M The Models and Variables
Negative binomial regression was conducted in both models instead of Poisson because the case data had an overdispersed distribution.Due to the time it takes for a person to become sick enough to seek treatment, as well as the reporting delays of cases to the state health department, we assumed that meteorological conditions and reported case counts are not directly related in time.Given that substantial lags between case onset and case reporting -an average of 5 weeks -have been found in other WNV outbreaks, temperature and rainfall were both lagged one month, so that the variables prior month temperature and prior month rainfall would better reflect the current month's cases [11].As the reporting of vector data are also subject to delays in reporting and biological processes, it was assumed that the mosquito pool positivity rate and dead bird count follow similar delays as cases and therefore were not lagged [11].This selective lagging strategy has been used in other work that models WNV [1].Rainfall, month of year, and county were adjusted for as confounders in the relationship between temperature and WNV cases.Controlling for these variables also helps control for the seasonality and location dependence of West Nile infections.The percentage of positive mosquito pools and positive dead birds were determined to be on the causal pathway and were not analyzed in the models testing for a measure of association, the incidence rate ratio.

Zero-inflated
We used two different methods to estimate an association between temperature and West Nile virus incidence.First, we utilized a zero-inflated negative binomial regression model to .
model the count of cases in the 11 high-burden counties.This method was used to account for the large number of months with zero cases in the data, as there is little WNV transmission outside of June through November.525 of the monthly case counts were zero, representing 66.3% of the observations.We represent the number of cases as y it , where  represents the county (i = 1….11)and  represents the month of observation over the six-year period (t = 1…72).We assume that structural zeroes appear in the data at time  and county  at a probability of .Therefore, there are two processes in which data can be generated for each observation: the first, which generates a case count of 0 with probability of ; the second, which generates a case count corresponding to a negative binomial model, represented by (  |  ) with a probability of ℎ 1 -  } Therefore, we assume the probability that the expected number of cases,   , is equal to   is given by the zero-inflated negative binomial model below.  represents the vector of covariates in the model, while ℎ  expresses the calendar month at county  and time , which is believed to well predict whether there will be cases in a given observation or not.
The function representing the negative binomial model, (  │  ), is defined below, where the vector of covariates in the model,   , includes the prior month temperature, prior month rainfall, the county, and the month.Prior month temperature is the exposure of interest on the outcome, while prior month rainfall, county, and month are all confounders of this relationship.While county and month are shown here as being expressed by one  term, they are analyzed as factor variables in the model, meaning that a dummy variable was created for each category level (10 for county and 11 for month), and a  term was calculated for each.
Second, we used a negative binomial model with autocorrelation features.We utilized an "ar1" auto-correlation structure, meaning cases in one month were strongly correlated with cases in the month before and the month after, but not other months.This structure is thought to accurately describe infection dynamics in our system, as the cases in county  at time  are dictated by how many mosquito infections, and subsequent human infections, were present at time  -1, as well as influences how many cases there will be at time  + 1 given the same dynamics.The model follows the same form as the negative binomial part of the zero-inflated model, but has an added autoregressive term, , that follows a distribution of "ar1", as shown in the model below.

Standardization
Model standardization was conducted to retrieve a risk difference (in the number of excess cases) between a hypothetical dataset where temperature was increased by two degrees (with all other variables kept constant) and the observed dataset.We created a population where prior month temperature was increased by two degrees Fahrenheit across all observations, later using it to fit a zero-inflated model and find the total number of cases expected in the six-year study.The risk difference is the total number of cases expected in the hypothetical population minus the number of cases expected given the observed data.While this risk difference cannot be interpreted as an association between temperature and West Nile incidence -due to it being a hypothetical population -it can provide insight into possible repercussions of a changing climate in the future.Bootstrapped sampling, using the biascorrected and accelerated technique (BCA), was subsequently applied to measure the uncertainty in our risk difference calculations.

Prediction Models
Both the zero-inflated model and autoregressive negative binomial model were used as prediction models for WNV cases in 2022.Both models were trained on the data from 2017-.2021 and then tested on the data from 2022.The models followed the same assumptions and equations as the models specified above, respectively, but were made to include different sets of the covariates in the data.Since they are prediction models, all variables, including percentage of positive mosquito pools and positive dead birds-which were left out of the measure of association models due to existing on the causal pathway between temperature and WNV incidence -were included in the analysis.The four different prediction sets tested were: "All," comprising all the covariables listed; "Host/Vector," comprising dead infected birds and mosquito positivity rate; "Just Temperature," comprising just prior month temperature; and "Weather," comprising prior month temperature and prior month rainfall.We opted to use mean squared error (MSE) to compare the models over information criteria tests, such as the AIC or BIC, as we didn't have concrete likelihood estimates from the GEE model [12].Though mean squared error doesn't account for and penalize the number of predictor variables in each model, the lack of a large difference in variables used (4 vs 2 vs 2 vs 1 in "All," "Host/Vector," "Weather," and "Just Temperature," respectively) and a clear difference in each model's mean squared error highlighted a clear best fit for the data.

D. Ethical Dimensions
Given the ecological design of the study and the passively collected surveillance case data, no data was actively collected on human subjects.No identifiers were included in the data, and only aggregated data from high-burden, highly populated counties were used in the analysis to protect individual's identities.Therefore, there was no risk to any individuals who may have been included in the data.While this analysis was conducted well after all of the infections and any findings will not be of benefit to the individual, the results may still benefit these community in the future.  .

Descriptive Analysis
These trends are further explored in Table 1, which shows the average cases, temperature, rainfall, dead birds, and mosquito pool positivity per six-month periods in each county over the study period.There are clear seasonal differences in all the variables; the analysis of detangling seasonality and temperature to examine the association between temperature and WNV cases is presented below.

Statistical Models and Standardization
Both the zero-inflated and GEE with autoregressive correlation models show a positive correlation between prior month temperature and WNV cases in a month (Table 2).Each model was adjusted for the variables prior month rainfall, county, and month, which were determined to be confounders in the relationship of interest.

Table 2
Both models had nearly the same estimation of 1.05 for the incidence rate ratio -this represents that a one degree increase in prior month temperature is associated with a 1.05 times greater incidence of West Nile virus in a month, controlling for prior month rainfall, location, and the time of year.The IRR estimates from both models were statistically significant, though the autoregressive GEE model had a narrower 95% confidence interval (Table 2).
The models can also be extrapolated to larger changes in temperatures, as is predicted by some climatologists [13][14][15].Some estimates suggest that California's average temperatures may rise by two degrees Fahrenheit by 2040 [13,14].Given a two degree increase in temperature, and holding all other variables constant, the zero-inflated models suggest that this .would be associated with a 1.12 times greater incidence rate, while the GEE model reports this number to be 1.10.Across the six-year study period, the risk difference between the hypothetical data, with a two degree temperature increase, and the observed data is 148.7 (95% confidence interval of 28.8 -292.8)cases for the zero-inflated model.This averages out to 24.8 (4.8 -48.8) excess cases per year.

Prediction Models
Table 3 shows the output of the prediction model with all variables for the zero-inflated model and GEE with autoregressive correlation model.As in the measure of association model, both types of models showed fairly similar results, as prior month temperature, mosquito pool positivity rate, and dead birds positively predicted WNV cases in each model, while prior month rainfall negatively predicted WNV cases.The models' predictions slightly differed in their estimates of the beta for each variable, and while small in absolute size, the differences were significant, as seen in later analysis.count months (November-June) but over-estimated the number of cases in the peak summer months."Just Temperature" and "Weather" both greatly over-estimated the peak summer months and incorrectly predicted the shape of the incidence curve.It's possible that since the zero-inflated model already uses the month of year, which is very strongly tied to weather patterns, to determine non-zero case counts, adding weather data to the prediction model did not increase the strength of the fit."All" variables provided the best fit -the lowest MSE -to the data out of the zero-inflated subset.

Fig 3
The GEE subset of models showed more similar fits, again most likely due to the model not having the month predictor for zero case counts.In contrast to the zero-inflated models, the GEE prediction models followed the peak of cases in August much more closely, though it also overestimated the actual reported number of cases slightly.The GEE model greatly overestimated the number of cases in months with low case counts, however, often at scales of three to four times larger.The "Host/Vector" model especially produced a skewed fit, as even with a mid-range mean squared error, it predicted 10 cases a month in the winter months and overall had a non-normal shape.The "All" GEE model resulted in the best fit across all of the prediction models with a mean squared error of 17 and a closely following curve. .Though it had the lowest MSE, the "All" GEE model still predicted more total cases in 2022 than were actually reported, by a count of 214 to 172, respectively.The best performing model in this regard was in fact the skewed "Host/Vector" GEE model (192 cases), followed by the "All" zero-inflated model (202 cases), and the "Host/Vector" zero-inflated model (214 cases).In a simpler view, Fig 4 shows both the zero-inflated and GEE "All" models -the twobest performing models according to MSE -plotted against the actual reported cases in the 11high burden counties in 2022.This more clearly shows the differences between the prediction models discussed above.

Fig 4 F. Discussion
Our study highlights an association between temperature and West Nile virus cases in 11 high-burden California counties from 2017-2022; holding month of year, location, and prior month rainfall constant, a one unit increase in prior month temperature was associated with 1.05 times the incidence of WNV.Given a hypothetical two degree Fahrenheit increase in average monthly temperature, which has been predicted for California in the next few decades due to climate change [13,14], the zero-inflated model predicted 24.8 excess cases per year over our study period.In the prediction models, using all variables -weather and host/vector combined -resulted in the best fit, and lowest mean squared error, for 2022 case counts.The GEE approach had overall better fitting prediction models, but the zero-inflated model was able to predict the total case count more closely for the year.Our estimates on the significantly positive association between temperature and WNV incidence at the group level is well-supported in other studies in California and the US [9,16].The magnitude of our association is in line with findings from Hahn et.al, who observed an odds ratio of 1.1 nationally [16]; alternatively, Hernandez et.al calculated an odds ratio of 10.5 in California's San Joaquin Valley, though this finding did have a wide confidence interval [9].The connection between temperature and mosquito life traits, [6] such as development time and survival, as well as mosquito and viral interaction, such as the extrinsic incubation period -the time it takes for an infected mosquito to become infective to hosts -have been documented in numerous other studies [7,17].These associations are complex and can often vary at different temperatures: e.g.Culex development rates rise with temperature until a certain point, when increasing temperature then causes rising mortality [18].While this paper doesn't go into the biological mechanisms that mediate this relationship, these previous findings provide a causal basis for the observed association.Given the results of both types of prediction models, it appears that having weather data alone provides little predictive power for WNV cases in California.Host and vector data provides a pretty good fit in the absence of weather data for the zero-inflated model, showing that simple enzootic data from local vector departments can be enough to give useful information on current and future WNV cases in humans.However, given how readily available weather data is, it seems unnecessary and uninformative to use a prediction model with just host and vector data.This mostly aligns with the results of previous work.Wimberly et.al shows that while meteorological and mosquito infection rate data can predict WNV cases better than just historical data, it takes the combination of the two to best predict future cases [8].Davis et.al's prediction model also showed that meteorological and mosquito data together can well predict future WNV cases, but again, disagreed with our model that mosquito infection data alone does nearly as well as all the data [19].
Our study revealed the power of the zero-inflated model to correctly predict the number of cases in low transmission months compared to more traditional models.However, the utility of this feature is limited, as low transmission months are of much smaller worry to health departments than summer months.The more traditional GEE model followed the shape and case counts of the peak summer months much closer and may provide health departments with a much more accurate picture of what may come month to month.Though it greatly overpredicts the number of cases during the summer, the zero-inflated model more accurately predicted the total number of cases in 2022, highlighting its potential utility in helping the state plan on a macro level.These models will need to be tested on a larger geographic scale with more counties and with newer years of data to make any final statements on their ability to be used by health departments.
A great strength of the study is its potential to be easily interpretable and implementable to public health agencies and the public: the data was easily accessible, and the model has just a few parameters that can be quickly integrated.These models allow for analyses that don't require complex knowledge of the many relationships that underlie the observed associations, including the mechanisms by which temperature is associated with incidence.It also lends itself to future use by public health departments, which don't need mountains of data to help predict WNV cases.We also utilized standardization to estimate a risk difference in cases between the observed data and a hypothetical California with an increased temperature of two degrees Fahrenheit, an underutilized strategy that can provide crucial insights into the future of WNV transmission in the state.Though a hypothetical scenario, it provides more easily digestible and understandable estimates (in number of excess cases per month) than an odds ratio, or even our calculated rate ratio.
The data in this study has inherent limitations, however.Cases were aggregated on a monthly level, and other variables were in turn averaged or summed to correspond to this time frame.The lack of granularity in case data may bias the association between temperature and incidence, especially considering that weather can be highly volatile, a characteristic that is lost when averaged over a monthly time frame.Surveillance data, which comprises the case counts, dead bird counts, and mosquito pool positivity rate, also carries its own shortcomings, as it misses most, if not all, of asymptomatic infections and may not be representative of the infection dynamics in the system as a whole.We also lost granularity and possible variation in weather patterns and transmission dynamics across counties by analyzing the counties together; future work would benefit by looking at the effect of temperature on WNV incidence within counties, possibly at the zip code or census tract level.
There are also limitations based on the way the models were constructed, especially the zero-inflated model.Based on data from the last decade, we assumed that the month of year was a quality predictor of whether there would be non-zero case counts.However, studies have shown that a rise in temperature can also shift the seasonality of WNV in California [20].This change would challenge our assumption and possibly bias our estimate of the association between temperature and WNV.Sensitivity analyses can be run to determine if other predictors, or sets of predictors, would be better suited as the zero count predictor in the zero-inflated model.
While this aggregated ecological study has limitations, it provides an easy and convenient study design using pre-existing surveillance data.As previously mentioned, it is mandatory to report WNV disease, creating a passive surveillance system; as a result, no new data on the outcome needed to be assessed.The type of exposure -environmental -also pointed to using an ecological study, as temperature is a group-level exposure.It not only would be hard to measure the temperature experienced by an individual in a cohort, but generally uninformative to attempt to discern how a change in temperature affects a singular person's risk of WNV disease, which is influenced by many different possible factors, including type of job and socioeconomic status.Therefore, we don't believe to be committing any ecological fallacy -inferring that the ecological association equals the individual association -as we don't attempt to determine or make assumptions about the effect of temperature on the individual risk of WNV disease.Our study simply examines the risk aggregated at the county level.This is probably more informative to Californian public health agencies, as the risk of WNV disease to the average Californian is very low.In all, an ecological study was sufficient and better applicable to calculate the association of interest at the county level, while remaining easily replicable to future researchers and public health departments.More types of climatic analysis can be conducted using this same data, such as the effect of prior seasonal rainfall and temperature on future WNV incidence, the importance of which has been shown for the length of the WNV season in the US as a whole [21,22].Exploring the mechanisms that mediate the association between temperature and West Nile virus would also be beneficial to further analyze different intervention strategies.Finally, more work is required to understand the interface between humans and the enzootic carriers of WNV in California, and how climate change may alter the ways people interact and are exposed to these hosts and vectors.

Conclusion
Increasing temperatures is associated with a higher incidence of West Nile virus infection in 11 high-burden California counties.Along with mosquito and bird infection data, meteorological data can well-predict future WNV incidence in these counties.This will be of extreme importance to public health agencies as WNV continues to become a larger health burden due to global warming and climate change.

Fig 1
Fig 1 plots the mean temperature and West Nile virus cases across all 11 high-burden

Fig 2
Fig 2 shows the risk difference of WNV cases conducted through model standardization,

3
Fig 3 plots the predicted cases in the 11-high burden counties in 2022 for each variable and GEE Prediction Models Using 'All' Variables Against Reported Cases in 11 High-Burden CA Counties in 2022 .

Table 1 :
Characteristcs of WNV Cases and Environmental Factors per Month By County from 2017-2022 *All variables are average per month