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Association between community socioeconomic factors, animal feeding operations, and campylobacteriosis incidence rates: Foodborne Diseases Active Surveillance Network (FoodNet), 2004–2010

Abstract

Background

Campylobacter is a leading cause of foodborne illness in the United States. Campylobacter infections have been associated with individual risk factors, such as the consumption of poultry and raw milk. Recently, a Maryland-based study identified community socioeconomic and environmental factors that are also associated with campylobacteriosis rates. However, no previous studies have evaluated the association between community risk factors and campylobacteriosis rates across multiple U.S. states.

Methods

We obtained Campylobacter case data (2004–2010; n = 40,768) from the Foodborne Diseases Active Surveillance Network (FoodNet) and socioeconomic and environmental data from the 2010 Census of Population and Housing, the 2011 American Community Survey, and the 2007 U.S. Census of Agriculture. We linked data by zip code and derived incidence rate ratios using negative binomial regression models.

Results

Community socioeconomic and environmental factors were associated with both lower and higher campylobacteriosis rates. Zip codes with higher percentages of African Americans had lower rates of campylobacteriosis (incidence rate ratio [IRR]) = 0.972; 95 % confidence interval (CI) = 0.970,0.974). In Georgia, Maryland, and Tennessee, three leading broiler chicken producing states, zip codes with broiler operations had incidence rates that were 22 % (IRR = 1.22; 95 % CI = 1.03,1.43), 16 % (IRR = 1.16; 95 % CI = 0.99,1.37), and 35 % (IRR = 1.35; 95 % CI = 1.18,1.53) higher, respectively, than those of zip codes without broiler operations. In Minnesota and New York FoodNet counties, two top dairy producing areas, zip codes with dairy operations had significantly higher campylobacteriosis incidence rates (IRR = 1.37; 95 % CI = 1.22, 1.55; IRR = 1.19; 95 % CI = 1.04,1.36).

Conclusions

Community socioeconomic and environmental factors are important to consider when evaluating the relationship between possible risk factors and Campylobacter infection.

Peer Review reports

Background

An estimated 9.4 million domestically acquired foodborne illnesses, associated with 31 known pathogens, occur each year in the United States [1]. Campylobacter, a leading bacterial cause of these foodborne illnesses, is responsible for an estimated 1 million cases each year [1]. Campylobacteriosis is typically characterized by gastroenteritis [2]. More severe Campylobacter infections can lead to septicemia, arthritis, Guillain-Barré syndrome, or Miller Fisher syndrome [2]. Campylobacter normally inhabit the intestines of warm-blooded wild and domestic animals and several avian species [3]. Along with international travel, ingestion and handling of poultry and ingestion of dairy products contaminated with Campylobacter have been identified as major risk factors for both sporadic cases and outbreaks [2, 47]. Current interventions to reduce the incidence of Campylobacter infection in the United States have focused on improving food safety by the development of poultry industry performance standards; yet, incidence rates in 2013 were higher than in 2006–2008 [8, 9].

Beyond food-related risk factors, multiple analyses show that community socioeconomic and environmental risk factors, such as living in areas with higher median household incomes or living in close contact with livestock, influence the risk of campylobacterosis [7, 10, 11]. Campylobacter can enter the environment through direct fecal contamination of water bodies, manure application on agricultural land, and runoff [12, 13]. Campylobacter has been found in surface water and groundwater, and living in homes on private wells or ingesting water from lakes or rivers has been associated with an increased risk of campylobacteriosis [1215].

A recent Maryland-based study evaluated the association between community socioeconomic and environmental risk factors and rates of campylobacteriosis and found that several factors, including degree of rurality and the presence of broiler chicken operations, were associated with campylobacteriosis rates [11]. However, campylobacteriosis rates differ by geographic region, and therefore, it is unknown whether Maryland-based findings can be extrapolated to other states [16]. Identifying whether community socioeconomic and environmental factors are associated with campylobacterosis across the U.S. is an important step towards improving our understanding of exposures associated with campylobacteriosis. This study investigated the association between zip code level socioeconomic and environmental variables and campylobacteriosis incidence at multiple surveillance sites in the U.S.

Methods

Data sources

The Foodborne Diseases Active Surveillance Network (FoodNet) is a collaboration between the Centers for Disease Control and Prevention (CDC), 10 state health departments, the US Department of Agriculture’s Food Safety and Inspection Service (USDA-FSIS), and the US Food and Drug Administration (FDA). The FoodNet surveillance area includes the states of Connecticut (CT), Georgia (GA), Maryland (MD), Minnesota (MN), New Mexico (NM), Oregon (OR), and Tennessee (TN), and selected counties in California (CA), Colorado (CO), and New York (NY). FoodNet conducts active population-based surveillance for laboratory-confirmed infections caused by nine pathogens transmitted commonly through food, including Campylobacter. For this study, we restricted analyses to data on culture-confirmed cases of Campylobacter infection (including infections caused by C. jejuni, C. coli and unknown Campylobacter spp.) reported between 2004 and 2010. Both sporadic cases and those associated with outbreaks were included in this analysis.

We obtained socioeconomic data from the 2010 Census of Population and Housing and the 2011 American Community Survey (5-year estimates) by 5-digit zip code tabulation area (ZCTA) (9). We selected socioeconomic variables on the basis of recommendations from studies conducted by Zappe Pasturel et al. [11] and Krieger et al. [17]. We obtained animal feeding operation data from the 2007 U.S. Census of Agriculture, National Agricultural Statistics Service [18].

Descriptive analyses

We calculated Campylobacter incidence rates per 100,000 population by year for each state using intercensal estimates of state populations from the U.S. Census Bureau [19]. FoodNet Campylobacter case count data were linked with the socioeconomic and animal feeding operation data by zip code and 5-digit ZCTA and used to calculate rates per 100,000 population by zip code using zip code population estimates from the 2010 Census.

Negative-binomial regression

We developed regression models to evaluate associations between socioeconomic and environmental factors and campylobacteriosis incidence at the zip code level. First, we evaluated collinearity among our predictor variables using the inverse of the variance inflation factor. Highly collinear variables were excluded using a stepwise approach. We compared several regression models for count data and tested models with and without zero inflation and with and without spatial covariate structure. The negative binomial regression model without spatial covariate structure provided the best fit for the dataset and the final model included the zip code level variables described in Table 1. Cases from Georgia between 2004 and 2008 (n = 3,112, 7.5 % of all campylobacteriosis cases reported to FoodNet between 2004 and 2010) and 762 cases (1.9 % of all reported cases) from the other FoodNet sites were excluded from the final model because either zip code information was missing or socioeconomic Census variables were not available for the given zip code. A total of 4,692 zip codes were included in the analysis. The number of zip codes included per state was as follows: CA, 116; CO, 133; CT, 271; GA, 710; MD, 450; MN, 880; NM, 345; NY, 757; OR, 413; TN, 617. We ran both a regression model that included all FoodNet sites and site-specific regression models. We performed all modeling using SAS version 9.3, and used p-values of ≤0.05 to assess statistical significance.

Table 1 Sources and files for the socioeconomic and environmental variables included in the negative binomial regression models used in this study

Results

From 2004 to 2010, 40,768 cases of culture-confirmed Campylobacter infection were reported to FoodNet. Of those cases, 36,894 had valid zip codes, for which Census data were available, and were included in subsequent analyses. About 45 % of cases were confirmed as C. jejuni, 2.4 % as C. coli and 52.7 % as unknown Campylobacter spp. Most cases were sporadic infections (99.6 %), while 0.4 % of cases were associated with outbreaks. Most cases were white (62.4 %), 3.8 % were African-American, 3.3 % were Asian, and 30.5 % were of other or unknown race. In terms of age, 12.6 % of cases were 0–4 years, 5.2 % were 5–9 years, 9.5 % were 10–19 years, 56.6 % were 20–59 years, and 16.1 % were ≥60 years.

The average annual incidence of campylobacteriosis across all 10 FoodNet sites ranged from 12.4 per 100,000 population in 2005 to 13.4 per 100,000 population in 2010 (Fig. 1). California had the highest average incidence (28.0 cases per 100,000 population) and Georgia had the lowest (6.8). The highest incidence among all sites was in California in 2010 (32.0), while the lowest was in Maryland in 2004 (5.2).

Fig. 1
figure 1

Incidence of Campylobacter infection per 100,000 population by year and by FoodNet site: 10 FoodNet sites, 2004–2010

Community socioeconomic factors

The overall regression model identified multiple socioeconomic factors at the zip code level that were associated with campylobacteriosis incidence rates. Incidence was higher in zip codes with higher percentages of Hispanic residents (incidence rate ratio [IRR] = 1.005; 95 % confidence interval [CI] = 1.002,1.007); and in zip codes with higher percentages of individuals living below the poverty level (IRR = 1.011; 95 % CI = 1.006,1.015) (Table 2). Incidence was lower in zip codes with higher percentages of African American residents (IRR = 0.972; 95 % CI = 0.97,0.974), higher owner occupancy rates (IRR = 0.995; 95 % CI = 0.992,0.997), and higher percentages of the population aged 25 years and older without a high school diploma (IRR = 0.967; 95 % CI = 0.96,0.973) (Table 2).

Table 2 Campylobacteriosis in association with community environmental and socioeconomic factors: 10 FoodNet sites, 2004–2010

When stratified by FoodNet site, the direction of the association and statistical significance for each socioeconomic variable varied, but we observed some common patterns (Table 2). In six sites (CA, CO, GA, MD, NY, and TN), zip codes characterized by higher percentages of African Americans had significantly lower rates of campylobacteriosis (Table 2). In four sites (CO, MD, NM, and TN), zip codes that had a higher percentage of individuals living below the poverty level had higher incidence rates (Table 2). Higher owner occupancy rate was inversely associated with Campylobacter infections in four sites (CA, CT, GA, and MN); however, the direction of the association was reversed in New Mexico (Table 2).

Community environmental factors

Several environmental factors at the zip code level were associated with campylobacteriosis incidence in the overall model. Incidence was slightly higher in zip codes with higher percentages of housing units within rural areas (IRR = 1.002; 95 % CI = 1.001,1.003); and in zip codes with turkey operations (IRR = 1.129; 95 % CI = 1.033,1.234). Incidence was lower in zip codes with broiler operations (IRR = 0.867; 95 % CI = 0. 806, 0.932).

When stratified by FoodNet site, we observed some interesting patterns for environmental factors (Table 2). In four sites (CA, MN, NY, and OR), zip codes with higher percentages of housing units in rural areas had higher incidence rates of campylobacterosis. In Georgia and Tennessee, zip codes with broiler operations had significantly higher incidence rates than those without. In Georgia, incidence was 22 % higher in zip codes with broiler operations (IRR = 1.22, 95 % CI = 1.03,1.43), and in Tennessee, incidence was 35 % higher in zip codes with broiler operations (IRR = 1.35, 95 % CI = 1.18,1.53) (Fig. 2). The findings were similar in Maryland, but the association was not significant (IRR = 1.163, 95 % CI = 0.99,1.37) (Fig. 2).

Fig. 2
figure 2

Campylobacter incidence rate ratios for the presence of broiler chicken and dairy operations in a zip code at 8 FoodNet sites. The FoodNet catchment areas for California and Colorado predominantly include more urban areas, are not representative of the entire state, and were not included in the figure

In Minnesota and New York FoodNet counties, incidence was 37 % higher (IRR = 1.37; 95 % CI = 1.22,1.55) and 19 % higher (IRR = 1.19; 95 % CI = 1.04,1.36), respectively, in zip codes with dairy operations (IRR = 1.37; 95 % CI = 1.22,1.55) (Fig. 2). In contrast, in the Colorado FoodNet counties and Connecticut, the incidence of campylobacteriosis was lower in zip codes with dairy operations compared to those without dairies (IRR = 0.36, 95 % CI = 0.23,0.54; IRR = 0.79, 95 % CI = 0.70,0.91, respectively).

Discussion

To our knowledge, this is the first study to evaluate the effect of community socioeconomic and environmental factors on Campylobacter incidence across multiple U.S. sites by linking surveillance data with publicly available data sources at the zip code level. Our results emphasize the importance of evaluating community risk factors for differing sites individually, because analyzing the data overall obscured some patterns.

Community socioeconomic factors

In six of the 10 FoodNet sites, campylobacteriosis incidence rates were lower in zip codes with higher percentages of African Americans. This finding corroborates previous findings in Maryland, as well as findings from Samuel et al. [20] that included data from all FoodNet sites [11]. These findings might be influenced by differences in healthcare access among different races and ethnicities. African Americans are less likely to have health insurance and are more likely to have structural impediments to healthcare which decreases the opportunities for infections among this population to be captured by surveillance programs [21]. Quinlan et al. [22] also suggested that African Americans could have greater immunity to Campylobacter.

In our overall regression model and in two of the individual FoodNet sites, campylobacteriosis incidence rates were higher in zip codes with higher percentages of Hispanics. Two recent studies analyzing risk factors for Campylobacter infections found similar associations between Hispanic ethnicity and increased risk of campylobacteriosis, including a telephone survey among residents in the 10 FoodNet sites [23, 24]. Neither of these studies posited why Hispanic ethnicity was associated with a higher risk of campylobacteriosis, and research concerning this association is still lacking.

Our results also showed that some zip codes characterized by lower socioeconomic status had higher incidence rates of campylobacterosis, suggesting that poverty might be associated with higher rates of Campylobacter infection. However, our results for all variables associated with poverty do not clearly support this hypothesis, and the literature is similarly unclear about the association between poverty and campylobacterosis incidence. For instance, in our overall regression model, zip codes with more individuals living below the poverty level, as well as zip codes with lower owner occupancy rates, had higher campylobacteriosis rates. However, there were lower rates of campylobacterosis in zip codes with higher percentages of individuals without a high school diploma (another indicator of low socioeconomic status). Krieger et al. [25] found that poverty increased the risk of multiple negative health outcomes including bacterial infections. Darcey and Quinlan [26] evaluated the number of health code violations at food retail facilities in the Philadelphia, Pennsylvania area as a surrogate for foodborne illness and found that there were more critical health violations in food service facilities in high poverty areas [22]. Bemis et al. [27] also showed that, among children less than 10 years old, lower socioeconomic status was associated with a higher incidence of campylobacteriosis. These findings are particularly interesting since lower socioeconomic status has been associated with several barriers to healthcare access--including financial barriers and stigma associated with using Medicaid--that would seemingly reduce the probability of poorer individuals seeking healthcare and being captured by surveillance systems [28]. On the other hand, some studies have noted that higher socioeconomic status is associated with higher rates of campylobacteriosis [27].

Community environmental factors

Several studies have suggested that environmental factors contribute more to the incidence of campylobacteriosis than previously thought [3, 22, 29]. The high variability of campylobacteriosis incidence across FoodNet sites supports the hypothesis that one’s environment might affect risk. Rurality was significantly associated with higher incidence rates of campylobacteriosis in our overall model as well as in site-specific regression models for four sites. The higher rate of Campylobacter infections in rural areas might be explained by an increased likelihood of exposure to animals and animal waste [11]. A previous study by Green et al. [30] identified a 1.46 higher campylobacteriosis incidence rate in rural areas of Manitoba, Canada compared to urban areas.

Poultry consumption is the most common risk factor for sporadic Campylobacter infections, and a leading risk factor for Campylobacter outbreaks, in the U.S. [4, 31]. Approximately 90 % of U.S. chicken flocks are colonized with Campylobacter [29]. Georgia and Tennessee, two of the leading broiler producing states in the U.S., had significantly higher incidence rates of campylobacteriosis (22 % and 35 % higher, respectively) in zip codes containing broiler chicken operations compared to zip codes without these operations (Table 2) [32]. Our results for Maryland, another leading broiler producing state, also suggest a relationship between the presence of broiler operations in a zip code and higher campylobacteriosis incidence rates.

Campylobacter could be spread from broiler operations to human populations through both surface water and groundwater. Broiler chickens shed Campylobacter in their feces, and it could then enter nearby surface waters after land application of poultry litter and during runoff events [33]. Campylobacter has been isolated from several types of surface water, including streams and rivers, and can survive in water for at least 29 days [29, 34]. Wilkes et al. [13] detected Campylobacter in Canadian surface water samples more frequently during cooler seasons when poultry litter is more typically applied to land. Vereen et al. [35] found more Campylobacter in streams downstream of poultry houses, as well as a positive association between the frequency of detecting Campylobacter and the number of poultry houses in a subwatershed. Contaminated groundwater is also a possible source of Campylobacter exposure among humans. The majority of Campylobacter outbreaks attributed to drinking water between 1997 and 2008 in the U.S. were associated with untreated groundwater [4].

Cows and other ruminants also have been identified as important sources of Campylobacter infection in both the U.S. and Europe [3, 4]. Taylor et al. [4] identified that the consumption of dairy products was the largest contributor (28.9 %) to U.S. campylobacteriosis outbreaks from 1997 to 2008. Campylobacter could be transmitted through the environment from dairy operations to human populations through water from direct fecal contamination of water bodies or from land application of dairy waste. A study in northwest England found that Campylobacter concentrations, specifically C. jejuni, increased as water flowed downstream through dairy grazing pastures [36]. When dairy wastewater is land applied, Campylobacter can also become airborne and could infect individuals downwind of dairy wastewater application sites [37, 38].

Our data support the findings of Arsenault et al. [3] in Quebec, who reported that higher density of ruminants was significantly associated with increased incidence of campylobacteriosis, especially among children. In New York FoodNet counties and Minnesota, two leading dairy producing regions [39], zip codes containing dairy operations had statistically significantly higher incidence rates of campylobacterosis compared to zip codes without dairies. In California and Colorado, two other important dairy producing states in the U.S., we could not effectively evaluate this relationship because the FoodNet catchment areas associated with these sites do not include the full states.

The type of dairy operation (e.g., concentrated animal feeding operation (CAFO), free range, conventional, organic), could also impact the risk of Campylobacter infection in a zip code. A study by Rapp et al. [14] found that dairy cows at CAFOs were more likely to shed Campylobacter than dairy cows at free range operations in New Zealand. A study conducted in the Midwestern and northeastern regions of the U.S. found that conventional dairy operations had more Campylobacter-positive fecal and environmental samples, and higher proportions of antibiotic-resistant Campylobacter isolates, compared to organic farms [40]. However, a similar study by Sato et al. [41] found no statistically significant differences in Campylobacter presence or antimicrobial resistance between conventional and organic dairy farms. The impact of the type of dairy operation on incidence of Campylobacter infections was not the focus of the current study, but deserves further attention.

Limitations

Our study had some limitations. First, because the FoodNet sites in California, Colorado, and New York do not cover the entire state but only select counties we could not fully examine some factors of interest at those sites. Second, the data collected by FoodNet is limited to specific U.S. sites and might not be representative of the whole country. In addition, since we engaged in an ecological study design, providing data on the association between community-level risk factors and campylobacteriosis incidence, our findings cannot be used to infer associations at the individual level. Finally, because the FoodNet data available to us was at the zip code level, the level of resolution of our analyses is not as fine as it would have been had the data been available at the census block or census tract level.

Conclusions

Our findings point to several community socioeconomic and environmental factors that might be associated with campylobacteriosis incidence. The increased incidence rates in zip codes containing broiler and dairy operations in states that are leading producers in those industries, as well as the inverse association in zip codes with more African Americans, were of interest. Previous social epidemiological studies have shown that community-level factors are important with regard to a range of diseases and health outcomes. Our data are among the first to show that it is important to consider both community-level socioeconomic and environmental factors, in addition to individual-level factors, when examining risk factors for Campylobacter infection. The unique patterns of association observed at individual sites emphasize the importance of analyzing smaller areas when investigating the association between socioeconomic and environmental factors and campylobacteriosis incidence. The heterogeneity of our findings across sites suggests that future studies of this nature may benefit from the inclusion of both individual-level and community-level factors in the modeling approach.

Abbreviations

95 % CI, 95 % confidence interval; CA, California; CDC, centers for disease control and prevention; CAFO, concentrated animal feeding operation; CT, connecticut, CO, Colorado; FDA, Food and Drug Administration; FoodNet, Foodborne Diseases Active Surveillance Network; GA, Georgia; IRR, Incidence rate ratio; MD, Maryland; MN, Minnesota; NM, New Mexico; NY, New York; OR, Oregon; TN, Tennessee; USDA-FSIS, US Department of Agriculture, Food Safety and Inspection Service; ZCTA, Zip code tabulation area.

References

  1. Scallan E, Hoekstra RM, Angulo FJ, Tauxe RV, Widdowson M-A, Roy SL, Jones JL, Griffin PM. Foodborne Illness Acquired in the United States--Major Pathogens. Emerg Infect Dis. 2011;17(1):7–15.

    Article  PubMed  PubMed Central  Google Scholar 

  2. Kaakoush NO, Castaño-Rodríguez N, Mitchell HM, Man SM. Global epidemiology of campylobacter infection. Clin Microbiol Rev. 2015;28(3):687–720.

    Article  PubMed  PubMed Central  Google Scholar 

  3. Arsenault J, Michel P, Berke O, Ravel A, Gosselin P. Environmental characteristics associated with campylobacteriosis: accounting for the effect of age and season. Epidemiol Infect. 2012;140(02):311–22.

    Article  CAS  PubMed  Google Scholar 

  4. Taylor EV, Herman KM, Ailes EC, Fitzgerald C, Yoder JS, Mahon BE, Tauxe RV. Common source outbreaks of Campylobacter infection in the USA, 1997–2008. Epidemiol Infect. 2013;141(05):987–96.

    Article  CAS  PubMed  Google Scholar 

  5. Pogreba-Brown K, Baker A, Ernst K, Stewart J, Harris RB, Weiss J. Assessing risk factors of sporadic Campylobacter infection: a case–control study in Arizona. Epidemiol Infect. 2016;144(04):829–39.

    Article  CAS  PubMed  Google Scholar 

  6. Bassal R, Ovadia A, Bromberg M, Stein M, Shainberg B, Loewenthal S, Somekh E, Cohen D, Shohat T. Risk Factors for Sporadic Infection with Campylobacter Spp. among Children in Israel: A Case–control Study. Pediatr Infect Dis J. 2015. [Epub ahead of print].

  7. MacDonald E, White R, Mexia R, Bruun T, Kapperud G, Lange H, Nygård K, Vold L. Risk Factors for Sporadic Domestically Acquired Campylobacter Infections in Norway 2010–2011: A National Prospective Case–control Study. PLoS ONE. 2015;10(10):e0139636.

    Article  PubMed  PubMed Central  Google Scholar 

  8. Food Safety and Inspection Service. New performance standards for Salmonella and Campylobacter in young chicken and turkey slaughter establishments; new compliance guides. U.S. Department of Agriculture FSaIS, editors. Washington: United States Department of Agriculture, FSIS; 2010.

  9. Crim SM, Iwamoto M, Huang JY, Griffin PM, Gilliss D, Cronquist AB, Cartter M, Tobin-D'Angelo M, Blythe D, Smith K, et al. Incidence and trends of infection with pathogens transmitted commonly through food - foodborne diseases active surveillance network, 10 u.s. Sites, 2006–2013. MMWR Morb Mortal Wkly Rep. 2014;63(15):328–32.

    PubMed  Google Scholar 

  10. Domingues AR, Pires SM, Halasa T, Hald T. Source attribution of human campylobacteriosis using a meta-analysis of case–control studies of sporadic infections. Epidemiol Infect. 2012;140(06):970–81.

    Article  CAS  PubMed  Google Scholar 

  11. Zappe Pasturel B, Cruz-Cano R, Rosenberg Goldstein RE, Palmer A, Blythe D, Ryan P, Hogan B, Jung C, Joseph SW, Wang MQ, et al. Impact of Rurality, Broiler Operations, and Community Socioeconomic Factors on the Risk of Campylobacteriosis in Maryland. Am J Public Health. 2013;103(12):2267–75.

    Article  PubMed  PubMed Central  Google Scholar 

  12. Close M, Noonan M, Hector R, Bright J. Microbial transport from dairying under Two spray-irrigation systems in Canterbury, New Zealand. J Environ Qual. 2010;3:824–33.

    Article  Google Scholar 

  13. Wilkes G, Edge TA, Gannon VPJ, Jokinen C, Lyautey E, Neumann NF, Ruecker N, Scott A, Sunohara M, Topp E, et al. Associations among pathogenic bacteria, parasites, and environmental and land use factors in multiple mixed-use watersheds. Water Res. 2011;45(18):5807–25.

    Article  CAS  PubMed  Google Scholar 

  14. Rapp D, Ross CM, Pleydell EJ, Muirhead RW. Differences in the fecal concentrations and genetic diversities of campylobacter jejuni populations among individual cows in Two dairy herds. Appl Environ Microbiol. 2012;78(21):7564–71.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  15. Carrique-Mas J, Andersson Y, Hjertqvist M, Svensson Å, Torner A, Giesecke J. Risk factors for domestic sporadic campylobacteriosis among young children in Sweden. Scand J Infect Dis. 2005;37(2):101–10.

    Article  PubMed  Google Scholar 

  16. Ailes E, Scallan E, Berkelman RL, Kleinbaum DG, Tauxe RV, Moe CL. Do differences in risk factors, medical care seeking, or medical practices explain the geographic variation in campylobacteriosis in Foodborne Diseases Active Surveillance Network (FoodNet) sites? Clin Infect Dis. 2012;54(suppl_5):S464–71.

    Article  PubMed  Google Scholar 

  17. Krieger N, Williams DR, Moss NE. MEASURING SOCIAL CLASS IN US PUBLIC HEALTH RESEARCH: Concepts, Methodologies, and Guidelines. Annu Rev Public Health. 1997;18(1):341.

    Article  CAS  PubMed  Google Scholar 

  18. NASS QuickStats. [https://quickstats.nass.usda.gov/]. Accessed 3 May 2016.

  19. U.S. Census Bureau. National Intercensal Estimates (2000-2010). Table 1. Intercensal Estimates of the Resident Population for the United States, Regions, States, and Puerto Rico. http://webcache.googleusercontent.com/search?q=cache:LbDjDfLs_ZcJ. www.census.gov/popest/data/intercensal/state/tables/ST-EST00INT-01.xls+&cd=1&hl=en&ct=clnk&gl=us. Accessed 7 Jul 2016.

  20. Samuel MC, Vugia DJ, Shallow S, Marcus R, Segler S, McGivern T, Kassenborg H, Reilly K, Kennedy M, Angulo F, et al. Epidemiology of sporadic campylobacter infection in the United States and declining trend in incidence, FoodNet 1996–1999. Clin Infect Dis. 2004;38:S165–74.

    Article  PubMed  Google Scholar 

  21. Copeland VC. African Americans: disparities in health care access and utilization. Health Soc Work. 2005;30(3):265–70.

    Article  PubMed  Google Scholar 

  22. Quinlan JJ. Foodborne illness incidence rates and food safety risks for populations of Low socioeconomic status and minority race/ethnicity: a review of the literature. Int J Environ Res Public Health. 2013;10(8):3634–52.

    Article  PubMed  PubMed Central  Google Scholar 

  23. Patrick ME, Mahon BE, Zansky SM, Hurd S, Scallan E. Riding in shopping carts and exposure to Raw meat and poultry products: prevalence of, and factors associated with, this risk factor for < i > salmonella</i > and < i > campylobacter</i > infection in children younger than 3 years. J Food Prot. 2010;73(6):1097–100.

    Article  PubMed  Google Scholar 

  24. Davis MA, Moore DL, Baker KNK, French NP, Patnode M, Hensley J, MacDonald K, Besser TE. Risk factors for campylobacteriosis in Two Washington State counties with high numbers of dairy farms. J Clin Microbiol. 2013;51(12):3921–7.

    Article  PubMed  PubMed Central  Google Scholar 

  25. Krieger N, Chen JT, Waterman PD, Rehkopf DH, Subramanian SV. Painting a truer picture of US socioeconomic and racial/ethnic health inequalities: the public health disparities geocoding project. Am J Public Health. 2005;95(2):312–23.

    Article  PubMed  PubMed Central  Google Scholar 

  26. Darcey VL, Quinlan JJ. Use of geographic information systems technology to track critical health code violations in retail facilities available to populations of different socioeconomic status and demographics. J Food Prot. 2011;74(9):1524–30.

    Article  PubMed  Google Scholar 

  27. Bemis KRJL. Socioeconomic Status and Campylobacteriosis, Connecticut, USA, 1999–2009. Emerg Infect Dis. 2014;20(7):1240–2.

    Article  PubMed  PubMed Central  Google Scholar 

  28. Allen H, Wright BJ, Harding K, Broffman L. The role of stigma in access to health care for the poor. Milbank Q. 2014;92(2):289–318.

    Article  PubMed  PubMed Central  Google Scholar 

  29. Whiley H, van den Akker B, Giglio S, Bentham R. The role of environmental reservoirs in human campylobacteriosis. Int J Environ Res Public Health. 2013;10(11):5886–907.

    Article  PubMed  PubMed Central  Google Scholar 

  30. Green CG, Krause DO, Wylie JL. Spatial analysis of campylobacter infection in the Canadian province of Manitoba. Int J Health Geogr. 2006;5:2–14.

    Article  PubMed  PubMed Central  Google Scholar 

  31. Friedman CR, Hoekstra RM, Samuel M, Marcus R, Bender J, Shiferaw B, Reddy S, Ahuja SD, Helfrick DL, Hardnett F, et al. Risk factors for sporadic campylobacter infection in the United States: a case–control study in FoodNet sites. Clin Infect Dis. 2004;38:S285–96.

    Article  PubMed  Google Scholar 

  32. USDA. In: Service NAS, editor. Poultry - Production and Value 2013 Summary. 2014.

    Google Scholar 

  33. Stern NJ, Fedorka-Cray P, Bailey JS, Cox NA, Craven SE, Hiett KL, Musgrove MT, Ladely S, Cosby D, Mead GC. Distribution of campylobacter spp. In selected U.S. Poultry production and processing operations. J Food Prot. 2001;64(11):1705–10.

    Article  CAS  PubMed  Google Scholar 

  34. Jones K. Campylobacters in water, sewage and the environment. J Appl Microbiol. 2001;90:68S–79S.

    Article  Google Scholar 

  35. Vereen Jr E, Lowrance RR, Jenkins MB, Adams P, Rajeev S, Lipp EK. Landscape and seasonal factors influence salmonella and campylobacter prevalence in a rural mixed use watershed. Water Res. 2013;47(16):6075–85.

    Article  CAS  PubMed  Google Scholar 

  36. Jones K, Hobbs A. Campylobacters and faecal indicators in streams and a small river subject to farm run-off. In: Newell DG, Ketley JM, Feldman RA, editors. Campylobacters, Helicobacters, and Related Organisms. 1996.

    Google Scholar 

  37. Dungan RS. Estimation of infectious risks in residential populations exposed to airborne pathogens during center pivot irrigation of dairy wastewaters. Environ Sci Technol. 2014;48(9):5033–42.

    Article  CAS  PubMed  Google Scholar 

  38. Williams DL, Breysse PN, McCormack MC, Diette GB, McKenzie S, Geyh AS. Airborne cow allergen, ammonia and particulate matter at homes vary with distance to industrial scale dairy operations: an exposure assessment. Environ Health. 2011;10:72.

    Article  PubMed  PubMed Central  Google Scholar 

  39. USDA. In: Service NAS, editor. Milk Production, Disposition, and Income 2013 Summary. 2014.

    Google Scholar 

  40. Halbert LW, Kaneene JB, Ruegg PL, Warnick LD, Wells SJ, Mansfield LS, Fossler CP, Campbell AM, Geiger-Zwald AM. Evaluation of antimicrobial susceptibility patterns in Campylobacter spp isolated from dairy cattle and farms managed organically and conventionally in the midwestern and northeastern United States. J Am Vet Med Assoc. 2006;228(7):1074–81.

    Article  CAS  PubMed  Google Scholar 

  41. Sato K, Bartlett PC, Kaneene JB, Downes FP. Comparison of prevalence and antimicrobial susceptibilities of campylobacter spp. Isolates from organic and conventional dairy herds in Wisconsin. Appl Environ Microbiol. 2004;70(3):1442–7.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

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Acknowledgments

We would like to acknowledge Mary Patrick and Olga Henao for their comments during the analysis and article review process. We would also like to acknowledge the Foodborne Diseases Active Surveillance Network Working Group for the collection of the surveillance data used in this analysis.

Funding

This work was supported by the Centers for Disease Control and Prevention (CDC) [5U50CK000316]. The contents of this article are solely the responsibility of the authors and do not necessarily represent the official views of the CDC.

Availability of data and materials

The socioeconomic, environmental and agricultural data used in this study are publicaly available data and were obtained from the 2010 Census of Population and Housing, the 2011 American Community Survey and the 2007 U.S. Census of Agriculture. Table 1 of this manuscript describes the precise data files from these surveys where authors can go to download the data. The salmonella case data used in this study were obtained from the U.S. Foodborne Diseases Active Surveillance Network (FoodNet), which is funded and maintained by the U.S. Centers for Disease Control and Prevention (CDC). These data are not publicly available.

Authors’ contributions

RERG contributed to the study design; wrote the first draft and organized all revisions; and approved the final version. RCC played a major role in data cleaning, data input, and data analysis; wrote statistics sections; contributed to the revision process; and approved the final version. CJ played a major role in data analysis; wrote sections of the manuscript; contributed to the revision process; and approved the final version. AP contributed to the study design; collected and cleaned the FoodNet data; contributed to the revision process; and approved the final version. DB conceived the study design; managed the FoodNet surveillance system and FoodNet data collection; contributed to the revision process; and approved the final version. PR contributed to the study design; managed the FoodNet surveillance system and FoodNet data collection; contributed to the revision process; and approved the final version. BH collected and cleaned FoodNet surveillance data; contributed to the revision process; and approved the final version. BW contributed to the study design; collected and cleaned FoodNet surveillance data; contributed to the revision process; and approved the final version. JD, TL, MT-D, JYH, SG and KS collected and cleaned FoodNet surveillance data; contributed to the revision process; and approved the final version. MTL played a role in data analysis; contributed to the revision process; and approved the final version. ARS organized and conceived the collaboration; conceived the study design and supervised the study; contributed heavily to the writing and revision process; and approved the final version. All authors have agreed to be accountable for all aspects of the work.

Competing interests

The authors declare that they have no competing interests.

Consent for publication

No details, images or videos relating to specific individuals were included in this manuscript.

Ethics approval and consent to participate

This study included surveillance data on human cases of salmonellosis that were reported to the U.S. FoodNet program. The data were de-identified, and therefore, the study was exempt from ethics approval by the Maryland Department of Health and Mental Hygiene.

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Correspondence to Amy R. Sapkota.

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Rosenberg Goldstein, R.E., Cruz-Cano, R., Jiang, C. et al. Association between community socioeconomic factors, animal feeding operations, and campylobacteriosis incidence rates: Foodborne Diseases Active Surveillance Network (FoodNet), 2004–2010. BMC Infect Dis 16, 354 (2016). https://0-doi-org.brum.beds.ac.uk/10.1186/s12879-016-1686-9

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