Effect of Age on the Risk of Fever and Seizures Following Immunization With Measles-Containing Vaccines in Children

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1 Research Original Investigation Effect of Age on the Risk of Fever and Seizures Following Immunization With Measles-Containing Vaccines in Children Ali Rowhani-Rahbar, MD, MPH, PhD; Bruce Fireman, MA; Edwin Lewis, MPH; James Nordin, MD, MPH; Allison Naleway, PhD; Steven J. Jacobsen, MD, PhD; Lisa A. Jackson, MD, MPH; Alison Tse, ScD; Edward A. Belongia, MD; Simon J. Hambidge, MD, PhD; Eric Weintraub, MPH; Roger Baxter, MD; Nicola P. Klein, MD, PhD IMPORTANCE The first dose of live attenuated measles-containing vaccines is associated with an increased risk of febrile seizures 7 to 10 days following immunization among 12- to 23-month-old children. The combination measles, mumps, rubella, and varicella vaccine is associated with a 2-fold increased risk of febrile seizures 7 to 10 days following immunization compared with the separately administered measles, mumps, and rubella and varicella vaccines. It is unknown whether the magnitude of these increased risks depends on age at immunization. Editorial page 1097 Author Video Interview at jamapediatrics.com OBJECTIVE To examine the potential modifying effect of age on the risk of fever and seizures following immunization with measles-containing vaccines. DESIGN, SETTING, AND PARTICIPANTS Retrospective cohort study at 8 Vaccine Safety Datalink sites of a total of children 12 to 23 months of age who had received a measles-containing vaccine from 2001 through EXPOSURES Any measles-containing vaccines and measles-containing vaccines by type. MAIN OUTCOMES AND MEASURES Fever and seizure events occurring during a 42-day postimmunization observation period. RESULTS In the analysis of any measles-containing vaccines, the increased risk of seizures during the 7- to 10-day risk interval, using the remainder of the observation period as the control interval, was significantly greater among older children (relative risk, 6.5; 95% CI, ; attributable risk, 9.5 excess cases per doses; 95% CI, ) than among younger children (relative risk, 3.4; 95% CI, ; attributable risk = 4.0 excess cases per doses; 95% CI, ). The relative risk of postimmunization fever was significantly greater among older children than among younger children; however, its attributable risk was not. In the analysis of vaccine type, measles, mumps, rubella, and varicella vaccine was associated with a 1.4-fold increase in the risk of fever and 2-fold increase in the risk of seizures compared with measles, mumps, and rubella vaccine administered with or without varicella vaccine in both younger and older children. CONCLUSIONS AND RELEVANCE Measles-containing vaccines are associated with a lower increased risk of seizures when administered at 12 to 15 months of age. Findings of this study that focused on safety outcomes highlight the importance of timely immunization of children with the first dose of measles-containing vaccines. JAMA Pediatr. 2013;167(12): doi: /jamapediatrics Published online October 14, Author Affiliations: Author affiliations are listed at the end of this article. Corresponding Author: Ali Rowhani-Rahbar, MD, MPH, PhD, Department of Epidemiology, University of Washington, PO Box , Seattle, WA (rowhani@uw.edu). 1111

2 Research Original Investigation Fever/Seizure Risk and Measles-Containing Vaccine Measles, mumps, and rubella (MMR) and measles, mumps, rubella, and varicella (MMRV) are the 2 live attenuated measles-containing vaccines currently licensed in the United States. These vaccines are effective, immunogenic, and generally well tolerated. 1 Measles-containing vaccines are recommended as a 2-dose series in the United States, with the first dose administered at 12 to 15 months and the second dose at 4 to 6 years of age. Most children in the United States receive their first dose of a measles-containing vaccine between the ages of 12 and 23 months; approximately 85% of them receive this dose by 19 months of age. 2,3 Monitoring the safety of measles-containing vaccines remains an important public health issue. Previous studies have shown that these vaccines administered to children 12 to 23 months of age are associated with an increased risk of fever and febrile seizures 1 to 2 weeks following immunization 4-9 ;however, the exact nature of the relationship between fever and febrile seizures is not entirely understood. It is thought that, during this period, the vaccine virus replication is at its peak and can cause fever, which may in turn induce a seizure event by exceeding a certain threshold. 10 Postlicensure studies have found that the safety profile of MMRV differs somewhat from that of the separately administered MMR and varicella (MMR+V) vaccines. 4,7 Among children 12 to 23 months of age, MMRV is associated with a 2-fold increase in the risk of febrile seizures 1 to 2 weeks following immunization compared with MMR+V. The background risk of febrile seizures is not constant during the second year of life, reaching its highest level at approximately 16 to 18 months of age It is important to examine the safety of measles-containing vaccines administered at different ages during the second year of life. Currently, it is not known whether the magnitude of increased risk of fever and seizures following immunization with measles-containing vaccines depends on age. The separate examination of fever and seizures could potentially shed light on the underlying immunologic and/or neurologic mechanisms leading to the occurrence of these events following immunization. Using data from the Centers for Disease Control and Prevention sponsored Vaccine Safety Datalink (VSD), we sought to examine the effect of age at immunization on the increased risk of fever and seizures after measles-containing vaccines among children 12 to 23 months of age. We evaluated the potential modifying effect of age on the risk of fever and seizures following immunization with (1) any measles-containing vaccines and (2) MMRV compared with MMR administered with or without varicella vaccine (MMR±V). Our hypothesis was that the increased risk of postimmunization fever and seizures following a delayed administration of measles-containing vaccines is greater than that following their timely administration. Methods Study Population The study was approved by the institutional review boards of all the participating sites. Vaccine Safety Datalink is a collaborative effort between the Centers for Disease Control and Prevention and 10 managed care organizations comprising data on more than 9 million members annually As the backbone of active surveillance for vaccine safety in the United States, VSD monitors prespecified potential adverse events following immunization using several methods, including a near real-time system known as rapid cycle analysis. Detailed information on analytic strategies used in rapid cycle analysis can be found elsewhere. 20 For this study, we used data collected through the VSD-conducted MMRV rapid cycle analysis among children 12 to 23 months of age who were members of 1 of the 8 participating VSD sites and had received their measles-containing vaccine between January 2001 and December For one of the sites, only data from July 2007 through December 2011 were included since the other portion of data had already been used in another related publication. Outcomes The 2 prespecified adverse events following immunization examined in this study were fever and seizures. These 2 outcomes were each investigated separately; hereafter throughout this article, fever and seizures refer to these separate adverse events and not a composite or combined outcome. We identified postimmunization medically attended fever events in the outpatient setting by using International Classification of Diseases, Ninth Revision (ICD-9) code 780.6* as previously described. 4,21 We identified postimmunization medically attended seizure events in the emergency department or hospital setting by using ICD-9 code 780.3* (convulsion) or 345* (epilepsy) as previously described. 4,21 All electronically identified seizure events were included in the analyses; we did not distinguish between febrile and afebrile seizures. Data from 2001 to 2008 had been previously used for our earlier study that evaluated the risk of febrile seizures following immunization with MMRV 4 ; additional data from 2009 to 2011 were collected for the current study. For both outcomes, we collected data on events during the 42-day postimmunization period to be consistent with earlier studies. 4,21,22 Children who had received the corresponding ICD-9 code at any setting during the 42 days prior to their fever or seizure event were excluded to minimize the likelihood of including follow-up visits in the analyses. Statistical Analysis The age distribution of measles-containing vaccine recipients was described using prespecified categories of 12 to 13, 14 to 15, 16 to 18, and 19 to 23 months according to the study protocol. We conducted 2 main analyses to examine the effect of age on the risk of fever and seizures following immunization with measles-containing vaccines. In these analyses, 2 age groups of 12 to 15 and 16 to 23 months defined a priori in the protocol were used. The rationale for using these 2 age groups was to reflect the current policy recommendation on immunization with measles-containing vaccines and to enhance power to explore effect modification. Analysis of Fever and Seizures Following Immunization With Any Measles-Containing Vaccines Using a risk interval analysis, each child s follow-up time was partitioned into risk and control intervals during an observa JAMA Pediatrics December 2013 Volume 167, Number 12 jamapediatrics.com

3 Fever/Seizure Risk and Measles-Containing Vaccine Original Investigation Research tion period of 42 days following immunization with a measlescontaining vaccine. The risk interval for fever and seizures was defined as days 7 to 10 following immunization as previously identified. 4,23,24 The remainder of the 42-day observation period (ie, days 0-6 and 11-42) was considered as the control interval. The follow-up time for each child ended with the occurrence of the event or completion of the 42-day period, whichever came first. The incidence of outcome events during the risk interval was calculated and compared with that during the control interval, consistent with the risk-interval analysis. 25 To examine the effect of age at immunization, we compared the relative risk of postimmunization fever and seizures between the age groups of 12 to 15 and 16 to 23 months by adding an age group exposure status (ie, risk or control interval) interaction term to a Poisson regression model. We additionally compared the attributable risk of fever and seizures between the age groups of 12 to 15 and 16 to 23 months by adding an age group exposure status interaction term to a binomial regression model with an identity link (to provide estimates of increased risk on an additive scale) and reported the results as number of excess cases of fever and seizures per doses. We conducted sensitivity analyses by excluding days 0 and 1, 5 and 6, and 11 and 12 following immunization from the control interval. Days 0 and 1 were excluded from the control interval to minimize any potential confounding effect of concomitantly administered inactivated vaccines in causing fever or seizures on those days 15,26 ;days5and6and 11 and 12 were excluded from the control interval to minimize the inclusion of days during which some risk of fever or seizures associated with measles-containing vaccine might still be present. Analysis of Fever and Seizures by Type of the Measles-Containing Vaccine Using a cohort analysis, we compared the incidence of fever and seizures during the 7 to 10 days following immunization with MMRV with that following immunization with MMR±V. To examine the effect of age at immunization, we compared the relative risk of fever and seizures between the age groups of 12 to 15 and 16 to 23 months by adding an age group vaccine type (ie, MMRV or MMR±V) interaction term to a Poisson regression model. We additionally compared the attributable risk of fever and seizures between the age groups of 12 to 15 and 16 to 23 months by adding an age group vaccine type interaction term to a binomial regression model with an identity link as previously described. All regression models included variables for sex, respiratory virus season (November-April and May-October), calendar year, and VSD site as potential confounders. Analyses were conducted using SAS version 9.2 (SAS Institute) and Stata (StataCorp). The study population included children 12 to 23 months of age who had received a measles-containing vaccine between January 2001 and December A total of vaccine recipients (51%) were male. Regardless of the age group, most administered vaccines were MMR+V. Regardless of the vaccine type, most vaccines were administered at 12 to 13 months of age. There were fever events during the 42 days following immunization with any measlescontaining vaccines; of those, 5919 events (32.2%) occurred during the 7 to 10 days following immunization. There were 1810 seizure events during the 42 days following immunization with any measles-containing vaccines; of those, 519 events (28.7%) occurred during the 7 to 10 days following immunization (Table 1). Analysis of Fever and Seizures Following Immunization With Any Measles-Containing Vaccines Following immunization with a measles-containing vaccine, the incidence of fever and seizures during days 7 to 10 was significantly greater than during the control interval in all age groups (Figure 1). The observed pattern of incidence of fever during the control interval across the age groups differed from that of seizures. The incidence of fever steadily declined from 12 to 13 to 19 to 23 months of age, while the incidence of seizures was highest among children 16 to 18 months of age. The relative risk of fever and seizures during the 7- to 10-day risk interval (using control interval as the reference) was significantly greater among children 16 to 23 months of age than among children 12 to 15 months of age. The attributable risk of seizures, but not fever, during the 7- to 10-day risk interval, using control interval as the reference, was significantly greater among children 16 to 23 months of age than among children 12 to 15 months of age (Table 2). Sensitivity analyses that excluded days 0, 1, 5, 6, 11, and 12 from the control interval did not change the results because the point estimates and confidence intervals materially remained the same (data not shown). Analysis of Fever and Seizures by the Type of Measles-Containing Vaccine Consistent with findings in previous studies, the incidence of fever and seizures during the 7 to 10 days following immunization with MMRV was significantly greater than that following immunization with MMR±V (Figure 2). The relative risk of fever and seizures during the 7- to 10-day risk interval following immunization with MMRV (using MMR±V as the reference) was not significantly different between children 16 to 23 months of age and those 12 to 15 months of age (Table 2). The attributable risk of seizures during the 7- to 10-day risk interval following immunization with MMRV, using MMR±V as the reference, was greater among children 16 to 23 months of age than among children 12 to 15 months of age; however, the difference did not gain statistical significance (Table 2). Results Discussion We found that the magnitude of increased risk of seizures following immunization with measles-containing vaccines during the second year of life depends on age. While measles- jamapediatrics.com JAMA Pediatrics December 2013 Volume 167, Number

4 Research Original Investigation Fever/Seizure Risk and Measles-Containing Vaccine Table 1. Number of Administered Doses and Fever and Seizure Events Following Immunization With Measles-Containing Vaccines No. of Events Vaccine Type Dose, No. (%) (N = ) 0-42 d (n = ) 7-10 d (n = 5919) 0-42 d (n = 1810) 7-10 d (n = 519) MMRV (14.9) MMR+V (72.6) MMR only (12.5) MMRV (12.7) MMR+V (66.9) MMR only (20.5) MMRV 9290 (13.1) MMR+V (59.2) MMR only (27.7) MMRV 5509 (13.4) MMR+V (55.3) MMR only (31.3) Total MMRV (14.3) MMR+V (69.6) MMR only (16.1) Abbreviations: MMR, measles, mumps, and rubella vaccine; MMRV, measles, mumps, rubella, and varicella vaccine; V, varicella vaccine. Fever Seizures Figure 1. Incidence Rate (per 1000 Person-years) of Fever (A) and Seizures (B) by Age During the Risk Interval (Days 7-10) and Control Interval (Days 0-6 and 11-42) Following Immunization With a Measles-Containing Vaccine A B Control interval Risk interval Incidence Rate of Fever Incidence Rate of Seizure Table 2. Increased Risk of Fever and Seizure Events 7 to 10 Days Following Immunization With Measles-Containing Vaccines During the Second Year of Life by Age Fever Seizures Type of Analysis Age, mo IRR (95% CI) Excess Cases a (95% CI) IRR (95% CI) Excess Cases a (95% CI) Any measles-containing (4.3 to 4.6) 52.0 (49.9 to 54.0) 3.4 (3.0 to 3.9) 4.0 (3.4 to 4.6) vaccine (risk-interval analysis) (5.4 to 6.5) 47.4 (43.0 to 51.8) 6.5 (5.3 to 8.1) 9.5 (7.6 to 11.5) P value for interaction < <.01 <.01 MMRV vs MMR±V vaccine (1.3 to 1.5) 8.9 (3.2 to 15.2) 2.0 (1.4 to 2.8) 4.2 (2.1 to 6.2) (cohort analysis) (1.1 to 1.7) 9.4 ( 5.1 to 24.0) 2.1 (1.3 to 3.3) 9.0 (1.8 to 16.3) P value for interaction Abbreviations: IRR, incidence rate ratio; MMR, measles, mumps, and rubella vaccine; MMRV, measles, mumps, rubella, and varicella vaccine; V, varicella vaccine. a Per doses. containing vaccines administered at 12 to 15 months of age are associated with an increased risk of seizures 7 to 10 days following immunization, their delayed administration at 16 to 23 months of age may result in an even greater increased risk of that adverse event following immunization. The relative risk of fever was significantly greater among children 16 to 23 months of age than among children 12 to 15 months of age; however, no significant difference between the 2 aforementioned age groups in the attributable risk of that adverse event following immunization with measles-containing vaccines was observed JAMA Pediatrics December 2013 Volume 167, Number 12 jamapediatrics.com

5 Fever/Seizure Risk and Measles-Containing Vaccine Original Investigation Research Figure 2. Incidence Rate (per 1000 Person-years) of Fever (A) and Seizures (B) by Age and Vaccine Type (Measles, Mumps, Rubella, and Varicella [MMRV] or Measles, Mumps, and Rubella Vaccine Administered With or Without Varicella Vaccine [MMR±V]) 7 to 10 Days Following Immunization A Incidence Rate of Fever B Incidence Rate of Seizure MMR ± V MMRV 0 Febrile seizures have been shown to occur following immunization with a small number of other childhood vaccines including whole-cell pertussis-containing vaccines and concomitantly administered inactivated influenza vaccine and 13- valent pneumococcal conjugate vaccine. 2,5,15 They are the most common neurologic adverse events following immunization with measles-containing vaccines. Nonetheless, the increased risk is overall small regardless of age; medically attended febrile seizures following immunization with measlescontaining vaccines are not common events. For instance, it is known that the incidence of postimmunization febrile seizures is several-fold lower than that following natural infection with measles virus. 10 Despite the excellent prognosis, when a child sustains a febrile seizure, negative effects on family members can result; many parents and caregivers consider febrile seizures as frightening events and seek medical attention including a visit to an emergency department. 2 Previous studies have reported that the incidence of febrile seizures among all children 12 to 23 months of age is approximately 10 to 20 cases per 1000 person-years. 11,12,14 In our study, the incidence of seizures during the control interval, shown in Figure 1B, was consistent with previously reported agespecific febrile seizures background rates. Similar to previous studies that found the background risk of febrile seizures to be at its highest level at approximately 16 to 18 months of age, we found that the incidence of seizures reached its peak at around 16 to 18 months of age during the control interval. The attributable risk of postimmunization seizures following any measles-containing vaccines was significantly greater among children 16 to 23 months of age than those 12 to 15 months of age in our study. This was the function of the higher incidence of seizures during the control interval, as well as higher relative risk of seizures, among older children compared with younger children. These findings collectively suggest that the administration of measles-containing vaccines at the age of highest vulnerability to febrile seizures may result in an even greater increased risk of those adverse events following immunization. Different factors may explain the effect of age on the risk of postimmunization fever and seizures observed in this study. Previous studies have suggested that measles-containing vaccines result in stronger immune responses among children older than 15 months compared with those 12 to 15 months of age. 27,28 In addition, immunologic responses following immunization with measles-containing vaccines have been shown to be positively correlated with the rate of fever and measleslike rashes among children 12 to 23 months of age. 28 It is conceivable that 16- to 23-month-old children are capable of mounting a more rigorous immunologic response to the measles component of these vaccines than 12- to 15-monthold children, resulting in their being susceptible to an even greater increased risk of febrile seizures 7 to 10 days following immunization. Alternative explanations for our findings may include differential underlying medical conditions or health-seeking behaviors between children who received their immunization on a timely basis and those who received it with a delay. Specifically, parents of children susceptible to seizures might have delayed receipt of a vaccine known to cause seizures; such children might have also been more likely to develop seizures following the receipt of these vaccines. We did not evaluate the potential contribution of such differences between younger and older children to our findings in this study. We found no evidence that the 2-fold increased risk of seizures 7 to 10 days following immunization with MMRV compared with MMR±V is modified by age. However, the attributable risk of seizures 7 to 10 days following immunization with MMRV, using MMR±V as the reference, was not the same across the age groups; there appeared to be a greater number of excess seizure cases per doses among 16- to 23-monthold children compared with 12- to 15-month-old children. This observed difference was a reflection of the variation by age in the incidence of seizures 7 to 10 days following immunization with MMR±V. Therefore, the same 2-fold increased risk following immunization with MMRV resulted in different numbers of excess cases per doses across the age groups. This study was subject to potential limitations. We exclusively used ICD-9 codes for the identification of fever events, and also seizures without a distinction between febrile and afebrile events, because of the large number of outcomes that would have made medical record reviews cost prohibitive. All jamapediatrics.com JAMA Pediatrics December 2013 Volume 167, Number

6 Research Original Investigation Fever/Seizure Risk and Measles-Containing Vaccine cases identified prior to October 2008 included in this study arose from our previous study of febrile seizures following immunization with MMRV. Medical record reviews conducted in that study found 87% of all electronically identified seizure events in the emergency department or hospital settings occurring within 42 days following immunization with measlescontaining vaccines to be febrile seizures. 4 There is no reason to believe that the risk of afebrile seizures varies in relation to the time since immunization with measles-containing vaccines; therefore, it is unlikely that potential inclusion of a relatively small number of afebrile seizure events could explain the observed differences. We did not examine health care encounters for the evidence of fever-inducing illnesses that could have potentially served as time-varying confounders. However, we do not believe that such illnesses had preferentially occurred within the risk interval of interest as opposed to other periods following immunization in this study. We did not include information on concomitantly administered vaccines in our analyses. However, results of our previous study found that the receipt of concomitant vaccines was not a significant predictor of seizures. 4 Furthermore, our sensitivity analysis in the current study that excluded days 0 and 1 from the control interval in an attempt to remove any potential effect of concomitantly administered vaccines in causing fever or seizures during those days did not materially change the results. The findings of this large study provide new insights into the effect of age on the risk of fever and seizures following immunization with measles-containing vaccines in the second year of life. Previously, Vestergaard et al 8 sought to determine subgroups of children who were particularly susceptible to developing febrile seizures following immunization with MMR. They assessed the potential modifying effect of several characteristics, but not age, among all children born in Denmark from 1991 through We were able to assess the effect of age since children in our study had received their vaccines at varying ages during the second year of life. Vaccines are typically recommended at an age that maximizes the likelihood of vaccine-induced protection and minimizes the risk of morbidity and mortality that would occur by delaying immunization. 10,27 The safety profile of vaccines at different ages is another important consideration in immunization policy decision making. Our findings are of direct relevance to the recommended childhood immunization schedule; they support the timely immunization of children with the first dose of measles-containing vaccines in accordance with current recommendations. ARTICLE INFORMATION Accepted for Publication: April 14, Published Online: October 14, doi: /jamapediatrics Author Affiliations: Kaiser Permanente Vaccine Study Center, Oakland, California (Rowhani-Rahbar, Fireman, Lewis, Baxter, Klein); HealthPartners Institute for Education and Research, Minneapolis, Minnesota (Nordin); Kaiser Permanente Center for Health Research, Portland, Oregon (Naleway); Kaiser Permanente Department of Research and Evaluation, Pasadena, California (Jacobsen); Group Health Research Institute, Seattle, Washington (Jackson); Department of Population Medicine, Harvard Pilgrim Health Care Institute, Boston, Massachusetts (Tse); Marshfield Clinic Research Foundation, Marshfield, Wisconsin (Belongia); Kaiser Permanente Institute for Health Research, Denver, Colorado (Hambidge); Immunization Safety Office, Centers for Disease Control and Prevention, Atlanta, Georgia (Weintraub). Author Contributions: Dr Rowhani-Rahbar had full access to all of the data in the study and takes responsibility for the integrity of the data and the accuracy of the data analysis. Study concept and design: Rowhani-Rahbar, Fireman, Lewis, Nordin, Jacobsen, Weintraub, Baxter, Klein. Acquisition of data: Rowhani-Rahbar, Lewis, Nordin, Naleway, Jackson, Tse, Belongia, Hambidge, Weintraub, Baxter, Klein. Analysis and interpretation of data: Rowhani-Rahbar, Fireman, Lewis, Nordin, Naleway, Jacobsen, Jackson, Tse, Hambidge, Klein. Drafting of the manuscript: Rowhani-Rahbar. Critical revision of the manuscript for important intellectual content: All authors. Statistical analysis: Rowhani-Rahbar, Fireman, Lewis, Weintraub. Obtained funding: Rowhani-Rahbar, Baxter, Klein. Administrative, technical, or material support: Naleway, Jacobsen, Jackson, Tse, Hambidge, Weintraub, Baxter, Klein. Study supervision: Rowhani-Rahbar, Weintraub, Klein. Conflict of Interest Disclosures: Dr Rowhani-Rahbar reports receiving institutional research support from the Centers for Disease Control and Prevention (CDC). Dr Nordin reports receiving institutional research support from the CDC. Dr Naleway reports receiving institutional research support from the CDC and GlaxoSmithKline. Dr Jacobsen reports receiving institutional research support from the CDC and Merck & Co. Dr Jackson reports receiving institutional research support from the CDC, National Institutes of Health, Novartis, Pfizer, and sanofi-pasteur. Dr Belongia reports receiving institutional research support from the CDC and MedImmune. Dr Hambidge reports receiving institutional research support from the CDC. Dr Baxter reports receiving institutional research support from the CDC, Merck & Co, Novartis, GlaxoSmithKline, Pfizer, and sanofi-pasteur. Dr Klein reports receiving institutional research support from the CDC, Merck & Co, Novartis, GlaxoSmithKline, Pfizer, and sanofi-pasteur. Mr Weintraub is an employee of the CDC. No other conflicts of interest were reported. Funding/Support: This study was supported by the CDC-sponsored VSD through a subcontract ( ) with America s Health Insurance Plans. Role of the Sponsor: The CDC played a role in the design and conduct of the study; collection, management, analysis, and interpretation of the data; and preparation, review, or approval of the manuscript; and decision to submit the manuscript for publication. Disclaimer: The findings and conclusions in this article are those of the authors and do not necessarily represent the official position of the CDC. Additional Contributions: We are grateful to Noel Weiss, MD, DPH (Department of Epidemiology, University of Washington), for critical review of the manuscript. REFERENCES 1. Atkinson W, Wolfe C, Hamborsky J, eds. 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7 Fever/Seizure Risk and Measles-Containing Vaccine Original Investigation Research 8. Vestergaard M, Hviid A, Madsen KM, et al. MMR vaccination and febrile seizures: evaluation of susceptible subgroups and long-term prognosis. JAMA. 2004;292(3): Farrington P, Pugh S, Colville A, et al. A new method for active surveillance of adverse events from diphtheria/tetanus/pertussis and measles/mumps/rubella vaccines. Lancet. 1995;345(8949): Strebel PM, Papania MJ, Dayan GH, Halsey NA. Measles vaccine. In: Plotkin SA, Orenstein WA, Offit PA, eds. Vaccines. 5th ed. Philadelphia, PA: Saunders Elsevier; Verburgh ME, Bruijnzeels MA, van der Wouden JC, et al. Incidence of febrile seizures in the Netherlands. Neuroepidemiology. 1992;11(4-6): Vestergaard M, Christensen J. Register-based studies on febrile seizures in Denmark. Brain Dev. 2009;31(5): Van der Berg BJ, Yerushalmy J. Studies on convulsive disorders in young children, I: incidence of febrile and nonfebrile convulsions by age and other factors. Pediatr Res. 1969;3(4): Huang WT, Gargiullo PM, Broder KR, et al; Vaccine Safety Datalink Team. Lack of association between acellular pertussis vaccine and seizures in early childhood.pediatrics. 2010;126(2): Tse A, Tseng HF, Greene SK, Vellozzi C, Lee GM; VSD Rapid Cycle Analysis Influenza Working Group. Signal identification and evaluation for risk of febrile seizures in children following trivalent inactivated influenza vaccine in the Vaccine Safety Datalink Project, Vaccine. 2012;30(11): Chen RT, DeStefano F, Davis RL, et al. The Vaccine Safety Datalink: immunization research in health maintenance organizations in the USA. Bull World Health Organ. 2000;78(2): DeStefano F; Vaccine Safety Datalink Research Group. The Vaccine Safety Datalink project. Pharmacoepidemiol Drug Saf. 2001;10(5): Baggs J, Gee J, Lewis E, et al. The Vaccine Safety Datalink: a model for monitoring immunization safety. Pediatrics. 2011;127(suppl 1):S45-S Yih WK, Kulldorff M, Fireman BH, et al. Active surveillance for adverse events: the experience of the Vaccine Safety Datalink project. Pediatrics. 2011;127(suppl 1):S54-S Lieu TA, Kulldorff M, Davis RL, et al; Vaccine Safety Datalink Rapid Cycle Analysis Team. Real-time vaccine safety surveillance for the early detection of adverse events. Med Care. 2007;45(10)(suppl 2):S89-S Klein NP, Lewis E, Baxter R, et al. Measles-containing vaccines and febrile seizures in childrenage4to6years.pediatrics. 2012;129(5): Gillet Y, Steri GC, Behre U, et al. Immunogenicity and safety of measles-mumps-rubella-varicella (MMRV) vaccine followed by one dose of varicella vaccine in children aged 15 months-2 years or 2-6 years primed with measles-mumps-rubella (MMR) vaccine. Vaccine. 2009;27(3): Blatter MM, Klein NP, Shepard JS, et al. Immunogenicity and safety of two tetravalent (measles, mumps, rubella, varicella) vaccines coadministered with hepatitis a and pneumococcal conjugate vaccines to children twelve to fourteen months of age. Pediatr Infect Dis J. 2012;31(8):e133-e Peltola H, Heinonen OP. Frequency of true adverse reactions to measles-mumps-rubella vaccine: a double-blind placebo-controlled trial in twins. Lancet. 1986;1(8487): Glanz JM, McClure DL, Xu S, et al. Four different study designs to evaluate vaccine safety were equally validated with contrasting limitations. J Clin Epidemiol. 2006;59(8): Rowhani-Rahbar A, Klein NP, Dekker CL, et al; Risk Interval Working Group of the Clinical Immunization Safety Assessment Network. Biologically plausible and evidence-based risk intervals in immunization safety research. Vaccine. 2012;31(1): Orenstein WA, Markowitz L, Preblud SR, Hinman AR, Tomasi A, Bart KJ. Appropriate age for measles vaccination in the United States. Dev Biol Stand. 1986;65: Kuter BJ, Brown ML, Hartzel J, et al; Study Group for ProQuad. Safety and immunogenicity of a combination measles, mumps, rubella and varicella vaccine (ProQuad). Hum Vaccin. 2006;2(5): jamapediatrics.com JAMA Pediatrics December 2013 Volume 167, Number