Hostname: page-component-78c5997874-lj6df Total loading time: 0 Render date: 2024-11-10T12:30:21.008Z Has data issue: false hasContentIssue false

An ecological analysis of pertussis disease in Minnesota, 2009–2013

Published online by Cambridge University Press:  02 September 2015

P. Y. IROH TAM*
Affiliation:
University of Minnesota Masonic Children's Hospital, Minneapolis, MN, USA
J. S. MENK
Affiliation:
Clinical and Translational Science Institute, University of Minnesota, Minneapolis, MN, USA
J. HUGHES
Affiliation:
University of Minnesota School of Public Health, Minneapolis, MN, USA
S. L. KULASINGAM
Affiliation:
University of Minnesota School of Public Health, Minneapolis, MN, USA
*
*Author for correspondence: Dr P. Y. Iroh Tam, 3-210 MTRF, 2001 6th St SE, Minneapolis, MN 55455, USA. (Email: irohtam@umn.edu)
Rights & Permissions [Opens in a new window]

Summary

The increase in pertussis cases in Minnesota in the last decade has been mainly attributed to the switch from whole cell to acellular pertussis [as part of the diphtheria, tetanus and acellular pertussis vaccine (DTaP)]. It is unclear, however, to what degree community-level risk factors also contribute. Understanding these factors can help inform public health policy-makers about where else to target resources. We performed an ecological analysis within Minnesota to identify risk factors at the county level using a Bayesian Poisson generalized linear areal model to account for spatial dependence. Univariate analyses suggested an association between increased pertussis rates at the county level and white maternal ethnicity, being US born, urban counties and average household size. In the multivariable analysis, the rate of pertussis was 1·79 times greater for urban vs. rural counties and 4·75 times greater for counties with a one-person larger average household size. Pertussis rates in counties with higher (i.e. 4+DTaP) receipt in children were 0·97 times lower. Examining county-level factors associated with varying levels of pertussis may help identify those counties that would most benefit from targeted interventions and increased resource allocation.

Type
Original Papers
Creative Commons
This is a work of the U.S. Government and is not subject to copyright protection in the United States.
Copyright
Copyright © Cambridge University Press 2015

INTRODUCTION

The United States has seen a surge in reported pertussis cases over the past decade [1, Reference Rohani and Drake2]. In 2012 the largest outbreak of pertussis in 50 years occurred, with over 41 000 reported cases nationally [3]. That year, Minnesota had the third highest incidence of pertussis of any state in the nation, with 4144 cases of pertussis reported, equivalent to 75/100 000 population [3]. Rates this high had not been reported for the state since 1938 [4].

Reasons for the resurgence have centred around the diphtheria, tetanus, and acellular pertussis (DTaP) vaccine: particularly under-immunization [Reference Jackson and Rohani5, Reference Smith, Chu and Barker6], parental refusal of vaccination [Reference Atwell7, Reference Glanz8], and waning immunity provided by the acellular pertussis formulation [Reference Koepke9, Reference Witt, Katz and Witt10]. Efforts to protect infants, the group with the highest risk of death or serious morbidity, have focused on ‘cocooning’ the infant by immunizing the surrounding caregiver group [Reference Healy, Rench and Baker11Reference Walter13], as well as by immunizing peripartum women [Reference Castagnini14, Reference Healy, Rench and Baker15]. However, less attention has been directed at determining environmental and social factors that may also contribute to the increased rates of pertussis.

Ecological analyses can be used to identify associations between aggregate demographic factors and disease [Reference Tiensin16], as well as improve our understanding of varying pertussis rates, transmission dynamics, immunity, and vaccine effectiveness [Reference Wolf17]. Ecological analyses have been conducted to examine the effect of pertussis vaccine coverage on county-level pertussis incidence rates in California during the 2010 pertussis epidemic [Reference Duffy and Shea18]. However, few have used an ecological approach to identify demographic and socioeconomic variables associated with higher county-level pertussis rates within a state. The objective of our study was to describe the geographical distribution of pertussis rates in Minnesota, and to identify county-level public health, education, economic and demographic indicators that are associated with increased county-specific pertussis rates.

METHODS

Data collection

County-level data were collected for 61 variables, including 20 demographic, 17 education, 14 health, seven socioeconomic, and three vaccination status indicators from various data sources (see Appendix). Sources included the US Census [19], the Minnesota Department of Health (MDH) [20], the Minnesota Board of Medical Practice (M. Chu, written communication), the Minnesota Geospatial Information Office [21], and the National Center for Health Statistics [Reference Ingram and Franco22]. Data used in this analysis ranged from estimates for individual years, to those based on a 5-year span (2009–2013), in order to yield estimates for all 87 counties within Minnesota. Separate sources for different county-level variables were combined into a single dataset for analysis, based on US Census data that showed that the population was fairly static over the 5-year period [19]. Data used in this analysis were assumed to provide a reasonable estimate of the population values for 2009 to 2013. In particular, when data for a given variable were available for a single year (e.g. 2011), we assumed it was representative of the other years (e.g. 2009, 2010, 2012, and 2013).

County-specific explanatory variables were collected or computed as percentages by county to account for population size. If an explanatory variable was available only for one year, this value was used and assumed representative of the 5-year period. Five-year data were available as a 5-year median, 5-year average, or 5-year percentages where the median, average or percentage was computed using the cumulative data over 5 years.

Variables examined

Pertussis cases were obtained from the MDH [20] at the county-level and encompassed all ages, and included patients who met the case definition of pertussis: clinical symptoms with paroxysms of coughing, inspiratory whoop, or post-tussive vomiting, or apnoea in infants aged <1 year; laboratory isolation of Bordetella pertussis from a clinical specimen, or positive PCR for B. pertussis; and contact with a laboratory-confirmed case of pertussis. County-level demographic indicators examined included the following: population density, average household size, natural rate of population increase, number of schools, and urban/rural designation as proxies for crowding. Urban and rural designation followed the National Center for Health Statistics classification [Reference Ingram and Franco22]. Urban areas included large central/large fringe metropolitan (populations of ⩾1 million) to small metropolitan (populations <250 000). Rural, non-metropolitan areas included micropolitan (containing at least one urban cluster of 10 000–49 999 inhabitants) and non-core (most rural area) [Reference Ingram and Franco22].

Socioeconomic indicators included median income, employment, medical insurance, enrolment in medical assistance programmes, as well as educational attainment, maternal educational attainment, single-parent households, English only spoken at home, teen birth rates, and births to unmarried mothers. Asthma hospitalization was also considered a socioeconomic indicator, based on documented disparities in asthma management and self-efficacy by race, ethnicity and income [Reference Smith23]. Age data were for 0–4, 5–9, 10–19, and ⩾65 years age groups.

Children aged <5 years were noted to have completed the vaccine series if they had received the recommended DTaP vaccine series by age 35 months which, if the routine immunization schedule is followed, means receipt of four doses of DTaP by 18 months. Vaccine exemption rates were not publicly available at the county level. Varicella vaccination was used as a proxy for vaccine exemption, given previous literature that showed that this was the most common vaccine exempted [Reference Salmon and Siegel24]. We also included adult and childhood obesity, based on studies of a possible link between infection and obesity [Reference Hegde and Dhurandhar25].

Statistical analysis

We applied the sparse spatial generalized linear mixed model (SGLMM) of Hughes & Haran [Reference Hughes and Haran26]. The sparse SGLMM allowed us to account for spatial dependence and spatial confounding in the counties. Spatial dependence is defined as counties that are in close proximity having similar outcomes. Spatial confounding is a type of redundancy for one or more risk factors [Reference Clayton, Bernardinelli and Montomoli27]. Failure to account for spatial dependence can result in confidence intervals that are too narrow, while failure to address spatial confounding can result in confidence intervals that are too wide. By using the SGLMM we address the former, which reduces the possibility of concluding that unimportant factors are in fact important, while addressing the latter, reducing the possibility of concluding that important factors are unimportant. Further, we employed the sparse SGLMM for (conditionally independent) Poisson outcomes. This model assumes that the outcomes are independent and Poisson distributed, conditional on a collection of spatially dependent random effects, where there is exactly one random effect for each areal unit (in this case, each county).

The raw incidence rate of pertussis was calculated per 10 000 person-years using the 2011 population with the assumption that the population is stable over the 5 years and that the mid-point population is the same population at risk for the entire 5 years. For the univariate and multivariable analysis, the response variable was the total number of cases reported for the county over the 5-year period; the 2011 county population was included as an offset. This also reduced zero counts for some counties in individual years. Bonferroni-corrected credible intervals were computed for the 67 separate comparisons, to maintain an overall significance level of 0·05 for all of the intervals (with an associated credible interval of 99·9%). This reduces the chance of concluding there is a true association, when there is in fact no association. The Bonferroni correction is conservative, i.e. we are less likely to make an incorrect conclusion compared to alternative methods for multiple comparison adjustment at the cost of reduced power for detecting a real effect. Univariate analyses were used to identify variables for inclusion in the multivariable analysis based on statistical significance and included urban/rural designation, maternal educational attainment, percentage of children who received ⩾4 doses of DTaP, health insurance, number of family physicians and paediatricians per 100 000 persons, and size of household. Commonly considered confounders such as race/ethnicity were also controlled for in the multivariable analysis, by being included in the model as a percentage of each group. Data were analysed with R software version 3.0.3 (R Foundation for Statistical Computing, Austria); the R package used to perform the SGLMM was ‘ngspatial’ [Reference Hughes28].

This study used de-identified publically available data and was considered exempt by the University of Minnesota Institutional Review Board.

RESULTS

Between 2009 and 2013 there were 8117 cases of pertussis reported in Minnesota. The incidence rate per 10 000 person-years ranged from 0 in Lincoln County, to 9·52 in Benton County (Fig. 1). The five counties with highest pertussis incidence rates were Benton, Wright, Sibley, Stearns, and Freeborn, and the five with the lowest pertussis incidence rates were Lincoln, Pennington, Becker, Martin and Le Sueur (Table 1).

Fig. 1. Map of pertussis county-level incidence rates per 10 000 person-years in Minnesota, 2009–2013.

Table 1. The five Minnesota counties with the lowest and highest pertussis incidence rates per 10 000 person-years, 2009–2013

Table 2 summarizes the results of the univariate analyses. Fourteen factors were associated with an increase in pertussis incidence, including younger age, population density, natural rate of increase in the population, white maternal race, US born, English only spoken at home, high maternal education, median income and proportion in labour force, among others. Two factors were associated with a substantial increase in pertussis rates: (1) urban-designated counties had a pertussis rate 2·32 times higher than rural-designated counties, and (2) a 1-unit increase in average household size was associated with a pertussis rate 2·62 times higher.

Table 2. Univariate regression analysis of the relationship between demographic and social indicators and pertussis incidence rate

RR, Rate ratio; CrI, credible interval.

* Credible intervals not including 1 were considered statistically significant

To two decimal places, except where statistical significance is shown.

Factors associated with a decrease in pertussis incidence included older age, foreign born, language other than English spoken at home, lower educational attainment and lower maternal educational attainment, uninsured and single-parent households, among others (Table 2). Of the sociodemographic factors associated with a decrease in pertussis incidence, there were two notable associations: a 1-unit increase in the number of family physicians per 100 000 was associated with a pertussis incidence 100 times lower, and a 1-unit increase in the density of schools in a county (school per 1000 persons) was associated with a pertussis incidence that was 1·32 times lower. A similar association was noted at each school level, where a 1-unit increase in density of elementary schools per 1000 persons was associated with a pertussis incidence that was 2·32 times lower; an incidence rate that was 1·59 times lower for each middle school added per 1000 persons; and an incidence rate that was 3·28 times lower for each high school added per 1000 persons. No significant association was found between pertussis counts and the number of pediatricians per 100 000, but the point estimates were similar to that of family physicians.

In the multivariable analysis (Table 3), urban county designation (compared to rural county) remained significant and larger average household size was also associated with higher pertussis rates, with rate ratios of 1·79 [99·9% credible interval (CrI) 1·43–2·31] and 4·75 (99·9% CrI 1·10–23·97), respectively. Counties with higher rates of 4+ DTaP vaccine receipt in children aged 24–35 months were associated with lower incidence rates of pertussis, with a rate ratio of 0·97 (99·9% CrI 0·96–0·99) for a 1% higher prevalence of 4+ DTaP vaccine receipt.

Table 3. Multivariable regression analysis of the relationship between demographics, social indicators and pertussis incidence rate

RR, Rate ratio; CrI, credible interval.

* Credible intervals not including 1 were considered statistically significant.

Although an association was noted in the univariate analysis between county maternal education level and the pertussis incidence rate, in the multivariable analysis these associations were no longer significant.

DISCUSSION

In this ecological analysis, we identified several demographic and social factors potentially associated with varying incidence rates of pertussis in Minnesota. Of note, higher pertussis rates were associated with urban county designation and counties with larger average household size. Lower pertussis rates were significantly associated with receipt of the DTaP vaccine series, where counties with a 1% higher percentage of children aged 24–35 months who received 4+ DTaP had 0·97 times the incidence rate of pertussis. This finding is in keeping with other studies that show that unvaccinated or under-vaccinated children are at high risk for pertussis and increase the likelihood of transmission in their communities [Reference Atwell7, Reference Glanz8]. Interestingly, our univariate analysis revealed a statistically significant association between a decrease in the pertussis incidence rate with an increase in density of family physicians, but not with paediatricians, even though point estimates were similar. The reason for this difference is partially due to rural counties who have no paediatrician indicated in the data whereas every county has at least one family physician. The difference in provider-type density by county is noteworthy, as vaccination rates for family physicians have been shown to be significantly lower (45–88%) than for paediatricians (85–99%) [Reference Daley29, Reference Kempe30]. Studies have attributed this to less family physician knowledge regarding vaccination recommendations and their concerns about vaccine safety, among other reasons [Reference Daley29, Reference Kempe30]. In the multivariable analysis, county family physician and paediatrician density were no longer significantly associated with pertussis incidence rate, although the rate ratios were similar and indicated a trend towards reduced rates of pertussis in counties with a higher density of either physician.

Our univariate analysis found a possible association between low and medium maternal education and a decrease in the pertussis incidence rate, but paradoxically high maternal education was associated with an increase in pertussis incidence rate. The association with high maternal education and an increase in pertussis incidence rate at the county level is consistent with other studies that have demonstrated an association between high maternal education with non-vaccination [Reference Hull, McIntyre and Sayer31], although the univariate association is likely to be confounded by the urban/rural classification of a county. This may also be due to increased uncertainty about the benefits of immunization in more educated parents [Reference Forrest, Burgess and McIntyre32], or possible decreased reporting of providers in these areas to immunization registries [Reference Hull, McIntyre and Sayer31].

Under-vaccination has been associated with low maternal education [Reference Hull, McIntyre and Sayer31], and lack of vaccine uptake has been linked to low socioeconomic status, country of origin, and single parenthood, among others [Reference Smith23, Reference Hull, McIntyre and Sayer31]. While there is substantial literature documenting poorer health indices in minority and immigrant families [Reference Healy33], and socioeconomic and racial disparities in vaccination uptake [Reference Dempsey34], we did not find any of these to be associated with pertussis incidence rate in Minnesota in our multivariable analysis. However, this may be due to the fact that minority populations are small in Minnesota and any association may be attenuated at the county level due to the large prevalence of whites.

Urbanization, household size and crowding have also been shown to be associated with similarly transmitted infections such as measles [Reference Hersh35], as well as a greater risk of acquiring other respiratory tract infections such as tuberculosis and respiratory syncytial virus [Reference Bockova36, Reference Wingfield37]. Household size has been recognized as a determinant of health given that the household environment can play an important role in the transmission of respiratory pathogens, and that the collective behaviours of household members can affect transmission at an individual level [Reference Delabre38]. Hence, household size as well as household age composition and how they vary in different counties may be important to consider when targeting specific counties for intervention [Reference Laskowski39].

Some of the limitations of this study are due to the nature of ecological analyses, which in general can describe associations of disease occurrence at an aggregate level such as the county level used in this analysis. These associations, however, may not be present at the individual level. There could also be variation in the completeness and representativeness of the county-level data used in this analysis, even though we tried to minimize this by using state- and federal-level data from surveys that have been shown to have high coverage and completion rates. As the goal of this study was to provide a statewide analysis of potential ecological factors associated with pertussis disease, we did not explore predictive values of identified factors, which would be the next step. Our data did not include age breakdown of pertussis cases, hence we were unable to examine in detail the role of age including impact of having more infants in a given county. We were also unable to examine parental vaccine refusal due to the limited availability of these data. Our use of varicella vaccination as a proxy for vaccine exemption was based on other published literature [Reference Salmon and Siegel24]; but, this approach could potentially overestimate how many children did not receive DTaP. However, immunization uptake for all four doses of DTaP varied widely between counties, suggesting that other factors besides parental refusal may play a role in pertussis rates. Our use of the SGLMM model does not address the problem of multicollinearity that arises from strong correlation between predictors. In particular, although the model alleviates multicollinearity between the fixed-effects predictors and the random effects, the fixed-effects predictors may exhibit multicollinearity on their own. Another limitation of this analysis is that census data for some variables at the county level were for a 5-year span, which limited our ability to compare different epidemics within a 5-year period, and also may not adequately account for changes in minor and major outbreaks, and sporadic cases identified in the intervening period. Further, the use of data from different sources, such as we have done in this analysis, is a limitation since there may be differences in the methods used, population studied and completeness of reporting. Finally, increasing awareness of pertussis leading to changes in testing patterns was also not accounted for in this analysis.

CONCLUSION

Ecological analyses can be used to identify factors that are associated with geographically varying incidence rates of pertussis to inform public health interventions. This analysis confirms the need to maintain high vaccine coverage and completion of the pertussis vaccine series, and highlights factors to consider, such as dense populations on both a large (cities/urban areas) and small (large families/day cares/schools) scale, when targeting counties for intensified surveillance and interventions.

APPENDIX. Sources for pertussis variables used in the analysis

ACKNOWLEDGEMENTS

We thank Joe Koopmeiners, Eleena Iissaka, Andrew Nicklawsky and Michael O'Connell for assistance with statistical analysis. Research reported in this publication was supported by the National Center for Advancing Translational Sciences of the National Institutes of Health Award Number UL1TR 000 114.

Research reported in this publication was supported by the National Center for Advancing Translational Sciences of the National Institutes of Health Award Number UL1TR 000 114.

DECLARATION OF INTEREST

None.

Footnotes

MDH, Minnesota Department of Health; MGIO, Minnesota Geospatial Information Office; MBMP, Minnesota Board of Medical Practice; NCHS, National Center for Health Statistics; WIC, Women, Infants and Children.

References

REFERENCES

1. Centers for Disease Control and Prevention. Updated recommendations for use of tetanus toxoid, reduced diphtheria toxoid, and acellular pertussis (Tdap) vaccine in adults aged 65 years and older – Advisory Committee on Immunization Practices (ACIP), 2012. Morbidity and Mortality Weekly Report 2012; 61: 468470.Google Scholar
2. Rohani, P, Drake, JM. The decline and resurgence of pertussis in the US. Epidemics 2011; 3: 183188.Google Scholar
3. Centers for Disease Control and Prevention. Pertussis (whooping cough). 2012 (http://www.cdc.gov/pertussis/outbreaks/about.html). Accessed 5 November 2014.Google Scholar
4. MDH. Pertussis (whooping cough). 2012 (http://www.health.state.mn.us/divs/idepc/diseases/pertussis/index.html). Accessed 5 November 2014.Google Scholar
5. Jackson, DW, Rohani, P. Perplexities of pertussis: recent global epidemiological trends and their potential causes. Epidemiology and Infection 2014; 142: 672684.Google Scholar
6. Smith, PJ, Chu, SY, Barker, LE. Children who have received no vaccines: who are they and where do they live? Pediatrics 2004; 114: 187195.CrossRefGoogle ScholarPubMed
7. Atwell, JE, et al. Nonmedical vaccine exemptions and pertussis in California, 2010. Pediatrics 2013; 132: 624630.CrossRefGoogle ScholarPubMed
8. Glanz, JM, et al. Parental refusal of pertussis vaccination is associated with an increased risk of pertussis infection in children. Pediatrics 2009; 123: 14461451.CrossRefGoogle ScholarPubMed
9. Koepke, R, et al. Estimating the effectiveness of tetanus-diphtheria-acellular pertussis vaccine (Tdap) for preventing pertussis: evidence of rapidly waning immunity and difference in effectiveness by Tdap brand. Journal of Infectious Diseases 2014; 210: 942953.Google Scholar
10. Witt, MA, Katz, PH, Witt, DJ. Unexpectedly limited durability of immunity following acellular pertussis vaccination in preadolescents in a North American outbreak. Clinical Infectious Diseases 2012; 54: 17301735.Google Scholar
11. Healy, CM, Rench, MA, Baker, CJ. Implementation of cocooning against pertussis in a high-risk population. Clinical Infectious Diseases 2011; 52: 157162.Google Scholar
12. Healy, CM, et al. Evaluation of the impact of a pertussis cocooning program on infant pertussis infection. Pediatric Infectious Disease Journal 2015; 34: 2226.Google Scholar
13. Walter, EB, et al. Cocooning infants: Tdap immunization for new parents in the pediatric office. Academic Pediatrics 2009; 9: 344347.Google Scholar
14. Castagnini, LA, et al. Impact of maternal postpartum tetanus and diphtheria toxoids and acellular pertussis immunization on infant pertussis infection. Clinical Infectious Diseases 2012; 54: 7884.CrossRefGoogle ScholarPubMed
15. Healy, CM, Rench, MA, Baker, CJ. Importance of timing of maternal combined tetanus, diphtheria, and acellular pertussis (Tdap) immunization and protection of young infants. Clinical Infectious Diseases 2013; 56: 539544.CrossRefGoogle ScholarPubMed
16. Tiensin, T, et al. Ecologic risk factor investigation of clusters of avian influenza A (H5N1) virus infection in Thailand. Journal of Infectious Diseases 2009; 199: 17351743.CrossRefGoogle ScholarPubMed
17. Wolf, ER, et al. Impact of a pertussis epidemic on infant vaccination in Washington state. Pediatrics 2014; 134: 456464.CrossRefGoogle ScholarPubMed
18. Duffy, E, Shea, K. Effect of county-level pertussis vaccine coverage on county-level pertussis incidence rates in California during the 2010 pertussis epidemic. Poster, ID Week. San Diego, CA, 2012.Google Scholar
20. Minnesota Department of Health (http://www.health.state.mn.us/pertussis). Accessed 22 April 2014.Google Scholar
21. Minnesota Geospatial Information Office (http://www.mngeo.state.mn.us/chouse/metalong.html#admin). Accessed 5 November 2014.Google Scholar
22. Ingram, DD, Franco, SJ. NCHS urban-rural classification scheme for counties. Vital Health Statistics 2012; 2.Google Scholar
23. Smith, LA, et al. Rethinking race/ethnicity, income, and childhood asthma: racial/ethnic disparities concentrated among the very poor. Public Health Reports 2005; 120: 109116.Google Scholar
24. Salmon, DA, Siegel, AW. Religious and philosophical exemptions from vaccination requirements and lessons learned from conscientious objectors from conscription. Public Health Reports 2001; 116: 289295.CrossRefGoogle ScholarPubMed
25. Hegde, V, Dhurandhar, NV. Microbes and obesity – interrelationship between infection, adipose tissue and the immune system. Clinical Microbiology and Infection 2013; 19: 314320.CrossRefGoogle ScholarPubMed
26. Hughes, J, Haran, M. Dimension reduction and alleviation of confounding for spatial generalized linear mixed models. Journal of the Royal Statistical Society, Series B 2013; 75: 139159.Google Scholar
27. Clayton, DG, Bernardinelli, L, Montomoli, C. Spatial correlation in ecological analysis. International Journal of Epidemiology 1993; 22: 11931202.Google Scholar
28. Hughes, J. ngspatial: a package for fitting the centered autologistic and sparse spatial generalized linear mixed models for areal data. 2014. (http://www.biostat.umn.edu/~johnh/pdf/ngspatial.pdf). Accessed 29 October 2014.CrossRefGoogle Scholar
29. Daley, MF, et al. Human papillomavirus vaccination practices: a survey of US physicians 18 months after licensure. Pediatrics 2010; 126: 425433.Google Scholar
30. Kempe, A, et al. Adoption of rotavirus vaccination by pediatricians and family medicine physicians in the United States. Pediatrics 2009; 124: e809816.Google Scholar
31. Hull, BP, McIntyre, PB, Sayer, GP. Factors associated with low uptake of measles and pertussis vaccines – an ecologic study based on the Australian Childhood Immunisation Register. Australian and New Zealand Journal of Public Health 2001; 25: 405410.CrossRefGoogle ScholarPubMed
32. Forrest, JM, Burgess, MA, McIntyre, PB. Factors influencing vaccination uptake. Workshop report. Current Australian research on the behavioural, social and demographic factors influencing immunisation, Royal Alexandra Hospital for Children, Sydney, March 1998. Communicable diseases intelligence 2000; 24: 5153.Google Scholar
33. Healy, CM, et al. Pertussis serostatus among neonates born to Hispanic women. Clinical Infectious Diseases 2006; 42: 14391442.Google Scholar
34. Dempsey, A, et al. Worsening disparities in HPV vaccine utilization among 19–26 year old women. Vaccine 2011; 29: 528534.CrossRefGoogle ScholarPubMed
35. Hersh, BS, et al. The geographic distribution of measles in the United States, 1980 through 1989. Journal of the American Medical Association 1992; 267: 19361941.Google Scholar
36. Bockova, J, et al. Respiratory syncytial virus infection in Navajo and White Mountain Apache children. Pediatrics 2002; 110: e20.Google Scholar
37. Wingfield, T, et al. The seasonality of tuberculosis, sunlight, vitamin D, and household crowding. Journal of Infectious Diseases 2014; 210: 774783.Google Scholar
38. Delabre, RM, et al. Risk factors of pandemic influenza A/H1N1 in a prospective household cohort in the general population: results from the CoPanFlu-France cohort. Influenza and Other Respiratory Viruses 2015; 9: 4350.Google Scholar
39. Laskowski, M, et al. The impact of demographic variable on disease spread: influenza in remote communities. Nature 2011; 1: 17.Google Scholar
Figure 0

Fig. 1. Map of pertussis county-level incidence rates per 10 000 person-years in Minnesota, 2009–2013.

Figure 1

Table 1. The five Minnesota counties with the lowest and highest pertussis incidence rates per 10 000 person-years, 2009–2013

Figure 2

Table 2. Univariate regression analysis of the relationship between demographic and social indicators and pertussis incidence rate

Figure 3

Table 3. Multivariable regression analysis of the relationship between demographics, social indicators and pertussis incidence rate

Figure 4

APPENDIX. Sources for pertussis variables used in the analysis