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Health Consequences of Religious and Philosophical Exemptions From Immunization Laws: Individual and Societal Risk of Measles

Health Consequences of Religious and Philosophical Exemptions From Immunization Laws: Individual... Abstract Context All US states require proof of immunization for school entry. Exemptions are generally offered for medical, religious, or philosophical reasons, but the health consequences of claiming such exemptions are poorly documented. Objectives To quantify the risk of contracting measles among individuals claiming religious and/or philosophical exemptions from immunization (exemptors) compared with vaccinated persons, and to examine the risk that exemptors pose to the nonexempt population. Design, Setting, and Participants Population-based, retrospective cohort study of data from 1985 through 1992, collected by the Measles Surveillance System of the Centers for Disease Control and Prevention, as well as from annual state immunization program reports on prevalence of exemptors and vaccination coverage. The study group was restricted to individuals aged 5 to 19 years. To empirically determine and quantify community risk, a mathematical model was developed that examines the spread of measles through communities with varying proportions of exemptors and vaccinated children. Main Outcome Measures Relative risk of contracting measles for exemptors vs vaccinated individuals based on cohort study data. Community risk of contracting measles derived from a mathematical model. Results On average, exemptors were 35 times more likely to contract measles than were vaccinated persons (95% confidence interval, 34-37). Relative risk varied by age and year. Comparing the incidence among exemptors with that among vaccinated children and adolescents during the years 1985-1992 indicated that the 1989-1991 measles resurgence may have occurred 1 year earlier among exemptors. Mapping of exemptors by county in California indicated that exempt populations tended to be clustered in certain geographic regions. Depending on assumptions of the model about the degree of mixing between exemptors and nonexemptors, an increase or decrease in the number of exemptors would affect the incidence of measles in nonexempt populations. If the number of exemptors doubled, the incidence of measles infection in nonexempt individuals would increase by 5.5%, 18.6%, and 30.8%, respectively, for intergroup mixing ratios of 20%, 40%, and 60%. Conclusions These data suggest the need for systematic review of vaccine-preventable incidents to examine the effect of exemptors, increased surveillance of the number of exemptors and cases among them, and research to determine the reasons why individuals claim exemptions. Immunizations are among the most cost-effective and successful public health interventions. Due to the high contagion, morbidity, and mortality associated with most vaccine-preventable diseases (VPDs), and the safety, effectiveness, and potential financial savings offered by vaccines, all jurisdictions in the United States have introduced and actively enforce laws that require proof of immunization for school entrance.1-3 Many of these laws were initially written specifically for smallpox and later amended to include other VPDs.4 Although there are no federal laws mandating immunizations, the US Supreme Court has upheld the constitutionality of state vaccination laws. In 1905, the Court ruled in favor of a Massachusetts law; in 1922, the Court specifically addressed vaccination as a prerequisite for school attendance.3 These federal rulings have served as precedents for state court rulings. State immunization laws permit certain exemptions. As of January 1998, all states allow medical exemptions (eg, for individuals who are immunocompromised, have allergic reactions to vaccine constituents, or have moderate or severe illness). To qualify for medical exemptions, parents or guardians must provide a letter or other documentation from a physician. Forty-eight states permit religious exemptions, and 15 states allow philosophical or personal exemptions.5 Such exemptions are defined differently by each state. Texas requires that individuals claiming religious exemptions be a member of a recognized religious group that opposes all immunizations and submit a letter from a faith leader. By contrast, California offers personal beliefs exemptions, which require only a parental affidavit. Persons who claim exemptions from immunizations for any reason may be at increased risk of contracting a VPD compared with immunized persons. In addition, persons who claim philosophical and/or religious exemptions (exemptors) may create some risk to the community because unvaccinated or undervaccinated persons may be a source of transmission. In contrast to medical exemptions, which are due to an intrinsic medical condition, religious and philosophical exemptions are voluntary choices. Exemptors also pose a social equity issue.6 While vaccines cause fewer complications than VPDs, no vaccine is perfectly safe. For most VPDs, "herd immunity," an indirect protection for a community, may be established when a high enough proportion of the population is immunized to interrupt transmission.3 High immunization levels therefore permit some unvaccinated individuals to reap benefits of immunization without facing risks.6 The current success of immunization programs in achieving record-high levels of coverage and record-low levels of VPDs results in many parents being unfamiliar with VPDs. As a result, the desire of some parents to claim exemptions for their children may increase when vaccine coverage is high.7 Since the actual impact of exemptors on disease occurrence has not been well studied, we analyzed risks of exemptors to themselves and to the communities in which they live. Methods Cohort Study Using a population-based, retrospective cohort study design, we quantified the risk of exemptors compared with vaccinated individuals in contracting measles. We identified measles cases among exemptors and vaccinated individuals from 1985 through 1992, using data derived from the Measles Surveillance System of the Centers for Disease Control and Prevention (CDC), Atlanta, Ga. This system receives weekly reports of confirmed measles cases from 53 reporting areas (50 states, New York City, Chicago, and the District of Columbia). The reports include county, age, whether the case was an international importation, vaccination status, and exemption status if unvaccinated.8 We restricted our study to school-aged children and adolescents (aged 5-19 years). We compared the relative risk of contracting measles of exemptors and vaccinated individuals. We estimated the number of exemptors using CDC annual, unpublished State Immunization Reports from 1990 through 1994. These reports provide the "percentage of enrollees with an exemption for 1 or more vaccines." Data submitted in the reports do not distinguish between religious, philosophical, and medical exemptors, so we contacted program managers to discern the types of exemptions. For states not able to identify type of exemptions (n=34 [68%]), we used the overall percentages reported on state surveys, which include medical exemptions (mean average of medical exemptions in the 16 states for which it was possible to identify type of exemption was 0.16). For 1 state (Delaware), which did not report percentage of individuals claiming exemption for any year, we used the average percentage of exemptors for states that did report these data (0.66%). We applied the (mean) average for each state over these 5 years to the period 1985-1992. California provided county-specific data on the percentage of exemptors, which were used in developing the mathematical model. We calculated the number of vaccinated individuals by assuming a 98% national vaccination coverage rate for school-aged children and adolescents, based on unpublished CDC school-survey data of yearly coverage by state and antigen. All states reported at least 98% vaccination coverage among school-aged youth for measles in the period 1985-1992. Sociodemographic variables were not available. We used age-specific population data from the Bureau of the Census to extrapolate the percentages into estimated numbers. Thus, we were able to estimate age-specific measles incidence and the relative risk of measles for exemptors compared with vaccinated persons. Mathematical Model To quantify the risk of contracting measles in communities that have contact with exemptors, we applied a mathematical model to the data from the cohort study (mathematical model available from the authors on request).9 The model examines the spread of disease through a population consisting of different strata or groups. In our application, the model consists of 2 groups: school-aged exemptors and nonexemptors. It is assumed that youth within a given group mix randomly, but exemptors are more likely to be in contact with other exemptors, and nonexemptors are more likely to be in contact with other nonexemptors. The extent to which youth are more likely to make contacts with others from the same group is determined by the intergroup mixing ratio, which may vary between 0 and 1. For example, if the mixing ratio is 0.6, then 60% of the contacts are made with children chosen at random from the entire community (including that child's own group), and the remaining 40% of a child's contacts are made with other children from the same group. When the intergroup mixing ratio is 1, there is random mixing between exemptors and nonexemptors, and when the mixing ratio is 0, there are no contacts between groups. Another important parameter in the model is the transmission probability, which is the probability that a susceptible child becomes infected from a single infected child. This parameter may vary across communities because it depends on socioeconomic factors such as crowding. We assume that the vaccine reduces the transmission probability to each child by a given fraction, which is the vaccine efficacy. The vaccine efficacy in terms of transmission probabilities is defined as 1 minus the ratio of the transmission probability to a vaccinee and a nonvaccinee when both are exposed to a single infected person.10 The estimate of this quantity depends on the assumption about the intergroup mixing ratio: for mixing ratios 0.6, 0.4, and 0.2, the estimated efficacy is 0.62, 0.42, and 0.22, respectively. The vaccine efficacy in the model differs significantly from the traditional definition of vaccine efficacy, which estimates the measles vaccine to be about 90% to 95% efficacious.1 Traditional vaccine efficacy is based on the overall attack rates for a vaccinee and a nonvaccinee during an outbreak. Efficacy also depends on the length of the epidemic period and on vaccine coverage. Estimation of efficacy also may be biased if vaccination is not random or if a vaccinee and a nonvaccinee do not have the same exposure to the infecting agent. Vaccine efficacy based on transmission probabilities, as in the model, standardizes exposure to a single contact with an infected person, so it does not depend on factors such as the vaccination strategy or coverage.9 These 2 measures of vaccine efficacy can be quite different, even if there is no bias, especially if mixing is not random. Our model provides equations that relate the disease attack rate (incidence) during an outbreak to the values of the transmission probabilities and intergroup mixing ratios. These equations are used to estimate the transmission probabilities from the observed attack rates among exemptors and nonexemptors and predict the expected attack rates based on changes in the number of exemptors. To apply this model, we assumed that the population consists of 1000 communities. The distribution of the transmission probabilities over the communities was determined so that the overall numbers of expected cases in exemptors and nonexemptors were close to the observed frequencies. The ratio of transmission probabilities for exemptors and nonexemptors was also determined from the overall attack rates. We developed the model to account for the clustering of exemptors as seen in national and California data. Five percent of the communities were assigned a rather high proportion of exemptors (5%); another 5% of the communities had no exemptors; and the proportion of exemptors in the remaining 90% of the communities was constant (0.21%), which was determined such that the overall proportion of exemptors was the same as in the entire population (0.44%). To empirically determine and quantify the impact of changes in the number of exemptors on the number of measles cases among nonexemptors, we explored various changes in the size of the exempt population: 50% decrease in the number of exemptors (ie, these individuals become vaccinated); and 50%, 100%, 200%, and 300% increases in the number of exemptors. Results United States measles surveillance data indicate that exemptors were at a statistically significant increased risk of contracting measles vs vaccinated individuals for each age group and in every year (Table 1). On average, from 1985 through 1992, for persons aged 5 to 19 years, exemptors were 35 times more likely to contract measles than were vaccinated persons. The relative risk varied greatly by age group and by year, ranging from 4 times the risk of contracting measles for exemptors aged 15 to 19 years compared with vaccinated individuals in 1992, to 170 times the risk in 1988 for those aged 5 to 9 years . Cases among the vaccinated youth were more frequent in the older age categories. Cases among exemptors have a more uniform distribution across age categories (Table 1). Comparing the incidence among school-aged exemptors with that among school-aged vaccinated children and adolescents during the years 1985 through 1992 indicates that the 1989-1991 measles resurgence may have occurred 1 year earlier among exemptors (Figure 1). Mapping of exemptors by county was available for California, where school entry laws allow parents to elect personal belief exemptions from mandatory vaccinations for their children. Overall, approximately 0.5% of children enter kindergarten each year with such exemptions, a value that has remained relatively stable over the past 2 decades. However, the frequency of exemptors is not uniform in schools across the state. In 1995, in 84% of California's public and private schools with kindergartens, the proportion of children entering with exemptions was less than 1%. However, in 12% of schools, 1% to 4% of children entered with exemptions, and in 4% of schools, at least 5% of entrants were exempted. The proportion of exemptors is higher in the northern half of the state and is particularly high along the northern foothills of the Sierra Nevada Mountains and in some central and northern coastal areas. Our mathematical model suggests that changes in the number of exemptors affects measles cases in the nonexempt population (Table 2). The mixing ratio largely determines the impact a particular increase or decrease of exemptors would have on the nonexempt population. For example, if the number of exemptors doubled, then the incidence of measles in the nonexempt population would increase by 5.5%, 18.6%, and 30.8% for intergroup mixing ratios of 20%, 40%, and 60%, respectively. The greater the increase in the number of exemptors, the more effect they have on the nonexempt population. Comment The control of VPDs by means of immunization requirements necessitates careful balance of individual rights and public good.3,5 Policymakers must weigh the rights of individuals who wish to claim exemptions from immunizations against VPD risks that endanger the general public. Each US state has permitted some degree of exemptions for medical reasons or for religious and/or philosophical reasons. At low vaccination coverage and exemption levels, exemptors are unlikely to have a significant impact from a public health standpoint. Their impact is essentially a minor increase in the percentage of nonimmune or nonimmunized individuals, the great majority of whom are unvaccinated for other reasons. When vaccination coverage levels are high, herd immunity results in low incidence of VPDs, and reports of vaccine adverse events compared with disease incidence are more visible.11 For diseases that are transmitted from person to person (and are therefore affected by herd immunity, eg, poliomyelitis, measles, pertussis, rubella, diphtheria, and varicella), individual and societal risk-benefit calculations may diverge.6 The individual (or parents) wishing to minimize individual risk may decide to avoid vaccination by claiming an exemption, relying on the fact that others are vaccinated to provide protection. Society's motives in vaccination, however, are to protect both individuals and their neighbors.6 If a large number of individuals choose exemption, a "tragedy of the commons" may result,12 with reductions in vaccination coverage and ensuing resurgence of VPDs. In several countries in the 1970s and 1980s, concerns about alleged or suspected adverse effects led to decreases in pertussis immunization resulting in a major resurgence in the incidence of pertussis.13 Such outbreaks highlight the continued relevance of state vaccination laws as long as VPDs have not been eradicated globally. The effort to increase availability of philosophical exemptions to vaccinations may reflect this divergence in perceived risk-benefit.5 Unfortunately, VPDs other than poliomyelitis are unlikely to be eradicated globally in the near future.14 Consequently, high immunization levels against these VPDs will need to be maintained. Thus, in settings like the United States, where levels of reported VPDs are low and reported adverse events following immunization are relatively prominent,15 debate over appropriateness of exemptions to mandatory immunizations is likely to continue. There have been many reports of VPD outbreaks that started primarily in exempt individuals and then spread to vaccinated persons.5 For example, a 1996 measles outbreak in Utah exemplified the effect that clusters of exemptors can have on the community. Statewide, 118 cases occurred, with 107 in Washington County.16 Compared with the percentage of exemptors nationally (0.44%), Utah has almost 3 times the national average (1.2%), while Washington County has more than 7 times the national average (3.7%). Of the Washington County cases, 48 (45%) were among exemptors. The outbreak lasted 6 generations. Two (66.7%) of the 3 cases in the first generation were exemptors, as were 17 (53%) of 32 cases in the second generation, and 15 (60%) of 25 cases in the third generation. The substantial percentage of exemptors in this outbreak, as well as the concentration of cases among exemptors in the beginning of the outbreak, suggests that they played a major role in transmission (Rebecca Ward, community health specialist, Utah Immunization Program, oral and written communications, September 1997 through September 1998). Such reports confirm the biological plausibility of outbreaks starting in susceptible, unvaccinated individuals and then spreading to vaccinated children and adolescents who are inadequately protected due to vaccine failure. While individual outbreaks of measles,17,18 pertussis,19 rubella,20 and poliomyelitis21,22 in unvaccinated religious communities have been reported, data are lacking to quantify the risk of acquiring a VPD among exemptors vs the general population and the risk that exemptors may pose to the nonexempt public. Our study estimates that from 1985 through 1992, school-aged children and adolescents claiming exemptions in the United States were 35 times more likely to contract measles than vaccinated youth. Surveillance data suggest that increases in VPD incidence among exemptors may be a sentinel effect for a potential outbreak among the general population. We also developed a mathematical model that permits quantification of the risk relationship between exemptor and nonexemptor communities, depending on the relative increase or decrease of exemptors and the degree of mixing between the 2 communities. We chose to use 1985-1992 measles data for this study because this was the most complete data set to which we had ready access. The data examined in this study include the 1989-1991 measles resurgence, the largest outbreak since 1977. In 1990 alone, 26,672 cases of measles and the largest annual number of measles deaths (n=89) since 1971 were reported.23 The resurgence has been attributed to poor coverage rates among children younger than 5 years in urban areas and certain minority groups.24 We focused on school-aged children and adolescents because approximately 80% of measles cases during these years were among individuals younger than 19 years.25 Furthermore, exemptions are granted when immunization laws are enforced—usually at day care or school entrance. If not medically exempt, the choice is either to become immunized or become an exemptor. The relative risk between exemptors and vaccinated persons quantifies the consequences of this choice. We developed a mathematical model based on the known characteristics of exemptors that emerged from the CDC State Immunization Reports and California data. Exemptors tend to cluster within local and state boundaries, thereby increasing the effect that they may have on the rest of the population in comparison with a dispersed pattern. For example, a state may have a relatively low percentage of exemptors overall, while a community in that state may have a substantially higher percentage of exemptors. Our model accounts for this by dividing the population into 1000 communities with varying percentages of exemptors. The mixing ratio accounts for individual choices in social settings. Although there may be a relatively small number of exemptors in the state or county, there could be a significant clustering of exemptors in a given individual's social sphere (eg, school, social organizations, and religious community). It is impossible to quantify a mixing ratio on a national level, but personal preferences in social settings suggest that this fluctuates as accounted for in our model. Our study findings should be interpreted with the following caveats. Cases of measles among exemptors may have been underreported to the Measles Surveillance System because they are more likely to occur in communities with "alternative" health care beliefs, or overreported because measles vaccination was not recorded in the child's immunization history. Furthermore, there may have been inaccuracies in determining the numbers of exemptors because these data were based on state reports from 1990 through 1994. If there was a substantial change in the percentage of exemptors in any state during these years compared with 1985 through 1989, the earlier estimations may be inaccurate. The number of religious and/or philosophical exemptors may have been overestimated because medical exemptions were included in 34 states for which it was not possible to distinguish between type of exemption. There are also limitations in the age-specific analysis. Vaccination coverage was estimated using state reports for kindergarten through grade 12. It is possible that immunization coverage was higher for the younger students because the primary point of enforcement is typically at first entry to school and strict enforcement of laws began in the late 1970s.5 This could account for differences in the age distribution of measles cases among exemptors and vaccinated children. These differences also could be explained by the possibility of waning immunity among vaccinated children or environmental exposure (ie, older children may be more likely to have environmental exposure to measles because of age-related differences in social settings and numbers of contacts). It is also possible that some individuals claimed an exemption for a specific vaccine, but not for other vaccines. If this were the case, the child would be counted in the denominator of the exemptor incidence, despite possible immunization for measles. Unfortunately, surveillance data prior to 1985 or after 1992 are not available to determine if the earlier increase in incidence among exemptors compared with vaccinated children observed in Figure 1 has a general sentinel effect or an ecologic aberrance unique to these years. However, such an effect is consistent with the known higher susceptibility rate in exemptors. Throughout this study, exemptors are defined as individuals claiming religious and/or philosophical exemptions offered by individual states. While this definition is functional for an epidemiologic study, it may not be for policy issues because each state defines exemptions differently. Some states require an unequivocal statement from a religious leader that immunization conflicts with the person's religious belief. This type of requirement for an exemption essentially assesses the strength of conviction of the individual applying for an exemption, similar to Selective Service boards assessing exemptions from military draft. Other states grant exemption based on a form signed by parents, indicating that immunizations are against the individual's personal belief. In these states, efforts may not be made to assess strength of conviction. Further research is needed to better quantify the magnitude of the risks that exemptors pose to nonexemptors. For example, systematic review of the role of exemptors in facilitating transmission in recent and future VPD outbreaks may be useful. Public health surveillance for VPDs should routinely monitor exemption status among new VPD cases. Methods to help identify potential increases in the number or clustering of exemptors before VPD outbreaks occur may be needed. Having determined that exemptors are a risk factor for contracting a VPD, it is important to discover the underlying reasons why individuals are claiming exemptions. Interventions should be developed and implemented to counter misunderstanding of the relative risks and benefits of immunization at both the individual and societal level. References 1. Plotkin SA, Mortimer EA. Vaccines. 2nd ed. Philadelphia, Pa: WB Saunders Co; 1994. 2. Robbins KB, Brandling-Bennett AD, Hinman AR. Low measles incidence: association with enforcement of school immunization laws. Am J Public Health.1981;71:270-274.Google Scholar 3. State Immunization Requirements: 1994-95 . Atlanta, Ga: Dept of Health and Human Services, Centers for Disease Control and Prevention; 1996. 4. Jackson CL. State laws on compulsory immunization in the United States. Public Health Rep.1969;84:787-795.Google Scholar 5. National Vaccine Advisory Committee. Report of the NVAC Working Group on Philosophical Exemptions. In: Minutes of the National Vaccine Advisory Committee: January 13, 1998. Atlanta, Ga: National Vaccine Program Office; 1998:1-5. 6. Hershey JC, Asch DA, Thumasathit T, Meszaros J, Waters VV. The roles of altruism, free riding, and bandwagoning in vaccination decisions. Organizational Behavior Hum Decis Process.1994;59:177-187.Google Scholar 7. Fine PE, Clarkson JA. Individual versus public priorities in the determination of optimal vaccination policies. Am J Epidemiol.1986;124:1012-1020.Google Scholar 8. Centers for Disease Control and Prevention. Summary of notifiable diseases, United States, 1996. MMWR Morb Mortal Wkly Rep.1996;45(53):iii-vi.Google Scholar 9. Haber M. Estimation of the population effectiveness of vaccination. Stat Med.1997;16:601-610.Google Scholar 10. Haber M, Longini IM, Holloram ME. Measures of the effects of vaccination in a randomly mixing population. Int J Epidemiol.1991;20:300-310.Google Scholar 11. Chen RT, Rastogi SC, Mullen JR. et al. The Vaccine Adverse Event Reporting System (VAERS). Vaccine.1994;12:542-550.Google Scholar 12. Hardin G. The tragedy of the commons. Science.1968;162:1243-1248.Google Scholar 13. Gangarosa EJ, Galazka A, Wolfe CR, Phillips LM, Miller E, Chen RT. Impact of the anti-vaccine movements on pertussis control: the untold story. Lancet.1998;351:356-361.Google Scholar 14. Centers for Disease Control and Prevention. Progress toward global eradication of poliomyelitis, 1997. MMWR Morb Mortal Wkly Rep.1998;47:414-419.Google Scholar 15. Chen RT, DeStefano F. Vaccine adverse event: causal or coincidental [commentary]? Lancet.1998;351:611-612.Google Scholar 16. Centers for Disease Control and Prevention. Measles outbreak—southwestern Utah, 1996. MMWR Morb Mortal Wkly Rep.1997;46:766-769.Google Scholar 17. Novotny T, Jennings CE, Doran M. Measles outbreaks in religious groups exempt from immunization laws. Public Health Rep.1988;103:49-54.Google Scholar 18. Sutter RW, Markowitz LE, Bennetch JM, Morris W, Zell WR, Prebud SR. Measles among the Amish: comparative study of measles severity in primary and secondary cases in households. J Infect Dis.1991;163:12-16.Google Scholar 19. Etkind P, Lett SM, MacDonald PD, Silva E, Peppe J. Pertussis outbreaks in groups claiming religious exemptions to vaccination. AJDC.1992;146:173-176.Google Scholar 20. Mellinger AK, Cragan JD, Atkinson WL. et al. High incidence of congenital rubella syndrome after a rubella outbreak. Pediatr Infect Dis J.1995;14:573-578.Google Scholar 21. Oostvogel PM, van Wijngaarden JK, van der Avoort HG. et al. Poliomyelitis outbreak in an unvaccinated community in the Netherlands, 1992-93. Lancet.1994;344:665-670.Google Scholar 22. White FM, Lacey BA, Constance PD. An outbreak of poliovirus infection in Alberta: 1978. Can J Public Health.1981;72:119-124. Taken from: MMWR Morb Mortal Wkly Rep. 1979;28:345.Google Scholar 23. Centers for Disease Control and Prevention. Measles—United States, 1990. MMWR Morb Mortal Wkly Rep.1991;40:369-372.Google Scholar 24. National Vaccine Advisory Committee. The Measles Epidemic: The Problems, Barriers and Recommendations. Washington, DC: National Vaccine Program Office; 1991. 25. Atkinson W, Murphy L, Gantt J, Mayfield M. Epidemiology and Prevention of Vaccine-Preventable Diseases. 2nd ed. Atlanta, Ga: Dept of Health and Human Services, Centers for Disease Control and Prevention; 1995. http://www.deepdyve.com/assets/images/DeepDyve-Logo-lg.png JAMA American Medical Association

Health Consequences of Religious and Philosophical Exemptions From Immunization Laws: Individual and Societal Risk of Measles

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Publisher
American Medical Association
Copyright
Copyright © 1999 American Medical Association. All Rights Reserved.
ISSN
0098-7484
eISSN
1538-3598
DOI
10.1001/jama.282.1.47
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Abstract

Abstract Context All US states require proof of immunization for school entry. Exemptions are generally offered for medical, religious, or philosophical reasons, but the health consequences of claiming such exemptions are poorly documented. Objectives To quantify the risk of contracting measles among individuals claiming religious and/or philosophical exemptions from immunization (exemptors) compared with vaccinated persons, and to examine the risk that exemptors pose to the nonexempt population. Design, Setting, and Participants Population-based, retrospective cohort study of data from 1985 through 1992, collected by the Measles Surveillance System of the Centers for Disease Control and Prevention, as well as from annual state immunization program reports on prevalence of exemptors and vaccination coverage. The study group was restricted to individuals aged 5 to 19 years. To empirically determine and quantify community risk, a mathematical model was developed that examines the spread of measles through communities with varying proportions of exemptors and vaccinated children. Main Outcome Measures Relative risk of contracting measles for exemptors vs vaccinated individuals based on cohort study data. Community risk of contracting measles derived from a mathematical model. Results On average, exemptors were 35 times more likely to contract measles than were vaccinated persons (95% confidence interval, 34-37). Relative risk varied by age and year. Comparing the incidence among exemptors with that among vaccinated children and adolescents during the years 1985-1992 indicated that the 1989-1991 measles resurgence may have occurred 1 year earlier among exemptors. Mapping of exemptors by county in California indicated that exempt populations tended to be clustered in certain geographic regions. Depending on assumptions of the model about the degree of mixing between exemptors and nonexemptors, an increase or decrease in the number of exemptors would affect the incidence of measles in nonexempt populations. If the number of exemptors doubled, the incidence of measles infection in nonexempt individuals would increase by 5.5%, 18.6%, and 30.8%, respectively, for intergroup mixing ratios of 20%, 40%, and 60%. Conclusions These data suggest the need for systematic review of vaccine-preventable incidents to examine the effect of exemptors, increased surveillance of the number of exemptors and cases among them, and research to determine the reasons why individuals claim exemptions. Immunizations are among the most cost-effective and successful public health interventions. Due to the high contagion, morbidity, and mortality associated with most vaccine-preventable diseases (VPDs), and the safety, effectiveness, and potential financial savings offered by vaccines, all jurisdictions in the United States have introduced and actively enforce laws that require proof of immunization for school entrance.1-3 Many of these laws were initially written specifically for smallpox and later amended to include other VPDs.4 Although there are no federal laws mandating immunizations, the US Supreme Court has upheld the constitutionality of state vaccination laws. In 1905, the Court ruled in favor of a Massachusetts law; in 1922, the Court specifically addressed vaccination as a prerequisite for school attendance.3 These federal rulings have served as precedents for state court rulings. State immunization laws permit certain exemptions. As of January 1998, all states allow medical exemptions (eg, for individuals who are immunocompromised, have allergic reactions to vaccine constituents, or have moderate or severe illness). To qualify for medical exemptions, parents or guardians must provide a letter or other documentation from a physician. Forty-eight states permit religious exemptions, and 15 states allow philosophical or personal exemptions.5 Such exemptions are defined differently by each state. Texas requires that individuals claiming religious exemptions be a member of a recognized religious group that opposes all immunizations and submit a letter from a faith leader. By contrast, California offers personal beliefs exemptions, which require only a parental affidavit. Persons who claim exemptions from immunizations for any reason may be at increased risk of contracting a VPD compared with immunized persons. In addition, persons who claim philosophical and/or religious exemptions (exemptors) may create some risk to the community because unvaccinated or undervaccinated persons may be a source of transmission. In contrast to medical exemptions, which are due to an intrinsic medical condition, religious and philosophical exemptions are voluntary choices. Exemptors also pose a social equity issue.6 While vaccines cause fewer complications than VPDs, no vaccine is perfectly safe. For most VPDs, "herd immunity," an indirect protection for a community, may be established when a high enough proportion of the population is immunized to interrupt transmission.3 High immunization levels therefore permit some unvaccinated individuals to reap benefits of immunization without facing risks.6 The current success of immunization programs in achieving record-high levels of coverage and record-low levels of VPDs results in many parents being unfamiliar with VPDs. As a result, the desire of some parents to claim exemptions for their children may increase when vaccine coverage is high.7 Since the actual impact of exemptors on disease occurrence has not been well studied, we analyzed risks of exemptors to themselves and to the communities in which they live. Methods Cohort Study Using a population-based, retrospective cohort study design, we quantified the risk of exemptors compared with vaccinated individuals in contracting measles. We identified measles cases among exemptors and vaccinated individuals from 1985 through 1992, using data derived from the Measles Surveillance System of the Centers for Disease Control and Prevention (CDC), Atlanta, Ga. This system receives weekly reports of confirmed measles cases from 53 reporting areas (50 states, New York City, Chicago, and the District of Columbia). The reports include county, age, whether the case was an international importation, vaccination status, and exemption status if unvaccinated.8 We restricted our study to school-aged children and adolescents (aged 5-19 years). We compared the relative risk of contracting measles of exemptors and vaccinated individuals. We estimated the number of exemptors using CDC annual, unpublished State Immunization Reports from 1990 through 1994. These reports provide the "percentage of enrollees with an exemption for 1 or more vaccines." Data submitted in the reports do not distinguish between religious, philosophical, and medical exemptors, so we contacted program managers to discern the types of exemptions. For states not able to identify type of exemptions (n=34 [68%]), we used the overall percentages reported on state surveys, which include medical exemptions (mean average of medical exemptions in the 16 states for which it was possible to identify type of exemption was 0.16). For 1 state (Delaware), which did not report percentage of individuals claiming exemption for any year, we used the average percentage of exemptors for states that did report these data (0.66%). We applied the (mean) average for each state over these 5 years to the period 1985-1992. California provided county-specific data on the percentage of exemptors, which were used in developing the mathematical model. We calculated the number of vaccinated individuals by assuming a 98% national vaccination coverage rate for school-aged children and adolescents, based on unpublished CDC school-survey data of yearly coverage by state and antigen. All states reported at least 98% vaccination coverage among school-aged youth for measles in the period 1985-1992. Sociodemographic variables were not available. We used age-specific population data from the Bureau of the Census to extrapolate the percentages into estimated numbers. Thus, we were able to estimate age-specific measles incidence and the relative risk of measles for exemptors compared with vaccinated persons. Mathematical Model To quantify the risk of contracting measles in communities that have contact with exemptors, we applied a mathematical model to the data from the cohort study (mathematical model available from the authors on request).9 The model examines the spread of disease through a population consisting of different strata or groups. In our application, the model consists of 2 groups: school-aged exemptors and nonexemptors. It is assumed that youth within a given group mix randomly, but exemptors are more likely to be in contact with other exemptors, and nonexemptors are more likely to be in contact with other nonexemptors. The extent to which youth are more likely to make contacts with others from the same group is determined by the intergroup mixing ratio, which may vary between 0 and 1. For example, if the mixing ratio is 0.6, then 60% of the contacts are made with children chosen at random from the entire community (including that child's own group), and the remaining 40% of a child's contacts are made with other children from the same group. When the intergroup mixing ratio is 1, there is random mixing between exemptors and nonexemptors, and when the mixing ratio is 0, there are no contacts between groups. Another important parameter in the model is the transmission probability, which is the probability that a susceptible child becomes infected from a single infected child. This parameter may vary across communities because it depends on socioeconomic factors such as crowding. We assume that the vaccine reduces the transmission probability to each child by a given fraction, which is the vaccine efficacy. The vaccine efficacy in terms of transmission probabilities is defined as 1 minus the ratio of the transmission probability to a vaccinee and a nonvaccinee when both are exposed to a single infected person.10 The estimate of this quantity depends on the assumption about the intergroup mixing ratio: for mixing ratios 0.6, 0.4, and 0.2, the estimated efficacy is 0.62, 0.42, and 0.22, respectively. The vaccine efficacy in the model differs significantly from the traditional definition of vaccine efficacy, which estimates the measles vaccine to be about 90% to 95% efficacious.1 Traditional vaccine efficacy is based on the overall attack rates for a vaccinee and a nonvaccinee during an outbreak. Efficacy also depends on the length of the epidemic period and on vaccine coverage. Estimation of efficacy also may be biased if vaccination is not random or if a vaccinee and a nonvaccinee do not have the same exposure to the infecting agent. Vaccine efficacy based on transmission probabilities, as in the model, standardizes exposure to a single contact with an infected person, so it does not depend on factors such as the vaccination strategy or coverage.9 These 2 measures of vaccine efficacy can be quite different, even if there is no bias, especially if mixing is not random. Our model provides equations that relate the disease attack rate (incidence) during an outbreak to the values of the transmission probabilities and intergroup mixing ratios. These equations are used to estimate the transmission probabilities from the observed attack rates among exemptors and nonexemptors and predict the expected attack rates based on changes in the number of exemptors. To apply this model, we assumed that the population consists of 1000 communities. The distribution of the transmission probabilities over the communities was determined so that the overall numbers of expected cases in exemptors and nonexemptors were close to the observed frequencies. The ratio of transmission probabilities for exemptors and nonexemptors was also determined from the overall attack rates. We developed the model to account for the clustering of exemptors as seen in national and California data. Five percent of the communities were assigned a rather high proportion of exemptors (5%); another 5% of the communities had no exemptors; and the proportion of exemptors in the remaining 90% of the communities was constant (0.21%), which was determined such that the overall proportion of exemptors was the same as in the entire population (0.44%). To empirically determine and quantify the impact of changes in the number of exemptors on the number of measles cases among nonexemptors, we explored various changes in the size of the exempt population: 50% decrease in the number of exemptors (ie, these individuals become vaccinated); and 50%, 100%, 200%, and 300% increases in the number of exemptors. Results United States measles surveillance data indicate that exemptors were at a statistically significant increased risk of contracting measles vs vaccinated individuals for each age group and in every year (Table 1). On average, from 1985 through 1992, for persons aged 5 to 19 years, exemptors were 35 times more likely to contract measles than were vaccinated persons. The relative risk varied greatly by age group and by year, ranging from 4 times the risk of contracting measles for exemptors aged 15 to 19 years compared with vaccinated individuals in 1992, to 170 times the risk in 1988 for those aged 5 to 9 years . Cases among the vaccinated youth were more frequent in the older age categories. Cases among exemptors have a more uniform distribution across age categories (Table 1). Comparing the incidence among school-aged exemptors with that among school-aged vaccinated children and adolescents during the years 1985 through 1992 indicates that the 1989-1991 measles resurgence may have occurred 1 year earlier among exemptors (Figure 1). Mapping of exemptors by county was available for California, where school entry laws allow parents to elect personal belief exemptions from mandatory vaccinations for their children. Overall, approximately 0.5% of children enter kindergarten each year with such exemptions, a value that has remained relatively stable over the past 2 decades. However, the frequency of exemptors is not uniform in schools across the state. In 1995, in 84% of California's public and private schools with kindergartens, the proportion of children entering with exemptions was less than 1%. However, in 12% of schools, 1% to 4% of children entered with exemptions, and in 4% of schools, at least 5% of entrants were exempted. The proportion of exemptors is higher in the northern half of the state and is particularly high along the northern foothills of the Sierra Nevada Mountains and in some central and northern coastal areas. Our mathematical model suggests that changes in the number of exemptors affects measles cases in the nonexempt population (Table 2). The mixing ratio largely determines the impact a particular increase or decrease of exemptors would have on the nonexempt population. For example, if the number of exemptors doubled, then the incidence of measles in the nonexempt population would increase by 5.5%, 18.6%, and 30.8% for intergroup mixing ratios of 20%, 40%, and 60%, respectively. The greater the increase in the number of exemptors, the more effect they have on the nonexempt population. Comment The control of VPDs by means of immunization requirements necessitates careful balance of individual rights and public good.3,5 Policymakers must weigh the rights of individuals who wish to claim exemptions from immunizations against VPD risks that endanger the general public. Each US state has permitted some degree of exemptions for medical reasons or for religious and/or philosophical reasons. At low vaccination coverage and exemption levels, exemptors are unlikely to have a significant impact from a public health standpoint. Their impact is essentially a minor increase in the percentage of nonimmune or nonimmunized individuals, the great majority of whom are unvaccinated for other reasons. When vaccination coverage levels are high, herd immunity results in low incidence of VPDs, and reports of vaccine adverse events compared with disease incidence are more visible.11 For diseases that are transmitted from person to person (and are therefore affected by herd immunity, eg, poliomyelitis, measles, pertussis, rubella, diphtheria, and varicella), individual and societal risk-benefit calculations may diverge.6 The individual (or parents) wishing to minimize individual risk may decide to avoid vaccination by claiming an exemption, relying on the fact that others are vaccinated to provide protection. Society's motives in vaccination, however, are to protect both individuals and their neighbors.6 If a large number of individuals choose exemption, a "tragedy of the commons" may result,12 with reductions in vaccination coverage and ensuing resurgence of VPDs. In several countries in the 1970s and 1980s, concerns about alleged or suspected adverse effects led to decreases in pertussis immunization resulting in a major resurgence in the incidence of pertussis.13 Such outbreaks highlight the continued relevance of state vaccination laws as long as VPDs have not been eradicated globally. The effort to increase availability of philosophical exemptions to vaccinations may reflect this divergence in perceived risk-benefit.5 Unfortunately, VPDs other than poliomyelitis are unlikely to be eradicated globally in the near future.14 Consequently, high immunization levels against these VPDs will need to be maintained. Thus, in settings like the United States, where levels of reported VPDs are low and reported adverse events following immunization are relatively prominent,15 debate over appropriateness of exemptions to mandatory immunizations is likely to continue. There have been many reports of VPD outbreaks that started primarily in exempt individuals and then spread to vaccinated persons.5 For example, a 1996 measles outbreak in Utah exemplified the effect that clusters of exemptors can have on the community. Statewide, 118 cases occurred, with 107 in Washington County.16 Compared with the percentage of exemptors nationally (0.44%), Utah has almost 3 times the national average (1.2%), while Washington County has more than 7 times the national average (3.7%). Of the Washington County cases, 48 (45%) were among exemptors. The outbreak lasted 6 generations. Two (66.7%) of the 3 cases in the first generation were exemptors, as were 17 (53%) of 32 cases in the second generation, and 15 (60%) of 25 cases in the third generation. The substantial percentage of exemptors in this outbreak, as well as the concentration of cases among exemptors in the beginning of the outbreak, suggests that they played a major role in transmission (Rebecca Ward, community health specialist, Utah Immunization Program, oral and written communications, September 1997 through September 1998). Such reports confirm the biological plausibility of outbreaks starting in susceptible, unvaccinated individuals and then spreading to vaccinated children and adolescents who are inadequately protected due to vaccine failure. While individual outbreaks of measles,17,18 pertussis,19 rubella,20 and poliomyelitis21,22 in unvaccinated religious communities have been reported, data are lacking to quantify the risk of acquiring a VPD among exemptors vs the general population and the risk that exemptors may pose to the nonexempt public. Our study estimates that from 1985 through 1992, school-aged children and adolescents claiming exemptions in the United States were 35 times more likely to contract measles than vaccinated youth. Surveillance data suggest that increases in VPD incidence among exemptors may be a sentinel effect for a potential outbreak among the general population. We also developed a mathematical model that permits quantification of the risk relationship between exemptor and nonexemptor communities, depending on the relative increase or decrease of exemptors and the degree of mixing between the 2 communities. We chose to use 1985-1992 measles data for this study because this was the most complete data set to which we had ready access. The data examined in this study include the 1989-1991 measles resurgence, the largest outbreak since 1977. In 1990 alone, 26,672 cases of measles and the largest annual number of measles deaths (n=89) since 1971 were reported.23 The resurgence has been attributed to poor coverage rates among children younger than 5 years in urban areas and certain minority groups.24 We focused on school-aged children and adolescents because approximately 80% of measles cases during these years were among individuals younger than 19 years.25 Furthermore, exemptions are granted when immunization laws are enforced—usually at day care or school entrance. If not medically exempt, the choice is either to become immunized or become an exemptor. The relative risk between exemptors and vaccinated persons quantifies the consequences of this choice. We developed a mathematical model based on the known characteristics of exemptors that emerged from the CDC State Immunization Reports and California data. Exemptors tend to cluster within local and state boundaries, thereby increasing the effect that they may have on the rest of the population in comparison with a dispersed pattern. For example, a state may have a relatively low percentage of exemptors overall, while a community in that state may have a substantially higher percentage of exemptors. Our model accounts for this by dividing the population into 1000 communities with varying percentages of exemptors. The mixing ratio accounts for individual choices in social settings. Although there may be a relatively small number of exemptors in the state or county, there could be a significant clustering of exemptors in a given individual's social sphere (eg, school, social organizations, and religious community). It is impossible to quantify a mixing ratio on a national level, but personal preferences in social settings suggest that this fluctuates as accounted for in our model. Our study findings should be interpreted with the following caveats. Cases of measles among exemptors may have been underreported to the Measles Surveillance System because they are more likely to occur in communities with "alternative" health care beliefs, or overreported because measles vaccination was not recorded in the child's immunization history. Furthermore, there may have been inaccuracies in determining the numbers of exemptors because these data were based on state reports from 1990 through 1994. If there was a substantial change in the percentage of exemptors in any state during these years compared with 1985 through 1989, the earlier estimations may be inaccurate. The number of religious and/or philosophical exemptors may have been overestimated because medical exemptions were included in 34 states for which it was not possible to distinguish between type of exemption. There are also limitations in the age-specific analysis. Vaccination coverage was estimated using state reports for kindergarten through grade 12. It is possible that immunization coverage was higher for the younger students because the primary point of enforcement is typically at first entry to school and strict enforcement of laws began in the late 1970s.5 This could account for differences in the age distribution of measles cases among exemptors and vaccinated children. These differences also could be explained by the possibility of waning immunity among vaccinated children or environmental exposure (ie, older children may be more likely to have environmental exposure to measles because of age-related differences in social settings and numbers of contacts). It is also possible that some individuals claimed an exemption for a specific vaccine, but not for other vaccines. If this were the case, the child would be counted in the denominator of the exemptor incidence, despite possible immunization for measles. Unfortunately, surveillance data prior to 1985 or after 1992 are not available to determine if the earlier increase in incidence among exemptors compared with vaccinated children observed in Figure 1 has a general sentinel effect or an ecologic aberrance unique to these years. However, such an effect is consistent with the known higher susceptibility rate in exemptors. Throughout this study, exemptors are defined as individuals claiming religious and/or philosophical exemptions offered by individual states. While this definition is functional for an epidemiologic study, it may not be for policy issues because each state defines exemptions differently. Some states require an unequivocal statement from a religious leader that immunization conflicts with the person's religious belief. This type of requirement for an exemption essentially assesses the strength of conviction of the individual applying for an exemption, similar to Selective Service boards assessing exemptions from military draft. Other states grant exemption based on a form signed by parents, indicating that immunizations are against the individual's personal belief. In these states, efforts may not be made to assess strength of conviction. Further research is needed to better quantify the magnitude of the risks that exemptors pose to nonexemptors. For example, systematic review of the role of exemptors in facilitating transmission in recent and future VPD outbreaks may be useful. Public health surveillance for VPDs should routinely monitor exemption status among new VPD cases. Methods to help identify potential increases in the number or clustering of exemptors before VPD outbreaks occur may be needed. Having determined that exemptors are a risk factor for contracting a VPD, it is important to discover the underlying reasons why individuals are claiming exemptions. Interventions should be developed and implemented to counter misunderstanding of the relative risks and benefits of immunization at both the individual and societal level. References 1. Plotkin SA, Mortimer EA. Vaccines. 2nd ed. Philadelphia, Pa: WB Saunders Co; 1994. 2. Robbins KB, Brandling-Bennett AD, Hinman AR. Low measles incidence: association with enforcement of school immunization laws. Am J Public Health.1981;71:270-274.Google Scholar 3. State Immunization Requirements: 1994-95 . Atlanta, Ga: Dept of Health and Human Services, Centers for Disease Control and Prevention; 1996. 4. Jackson CL. State laws on compulsory immunization in the United States. Public Health Rep.1969;84:787-795.Google Scholar 5. National Vaccine Advisory Committee. Report of the NVAC Working Group on Philosophical Exemptions. In: Minutes of the National Vaccine Advisory Committee: January 13, 1998. Atlanta, Ga: National Vaccine Program Office; 1998:1-5. 6. Hershey JC, Asch DA, Thumasathit T, Meszaros J, Waters VV. The roles of altruism, free riding, and bandwagoning in vaccination decisions. Organizational Behavior Hum Decis Process.1994;59:177-187.Google Scholar 7. Fine PE, Clarkson JA. Individual versus public priorities in the determination of optimal vaccination policies. Am J Epidemiol.1986;124:1012-1020.Google Scholar 8. Centers for Disease Control and Prevention. Summary of notifiable diseases, United States, 1996. MMWR Morb Mortal Wkly Rep.1996;45(53):iii-vi.Google Scholar 9. Haber M. Estimation of the population effectiveness of vaccination. Stat Med.1997;16:601-610.Google Scholar 10. Haber M, Longini IM, Holloram ME. Measures of the effects of vaccination in a randomly mixing population. Int J Epidemiol.1991;20:300-310.Google Scholar 11. Chen RT, Rastogi SC, Mullen JR. et al. The Vaccine Adverse Event Reporting System (VAERS). Vaccine.1994;12:542-550.Google Scholar 12. Hardin G. The tragedy of the commons. Science.1968;162:1243-1248.Google Scholar 13. Gangarosa EJ, Galazka A, Wolfe CR, Phillips LM, Miller E, Chen RT. Impact of the anti-vaccine movements on pertussis control: the untold story. Lancet.1998;351:356-361.Google Scholar 14. Centers for Disease Control and Prevention. Progress toward global eradication of poliomyelitis, 1997. MMWR Morb Mortal Wkly Rep.1998;47:414-419.Google Scholar 15. Chen RT, DeStefano F. Vaccine adverse event: causal or coincidental [commentary]? Lancet.1998;351:611-612.Google Scholar 16. Centers for Disease Control and Prevention. Measles outbreak—southwestern Utah, 1996. MMWR Morb Mortal Wkly Rep.1997;46:766-769.Google Scholar 17. Novotny T, Jennings CE, Doran M. Measles outbreaks in religious groups exempt from immunization laws. Public Health Rep.1988;103:49-54.Google Scholar 18. Sutter RW, Markowitz LE, Bennetch JM, Morris W, Zell WR, Prebud SR. Measles among the Amish: comparative study of measles severity in primary and secondary cases in households. J Infect Dis.1991;163:12-16.Google Scholar 19. Etkind P, Lett SM, MacDonald PD, Silva E, Peppe J. Pertussis outbreaks in groups claiming religious exemptions to vaccination. AJDC.1992;146:173-176.Google Scholar 20. Mellinger AK, Cragan JD, Atkinson WL. et al. High incidence of congenital rubella syndrome after a rubella outbreak. Pediatr Infect Dis J.1995;14:573-578.Google Scholar 21. Oostvogel PM, van Wijngaarden JK, van der Avoort HG. et al. Poliomyelitis outbreak in an unvaccinated community in the Netherlands, 1992-93. Lancet.1994;344:665-670.Google Scholar 22. White FM, Lacey BA, Constance PD. An outbreak of poliovirus infection in Alberta: 1978. Can J Public Health.1981;72:119-124. Taken from: MMWR Morb Mortal Wkly Rep. 1979;28:345.Google Scholar 23. Centers for Disease Control and Prevention. Measles—United States, 1990. MMWR Morb Mortal Wkly Rep.1991;40:369-372.Google Scholar 24. National Vaccine Advisory Committee. The Measles Epidemic: The Problems, Barriers and Recommendations. Washington, DC: National Vaccine Program Office; 1991. 25. Atkinson W, Murphy L, Gantt J, Mayfield M. Epidemiology and Prevention of Vaccine-Preventable Diseases. 2nd ed. Atlanta, Ga: Dept of Health and Human Services, Centers for Disease Control and Prevention; 1995.

Journal

JAMAAmerican Medical Association

Published: Jul 7, 1999

Keywords: immunization,vaccination,measles,vaccines,adolescent,mathematical model,child

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