Active surveillance of adverse events following immunization in primary health care

Batista, Emily Caroline Cardoso; Ferreira, Ana Paula; Oliveira, Valéria Conceição de; Amaral, Gabriela Gonçalves; Jesus, Renato Fernando de; Quintino, Nayara Dornela; Viegas, Selma Maria da Fonseca; Guimarães, Eliete Albano de Azevedo

Abstract

Objective

To describe the active surveillance of adverse events following immunization, their incidence and associated factors in a municipality of Minas Gerais, Brazil.

Methods

This is a prospective cohort conducted in Primary Health Care between 2017 and 2018. A total of 384 individuals who received vaccines were followed up, excluding those who had previous adverse events. At baseline, sociodemographic, health and vaccination history information and, in follow-up, the characteristics of adverse events and epidemiological surveillance actions were collected. The incidence rate of adverse events was estimated, and the chi-square test, poisson regression and Hosmer-Lemeshow test were performed.

Results

The incidence of adverse events was 13.36 cases/100,000 doses of vaccines (95% confidence interval: 13.34-13.38), with a higher incidence in children under 5 years of age. The most frequent adverse events were local pain, redness, hardening, followed by fever and persistent crying. Among the factors associated with the occurrence of adverse events, receiving tetanus and diffrhyphria vaccine (relative risk: 7.9; 95% confidence interval: 2.77-12.46) and intramuscular administration were considered at risk (relative risk: 6.1; 95% confidence interval: 2.55-14.63). Nursing professionals’ conduct, considering the guidelines on the vaccines received, increased adverse event reporting (relative risk: 3.4; 95% confidence interval: 1.53-7.68).

Conclusion

The study allowed to know factors that favor the occurrence of adverse events. There is evidence that conducts adopted by nursing professionals in immunization rooms may avoid underreporting of adverse events following immunization.

Vaccination; Drug-related side effects and adverse reactions; Primary health care; Epidemiological monitoring

Resumo

Objetivo

Descrever a vigilância ativa dos eventos adversos pós-vacinação, sua incidência e fatores associados, em um município de Minas Gerais, Brasil.

Métodos

Coorte prospectiva realizada na Atenção Primária à Saúde, entre 2017 e 2018. Foram acompanhados 384 indivíduos que receberam vacinas, excluindo-se aqueles que tiveram eventos adversos prévios. Na linha de base, foram coletadas informações sociodemográficas, de saúde e histórico de vacinação e, no seguimento, as características do evento adverso e das ações de vigilância epidemiológica. Estimou-se taxa de incidência de eventos adversos, e realizaram-se o teste do qui-quadrado, a regressão de Poisson e o teste de Hosmer-Lemeshow.

Resultados

A incidência de eventos adversos foi de 13,36 casos/100 mil doses de vacinas (intervalo de confiança de 95%: 13,34-13,38), com maior incidência em crianças menores de 5 anos. Os eventos adversos mais frequentes foram dor local, vermelhidão, endurecimento, seguidos de febre e choro persistente. Dentre os fatores associados à ocorrência dos eventos adversos, recebimento da vacina contra tétano e difteria (risco relativo: 7,9; intervalo de confiança de 95%: 2,77-12,46) e administração por meio da via intramuscular foram considerados de risco (risco relativo: 6,1; intervalo de confiança de 95%: 2,55-14,63). A conduta do profissional de enfermagem, diante das orientações sobre as vacinas recebidas, aumentou a notificação de eventos adversos (risco relativo: 3,4; intervalo de confiança de 95%: 1,53-7,68).

Conclusão

O estudo permitiu conhecer fatores que favorecem a ocorrência de eventos adversos. Há evidências de que condutas adotadas pelos profissionais de enfermagem nas salas de vacinação podem evitar subnotificações de eventos adversos pós-vacinação.

Vacinação; Efeitos colaterais e reações adversas relacionados a medicamentos; Atenção primária à saúde; Monitoramento epidemiológico

Resumen

Observación

Describir la observación activa de los eventos adversos posvacunación, su incidencia y factores asociados en un municipio del estado de Minas Gerais, Brasil.

Métodos

Cohorte prospectiva realizada en la Atención Primaria de Salud, entre 2017 y 2018. Se realizó el seguimiento de 384 individuos que recibieron vacunas, excluyendo a aquellos que tuvieron eventos adversos previos. En la línea basal, se recopiló información sociodemográfica, de salud e historial de vacunación y, en el seguimiento, las características del evento adverso y las acciones de observación epidemiológica. Se estimó un índice de incidencia de eventos adversos y se realizó la prueba χ² de Pearson, la regresión de Poisson y la prueba de Hosmer-Lemeshow.

Resultados

La incidencia de eventos adversos fue de 13,36 casos/100.000 dosis de vacuna (intervalo de confianza de 95 %: 13,34-13,38), con mayor incidencia en niños menores de 5 años. Los eventos adversos más frecuentes fueron dolor local, enrojecimiento, endurecimiento, seguidos de fiebre y llanto persistente. Entre los factores asociados a la ocurrencia de los eventos adversos, la aplicación de la vacuna contra el tétanos y la difteria (riesgo relativo: 7,9; intervalo de confianza de 95 %: 2,77-12,46) y la administración por medio de la vía intramuscular fueron considerados de riesgo (riesgo relativo: 6,1; intervalo de confianza de 95 %: 2,55-14,63). La conducta del profesional de enfermería ante las instrucciones sobre las vacunas recibidas aumentó la notificación de eventos adversos (riesgo relativo: 3,4; intervalo de confianza de 95 %: 1,53-7,68).

Conclusión

El estudio permitió conocer factores que favorecen a la ocurrencia de eventos adversos. Hay evidencias de que las conductas adoptadas por los profesionales de enfermería en las salas de vacunación pueden evitar subnotificaciones de eventos adversos posvacunación.

Vacunación; Efectos colaterales y reacciones adversas relacionados con medicamentos; atención primaria de salud; monitoreo epidemiológico

Introduction

Immunobiologicals have excellent safety records, but are not exempt from causing adverse events following immunization, even if they are submitted to a rigorous clinical trial process, in which they are thoroughly tested and studied, to ensure maximum safety and efficacy for their users.(¹1. Di Pasquale A, Bonanni P, Garçon N, Stanberry LR, El-Hodhod M, Tavares Da Silva F. Vaccine safety evaluation: Practical aspects in assessing benefits and risks. Vaccine. 2016;34(52):6672-80. Review.)

An adverse event following immunization is characterized as any undesirable and unintentional event that an individual may develop when receiving a dose of some immunobiological.(²2. Brasil. Ministério da Saúde. Secretaria de Vigilância em Saúde. Departamento de Vigilância das Doenças Transmissíveis. Manual de vigilância epidemiológica de eventos adversos pós-vacinação. 3a ed. Brasília (DF): Ministério da Saúde; 2014 [citado 2020 Dez 30]. Disponível em: https://bvsms.saude.gov.br/bvs/publicacoes/manual_vigilancia_epidemiologica_eventos_adversos_pos_vacinacao.pdf
https://bvsms.saude.gov.br/bvs/publicaco... )Its occurrence may be related to the process of production and storage of these products, the physical and biological characteristics of vaccinated individuals and the process of administration of these immunobiologicals.(³3. Santos SS, Oliveira VC, Ribeiro HC, Alves TG, Cavalcante RB, Guimarães EA. Analysis of adverse events following immunization in Minas Gerais, Brazil, 2011: a cross-sectional study. Epidemiol Serv Saúde. 2016;25(1):45-54.,⁴4. Donà D, Masiero S, Brisotto S, Gottardello L, Lundin R, Borgia E, et al. Special Immunization Service: a 14-year experience in Italy. PLoS One. 2018;13(4):e0195881.) Adverse events following immunization are classified into two distinct types: severe adverse event and non-severe adverse event. They differ in their intensities and severities, in addition to the type of demand for clinical treatment.(³3. Santos SS, Oliveira VC, Ribeiro HC, Alves TG, Cavalcante RB, Guimarães EA. Analysis of adverse events following immunization in Minas Gerais, Brazil, 2011: a cross-sectional study. Epidemiol Serv Saúde. 2016;25(1):45-54.,⁵5. Stone CA Jr, Rukasin CRF, Beachkofsky TM, Phillips EJ. Immune-mediated adverse reactions to vaccines. Br J Clin Pharmacol. 2019;85(12):2694-706. Review.,⁶6. Danova J, Kocourkova A, Celko AM. Active surveillance study of adverse events following immunisation of children in the Czech Republic. BMC Public Health. 2017;17(1):167.)

The occurrence of an adverse event following immunization can trigger rumors in the community, compromising the reliability of the Brazilian National Immunization Program (PNI - Programa Nacional de Imunização), with harmful consequences to public health, such as the reduction of vaccination coverage and the resurgence of immunopreventable diseases.(¹1. Di Pasquale A, Bonanni P, Garçon N, Stanberry LR, El-Hodhod M, Tavares Da Silva F. Vaccine safety evaluation: Practical aspects in assessing benefits and risks. Vaccine. 2016;34(52):6672-80. Review.)Thus, surveillance and monitoring of these adverse events or any other vaccination-related problems are essential so that the risks do not exceed the benefits achieved by PNI.(²2. Brasil. Ministério da Saúde. Secretaria de Vigilância em Saúde. Departamento de Vigilância das Doenças Transmissíveis. Manual de vigilância epidemiológica de eventos adversos pós-vacinação. 3a ed. Brasília (DF): Ministério da Saúde; 2014 [citado 2020 Dez 30]. Disponível em: https://bvsms.saude.gov.br/bvs/publicacoes/manual_vigilancia_epidemiologica_eventos_adversos_pos_vacinacao.pdf
https://bvsms.saude.gov.br/bvs/publicaco... )Most countries have surveillance systems, in which reporting of the occurrence of an adverse event following immunization can be performed spontaneously and actively by any individual, whether health professional or not.(⁴4. Donà D, Masiero S, Brisotto S, Gottardello L, Lundin R, Borgia E, et al. Special Immunization Service: a 14-year experience in Italy. PLoS One. 2018;13(4):e0195881.,⁵5. Stone CA Jr, Rukasin CRF, Beachkofsky TM, Phillips EJ. Immune-mediated adverse reactions to vaccines. Br J Clin Pharmacol. 2019;85(12):2694-706. Review.,⁷7. Haber P, Parashar UD, Haber M, DeStefano F. Intussusception after monovalent rotavirus vaccine-United States, Vaccine Adverse Event Reporting System (VAERS), 2008-2014. Vaccine. 2015;33(38):4873-7.)In Brazil, reportings are made passively by health professionals when individuals, who received some immunobiological, had some adverse post-vaccination event in health services,(⁸8. Sato AP, Ferreira VL, Tauil MC, Rodrigues LC, Barros MB, Martineli E, et al. Use of electronic immunization registry in the surveillance of adverse events following immunization. Rev Saude Publica. 2018;52:4.)leading to underreporting.

Most studies are developed based on secondary data from the Brazilian Adverse Events Following Immunization Information System (SI-AEFI - Sistema de Informação dos Eventos Adversos Pós-Vacinação). However, the problems in filling out the reporting forms, especially with regard to the completeness of the fields, can interfere with information quality and, consequently, the actual situation of event occurrence.(⁹9. Santos MC, Pontes Netto VB, Andrade MS. Prevalence and factors associated with the occurrence of adverse events following immunization in children. Acta Paul Enferm. 2016;29(6):626-32.

10. Yamoah P, Bangalee V, Oosthuizen F. Knowledge and perceptions of adverse events following immunization among healthcare professionals in Africa: a case study from Ghana. Vaccines (Basel). 2019;7(1):28.-¹¹11. Bisetto LH, Ciosak SI, Cordeiro TL, Boing MS. Adverse events following immunization of the elderly. Cogitare Enferm. 2016;21(4):1-10.)

The proposal of this study advances knowledge by proposing to perform active surveillance of adverse events following immunization, with a direct search for data, allowing greater knowledge of these events in the community. This type of surveillance allows observing, knowing and identifying an adverse event following immunization, planning health actions and improving communication between health professionals and users, enabling individuals to increase confidence in the immunobiologicals available in PNI.(¹²12. Heininger U, Holm K, Caplanusi I, Bailey SR; CIOMS Working Group on Vaccine Safety. Guide to active vaccine safety surveillance: Report of CIOMS working group on vaccine safety - executive summary. Vaccine. 2017;35(32):3917-21.)

In Brazil, the nursing team occupies a prominent position regarding vaccination activities. Nursing is responsible for all stages of the vaccination process at the local health level, represented by immunization rooms, since users’ reception; conservation and administration of immunobiological agents; management of the Information System of the Brazilian National Immunization Program (SI-PNI), in addition to surveillance of adverse events.

The present study aimed to describe the active surveillance of adverse events following immunization, their incidence and associated factors in a municipality of Minas Gerais, Brazil. Most studies conducted in Brazil are based on the database provided by SI-AEFI;(¹¹11. Bisetto LH, Ciosak SI, Cordeiro TL, Boing MS. Adverse events following immunization of the elderly. Cogitare Enferm. 2016;21(4):1-10.)epidemiological cohort studies are essential to supplement such information in order to identify the incidence and factors associated with adverse events following immunization, contributing to safety in immunization rooms and, consequently, the maintainance of the reliability of PNI.

Methods

This is an observational epidemiological study of a prospective cohort, conducted in Primary Health Care (PHC) of a municipality of Minas Gerais, in southeast region of Brazil.

The research setting was composed of all 43 PHC units of the municipality, distributed in ten sanitary regions. For this study, these regions were grouped considering the population and territorial proximity, resulting in six sanitary regions. Subsequently, six PHC units were selected by a simple cluster sample, stratified by the six sanitary regions. The units were selected considering their strategic location because they presented a large flow of care, which eventually favored the opportunity to find individuals available for the study. Individuals were arranged proportionally to the size of each sanitary region.

The cohort sample was calculated considering the population registered and assisted in the municipal public health system (n=187,030). We used the estimated proportion of 50% for a given characteristic, a value that provides the largest sample size for finite population, setting the significance level at 5% and the sampling error at 5%. The estimated sample for the composition of the cohort was 384 individuals.

The study included individuals who attended PHC units to receive some type of vaccine offered by the Brazilian PNI and had a telephone to help them follow up. The participation of public-target individuals of vaccination schedules contemplated in the Brazilian PNI was guaranteed. Individuals of any age who attended to receive special vaccines due to an adverse event prior to vaccination were excluded.

Data collection was performed between September 2009 and June 2010. The field research was prolonged due to the sample size, logistics and refusals (n=189) by the population to participate in the research. During this stage, six previously trained researchers collected the data at baseline, working on a relay scale in the selected units, for a period of 4 to 5 hours per day. Collection was performed in one health unit at a time. Telephone survey was conducted only by the main researcher.

A semi-structured questionnaire was used, adapted from the form of reporting/investigation of adverse events following immunization, standardized by the National Epidemiological Surveillance System.(²2. Brasil. Ministério da Saúde. Secretaria de Vigilância em Saúde. Departamento de Vigilância das Doenças Transmissíveis. Manual de vigilância epidemiológica de eventos adversos pós-vacinação. 3a ed. Brasília (DF): Ministério da Saúde; 2014 [citado 2020 Dez 30]. Disponível em: https://bvsms.saude.gov.br/bvs/publicacoes/manual_vigilancia_epidemiologica_eventos_adversos_pos_vacinacao.pdf
https://bvsms.saude.gov.br/bvs/publicaco... )The questionnaire consisted of a set of items related to: sociodemographic identification, health information and vaccination history, information on vaccines and adverse events following immunization, and guidance on vaccination.

At baseline, individuals who attended PHC units for vaccination and agreed to participate in the study were interviewed individually. The interview was conducted in a private room, in the Basic Health Unit itself, after vaccine administration, and lasted an average of 15 minutes. After the interview, participants were instructed regarding follow-up follow-up, to be performed by telephone contact after 72 hours of vaccination. Telephone intervention is a contemporary, affordable and low-cost strategy for individual monitoring, which can increase bonding and access to health services.(¹³13. Mantwill S, Fiordelli M, Ludolph R, Schulz PJ. EMPOWER-support of patient empowerment by an intelligent self-management pathway for patients: study protocol. BMC Med Inform Decis Mak. 2015;15:18.) The decision for the 72-hour follow-up period was due to the higher prevalence of adverse events following immunization in this period.(²2. Brasil. Ministério da Saúde. Secretaria de Vigilância em Saúde. Departamento de Vigilância das Doenças Transmissíveis. Manual de vigilância epidemiológica de eventos adversos pós-vacinação. 3a ed. Brasília (DF): Ministério da Saúde; 2014 [citado 2020 Dez 30]. Disponível em: https://bvsms.saude.gov.br/bvs/publicacoes/manual_vigilancia_epidemiologica_eventos_adversos_pos_vacinacao.pdf
https://bvsms.saude.gov.br/bvs/publicaco... )

In the follow-up, individuals were again interviewed regarding the presence or not of adverse events following immunization and, upon reporting the event, guidance was made regarding an event care and reporting. For individuals who were not found in the 72 hours of follow-up, new telephone contacts were made in an attempt to reduce sample loss. During the follow-up period, the search was also carried out in the municipal SI-AEFI, in order to identify the events reported and confirmed in the selected PHC units.

The outcome variable was the presence of adverse events following immunization with onset of symptoms up to 72 hours. The criteria for defining adverse events following immunization were: reports of local manifestations (pain, redness, hardening and edema) and systemic manifestations (thermometric fever, persistent crying, headache, vomiting, diarrhea, hypotonic-hyporesponsive episodes. For the hypotonic-hyporesponsive episodes, symptoms that identified hypotonia, hyporesponsiveness and cyosis were taken into consideration in individuals’ report. For persistent crying, we considered the report of prolonged and inconsolable crying for more than 6 hours.(²2. Brasil. Ministério da Saúde. Secretaria de Vigilância em Saúde. Departamento de Vigilância das Doenças Transmissíveis. Manual de vigilância epidemiológica de eventos adversos pós-vacinação. 3a ed. Brasília (DF): Ministério da Saúde; 2014 [citado 2020 Dez 30]. Disponível em: https://bvsms.saude.gov.br/bvs/publicacoes/manual_vigilancia_epidemiologica_eventos_adversos_pos_vacinacao.pdf
https://bvsms.saude.gov.br/bvs/publicaco... ) The vaccine composed of calmette-guérin bacillus (BCG), as it normally presents an adverse event after 72 hours, was excluded from the study.

The exposure variables were: sociodemographic identification (gender, age, date of birth, address and telephone contact); information on health and vaccination history (pre-existing diseases, known allergies, medications in use, clinical symptoms at the time of vaccination and presence of an adverse event following immunization in previous doses); current vaccination (date of vaccination, PHC unit, professional category of administrator and amount of vaccines administered); characteristics of the adverse event following immunization and epidemiological surveillance actions (date of identification and type of event, need for referral to other health services, health professionals’ conduct, hospitalization, presence of systemic manifestations and receipt of information about vaccination guidelines and adverse events following immunization).

Stata software (version 14.0) was used for data analysis and processing. The distribution of relative frequencies for categorical and median variables for the variable age was calculated. The incidence of an adverse event following immunization was estimated considering the cases of events as numerator and the number of doses of vaccines applied during the study period in the denominator.(²2. Brasil. Ministério da Saúde. Secretaria de Vigilância em Saúde. Departamento de Vigilância das Doenças Transmissíveis. Manual de vigilância epidemiológica de eventos adversos pós-vacinação. 3a ed. Brasília (DF): Ministério da Saúde; 2014 [citado 2020 Dez 30]. Disponível em: https://bvsms.saude.gov.br/bvs/publicacoes/manual_vigilancia_epidemiologica_eventos_adversos_pos_vacinacao.pdf
https://bvsms.saude.gov.br/bvs/publicaco... ) The municipal SI-PNI was used to survey the doses of vaccines applied during the study period.

Pearson’s chi-square test was used for bivariate analysis. The explanatory variables, which obtained p-value less than 20% (p<0.20), were inserted by the backward method in the multivariate poisson regression model of robust variance, to verify the factors associated with adverse events following immunization. Those with the least meaning (higher value of p) were removed one by one from the model. The procedure was repeated until all variables present in the model presented statistical significance, with p<0.05. It is noteworthy that the multivariate model was controlled by the effect of individuals’ age, categorized as: less than 1 year; 1 to 4 years; 5 to 19 years and 20 years or more. In this analysis, adults and the elderly were grouped into a single category due to the low occurrence of an adverse event following immunization observed in these age groups. The Hosmer-Lemeshow test was used to verify the adjustment of the final model. Relative risk (RR), with a 95% confidence interval (95% CI), was used as a measure of effect. For all analyses, a significance level of 5% was adopted.

The study was approved by an Institutional Review Board, under opinion 2,206,213.

Results

Of the total number of vaccinated individuals interviewed (n=384), more than half were female and white, aged between zero and 83 years, with a median of 28.5 years. Regarding the age group, 32.3% were children under 5 years of age. In the sample, 2.6% of pregnant women were identified, but none of them presented an adverse event following immunization.

Regarding the history of information and health, more than half stated that they did not have any type of comorbidity. Among the self-reported comorbidities, the most cited were: heart diseases (18.5%) and diabetes (6.8%); consequently, the use of antihypertensivedrugs (14.3%) and antidiabetic (4.7%) were the most cited. Moreover, 2.9% of individuals reported having had at least one convulsive episode, 8.4% reported drug allergy and 1.8% lactose allergy.

Most vaccines were applied by nursing technicians (97.4%). Among those vaccinated, 78.1% reported that no vaccination screening was performed; more than half did not receive guidance about the vaccine administered, were not informed about the possibility of adverse events and did not receive guidance on the conduct if such an event occurred.

Among the individuals, 62.2% received only one vaccine, while the others ranged from two to three or more. The most used route of administration was intramuscular.

In the follow-up, there was a sample loss of 7.5% (n=29, due to the impossibility of contact with the vaccinated individual, according to the number or telephone address reported. Among the 355 vaccinated individuals followed, 35.8% (n=127) self-reported the presence of some type of adverse event following immunization.

Table 1 presents the clinical and epidemiological characteristics of vaccinated individuals who reported the presence of an adverse event following immunization (n=127). Local events were the most reported and included pain, hardening and redness at the vaccine administration site. Regarding systemic events, vaccinated individuals reported the presence of ≥37.5°C fever, headache and persistent crying. Other symptoms, such as diarrhea, hypotonic-hyporesponsive episode, nausea and vomiting, were also reported. It is emphasized that, in an analysis, more than one symptom was identified per vaccinated individual. Regarding the time of onset of an adverse event, 20.5% occurred less than 1 hour after vaccine administration; 40.2% in more than 1 hour, and 39.3% in more than 12 hours, not exceeding the follow-up time of 72 hours. Of the 127 vaccinated individuals who reported the presence of an adverse event following immunization, 26.0% sought health services, including immunization rooms in PHC units and hospitals. Only 17.3% were reported and investigated and, of these, 4.7% were hospitalized. Most of the reported adverse events following immunization were classified as non-severe (81.9%).

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Table 1
Clinical and epidemiological characteristics of vaccinated individuals who reported presence of adverse events following immunization

In a search for SI-AEFI during the study period, eight vaccination errors were identified reported by the PHC units participating in the study. However, these errors did not cause adverse events and were also not part of the study. In addition, six adverse events following immunization related to bcg vaccine were identified, but did not enter the study analysis because they started after 72 hours.

To calculate the incidence, only the cases of confirmed Adverse events following immunization (n=22) were analyzed, considering 164,640 doses of vaccines applied in the studied period, in the selected regions. The incidence was 13.36 cases/100,000 doses of applied vaccines (95%CI 13.34-13.38). The highest incidence was in children under 5 years of age (45.6%), and the most frequent events were pain, redness and hardening, followed by fever, edema, hypotonic-hyporesponsive episode, diarrhea and persistent crying.

In a bivariate analysis, the incidence of adverse events following immunization was higher among vaccinated individuals who received guidance on vaccines and those caused by them and on the conduct to be taken in the presence of these events. Intramuscular and oral administration routes were also associated with the presence of adverse events following immunization (Table 2).

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Table 2
Confirmed Adverse events following immunization, according to sociodemographic characteristics and health history of vaccinated individuals, activities performed in immunization services and applied vaccines

Regarding the percentage distribution of adverse events following immunization, according to the vaccines received at the time of data collection, it was identified that hepatitis B and influenza vaccines were associated with a higher risk of adverse events (Table 3).

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Table 3
Adverse events following immunization, according to the vaccines received

In a multivariate analysis, when adjusted for age, it was observed that the receipt of guidance on the vaccines administered increased 3.4 times the reporting of adverse events following immunization. The vaccine administered intramuscularly increased the risk of adverse events by up to 6.1 times. As for the vaccines received, the diffrhyphtheria and tetanus vaccine increased the risk of having an adverse event following immunization by up to 7.9 times, while the hepatitis B vaccine reduced this risk. The other variables did not present statistical significance, being excluded from the adjusted model, because they presented a value of p> 0.05 (Table 4).

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Table 4
Poisson’s final regression model for factors associated with Adverse events following immunization

Discussion

Although passive surveillance can maintain and feed an information system and is a low-cost service, it has the disadvantage of underreporting adverse events following immunization(⁹9. Santos MC, Pontes Netto VB, Andrade MS. Prevalence and factors associated with the occurrence of adverse events following immunization in children. Acta Paul Enferm. 2016;29(6):626-32.,¹²12. Heininger U, Holm K, Caplanusi I, Bailey SR; CIOMS Working Group on Vaccine Safety. Guide to active vaccine safety surveillance: Report of CIOMS working group on vaccine safety - executive summary. Vaccine. 2017;35(32):3917-21.,¹⁴14. Bisetto LH, Ciosak, SI. Analysis of adverse events following immunization caused by immunization errors. Rev Bras Enferm. 2017;70(1):81-89.)and reducing sensitivity to identifynew cases, signs or even new types of adverse events.(¹⁵15. Lopes SR, Perin JL, Prass TS, Carvalho SM, Lessa SC, Dórea JG. Adverse Events Following Immunization in Brazil: Age of Child and Vaccine-Associated Risk Analysis Using Logistic Regression. Int J Environ Res Public Health. 2018;15(6):1149.)

An observational study conducted in the Puglia region of Italy showed that health services that perform search and active surveillance of adverse events following immunization considerably increase the number of these reportings.(¹⁶16. Stefanizzi P, Stella P, Ancona D, Malcangi KN, Bianchi FP, De Nitto S, et al. Adverse Events Following Measles-Mumps-Rubella-Varicella Vaccination and the Case of Seizures: a Post Marketing Active Surveillance in Puglia Italian Region, 2017-2018. Vaccines (Basel). 2019;7(4):140.) This proves the results evidenced in this study in relation to adverse events reported by individuals and those reported in PHC units. Even in the occurrence of adverse events following immunization, most vaccinated individuals did not return to the immunization rooms of PHC units for due reporting.

The results of this study demonstrate the incidence of adverse events following immunization consistent with that described in literature,(⁵5. Stone CA Jr, Rukasin CRF, Beachkofsky TM, Phillips EJ. Immune-mediated adverse reactions to vaccines. Br J Clin Pharmacol. 2019;85(12):2694-706. Review.,⁶6. Danova J, Kocourkova A, Celko AM. Active surveillance study of adverse events following immunisation of children in the Czech Republic. BMC Public Health. 2017;17(1):167.,⁹9. Santos MC, Pontes Netto VB, Andrade MS. Prevalence and factors associated with the occurrence of adverse events following immunization in children. Acta Paul Enferm. 2016;29(6):626-32.)in which children under 5 years of age were more likely to develop this type of event. The high incidence may be associated with immaturity of the immune system and the high number of vaccines administered in this age group.(¹⁷17. Loiola HA, Almeida AA, Pereira FM, Sardinha AH. Eventos adversos pós-vacinação ocorridos em crianças no município de São Luís, Maranhão. Rev Pesq Saúde. 2016;17(1):17-22.

18. Mrozek-Budzyn D, Majewska R, Kiełtyka A. Early exposure to thimerosal-containing vaccines and children’s cognitive development. A 9-year prospective birth cohort study in Poland. Eur J Pediatr. 2015;174(3):383-91.

19. Salik E, Løvik I, Andersen KE, Bygum A. Persistent Skin Reactions and Aluminium Hypersensitivity Induced by Childhood Vaccines. Acta Derm Venereol. 2016;96(7):967-71.-²⁰20. Sebastian J, Gurumurthy P, Ravi MD, Ramesh M. Active surveillance of adverse events following immunization (AEFI): a prospective 3-year vaccine safety study. Ther Adv Vaccines Immunother. 2019;7:2515135519889000.)

Among the local and systemic events identified, pain and fever were the most common. Most Adverse events following immunization, local and systemic, are mild and self-limiting(⁸8. Sato AP, Ferreira VL, Tauil MC, Rodrigues LC, Barros MB, Martineli E, et al. Use of electronic immunization registry in the surveillance of adverse events following immunization. Rev Saude Publica. 2018;52:4.,⁹9. Santos MC, Pontes Netto VB, Andrade MS. Prevalence and factors associated with the occurrence of adverse events following immunization in children. Acta Paul Enferm. 2016;29(6):626-32.,¹⁷17. Loiola HA, Almeida AA, Pereira FM, Sardinha AH. Eventos adversos pós-vacinação ocorridos em crianças no município de São Luís, Maranhão. Rev Pesq Saúde. 2016;17(1):17-22.,²¹21. Santos CA, Costa RS, Silva JL, Santos MR, Gomes BL. Conhecimento, atitude e prática dos vacinadores sobre vacinação infantil em Teresina-PI, 2015. Epidemiol Serv Saúde. 2017;26(1):133-40.)and represent the area of activity of the nursing team, since, in brazilian public PHC units, it is the main responsible for vaccination activities.(¹⁴14. Bisetto LH, Ciosak, SI. Analysis of adverse events following immunization caused by immunization errors. Rev Bras Enferm. 2017;70(1):81-89.) The fact that local reactions are few and intense, in addition to being expected by the vaccinated individual, end up not being reported to PHC units.(⁵5. Stone CA Jr, Rukasin CRF, Beachkofsky TM, Phillips EJ. Immune-mediated adverse reactions to vaccines. Br J Clin Pharmacol. 2019;85(12):2694-706. Review.,⁸8. Sato AP, Ferreira VL, Tauil MC, Rodrigues LC, Barros MB, Martineli E, et al. Use of electronic immunization registry in the surveillance of adverse events following immunization. Rev Saude Publica. 2018;52:4.)

In this respect, it is important to emphasize the role of the nursing team in the surveillance of adverse events following immunization. The findings of this study identified that the fact that professionals provide guidance on vaccination increases the voluntary reporting of this type of event and, consequently, its incidence. However, more than half of vaccinated individuals reported that they had not received basic information about the vaccines administered, what diseases they were preventing, and that possible adverse events could be caused by them. Health professionals with knowledge are able to inform individuals about the importance and benefits of vaccination and about the possible risks and occurrence of adverse events following immunization.(¹⁶16. Stefanizzi P, Stella P, Ancona D, Malcangi KN, Bianchi FP, De Nitto S, et al. Adverse Events Following Measles-Mumps-Rubella-Varicella Vaccination and the Case of Seizures: a Post Marketing Active Surveillance in Puglia Italian Region, 2017-2018. Vaccines (Basel). 2019;7(4):140.,²⁰20. Sebastian J, Gurumurthy P, Ravi MD, Ramesh M. Active surveillance of adverse events following immunization (AEFI): a prospective 3-year vaccine safety study. Ther Adv Vaccines Immunother. 2019;7:2515135519889000.)The provision of this information to the population, called vaccination screening, is recommended as a basic activity to be performed in immunization rooms. (¹⁰10. Yamoah P, Bangalee V, Oosthuizen F. Knowledge and perceptions of adverse events following immunization among healthcare professionals in Africa: a case study from Ghana. Vaccines (Basel). 2019;7(1):28.) Vaccination screening is a specific measure to avoid risks in vaccination, because, in addition to allowing monitoring individuals’ vaccination status and health hisms, this is when health professionals have the opportunity to conduct advice on vaccines and their possible AEFI. (¹⁴14. Bisetto LH, Ciosak, SI. Analysis of adverse events following immunization caused by immunization errors. Rev Bras Enferm. 2017;70(1):81-89.)

When there is no clarification on the benefits of vaccination and possible adverse events following immunization, the population tends to withdraw from health services, compromising the next doses, both for fear of other reactions and for insecurity in the vaccine professional,(⁹9. Santos MC, Pontes Netto VB, Andrade MS. Prevalence and factors associated with the occurrence of adverse events following immunization in children. Acta Paul Enferm. 2016;29(6):626-32.) increasing the risk of acquiring immunopreventable diseases. With this, such diseases, which have already been controlled, can resurface.(⁸8. Sato AP, Ferreira VL, Tauil MC, Rodrigues LC, Barros MB, Martineli E, et al. Use of electronic immunization registry in the surveillance of adverse events following immunization. Rev Saude Publica. 2018;52:4.) Studies emphasize that adequate vaccination screening and health training and education are specific measures to increase the reporting of adverse events following immunization and ensure the quality and safety of vaccination. (¹⁷17. Loiola HA, Almeida AA, Pereira FM, Sardinha AH. Eventos adversos pós-vacinação ocorridos em crianças no município de São Luís, Maranhão. Rev Pesq Saúde. 2016;17(1):17-22.) In addition, knowledge about vaccines and their possible adverse events considerably increases the population’s confidence in vaccination, since users feel welcome in immunization rooms, and this allows them to resolve existing doubts.

Diffrhyphthes and tetanus vaccine has been associated with an increased risk of causing an adverse event. This vaccine aggregates tetanus toxoids and diffrhyphtheria, as well as aluminum hydroxide and thurosal, considered one of the main responsible for causing local reactions. (²²22. Trucchi C, Zoppi G. Decennial diphtheria-tetanus adult boosters: are they really necessary? J Prev Med Hyg. 2015;56(1):E44-E8. Review.)The lack of knowledge of vaccine history in adults, due to the lack of evidence of vaccine administration, favors the development of adverse events following immunization due to revaccination in a shorter period than the recommended.(⁶6. Danova J, Kocourkova A, Celko AM. Active surveillance study of adverse events following immunisation of children in the Czech Republic. BMC Public Health. 2017;17(1):167.,¹⁷17. Loiola HA, Almeida AA, Pereira FM, Sardinha AH. Eventos adversos pós-vacinação ocorridos em crianças no município de São Luís, Maranhão. Rev Pesq Saúde. 2016;17(1):17-22.)

Another finding refers to the lower reatogenicity of hepatitis B vaccine. (¹¹11. Bisetto LH, Ciosak SI, Cordeiro TL, Boing MS. Adverse events following immunization of the elderly. Cogitare Enferm. 2016;21(4):1-10.,²³23. Myers TR, McNeil MM, Ng CS, Li R, Lewis PW, Cano MV. Adverse events following quadrivalent meningococcal CRM-conjugate vaccine (Menveo®) reported to the Vaccine Adverse Event Reporting system (VAERS), 2010-2015. Vaccine. 2017;35(14):1758-63.) It is important to highlight that vaccines administered during this study, in general, had the same manufacturing origin, being largely produced in Brazilian laboratories, which demonstrates the quality of immunobiologicals produced nationally.

There was no significant association between the number of vaccines received and the presence of adverse events following immunization. A systematic review study indicated the absence of adverse events following immunization in the presence of administration of three or more doses of vaccines.(²⁴24. Zafack JG, De Serres G, Kiely M, Gariépy MC, Rouleau I, Top KA; Canadian Immunization Research Network. Risk of Recurrence of Adverse Events Following Immunization: a Systematic Review. Pediatrics. 2017;140(3):e20163707. Review.)On the other hand, the intramuscular route of administration was associated with the presence of this type of event. This is due to the fact that most vaccines, because they are inactivated, require adjuvants, usually derived from aluminum, which increases the risk of local reactions. (¹⁵15. Lopes SR, Perin JL, Prass TS, Carvalho SM, Lessa SC, Dórea JG. Adverse Events Following Immunization in Brazil: Age of Child and Vaccine-Associated Risk Analysis Using Logistic Regression. Int J Environ Res Public Health. 2018;15(6):1149.)

In this regard, health professionals need to have theoretical and practical knowledge for the administration of vaccines intramuscularly, so as not to incur errors that may generate adverse events following immunization and dissatisfaction of vaccinated individuals.(¹⁴14. Bisetto LH, Ciosak, SI. Analysis of adverse events following immunization caused by immunization errors. Rev Bras Enferm. 2017;70(1):81-89.,²⁵25. Martins JR, Alexandre BG, Oliveira VC, Viegas SM. Permanent education in the vaccination room: what is the reality? Rev Bras Enferm. 2018;71(Suppl 1):668-76.)Certain precautions should be taken when administering a vaccine intramuscularly, considering the body composition of vaccinated individual, the size of the needle and the volume to be administered. (²2. Brasil. Ministério da Saúde. Secretaria de Vigilância em Saúde. Departamento de Vigilância das Doenças Transmissíveis. Manual de vigilância epidemiológica de eventos adversos pós-vacinação. 3a ed. Brasília (DF): Ministério da Saúde; 2014 [citado 2020 Dez 30]. Disponível em: https://bvsms.saude.gov.br/bvs/publicacoes/manual_vigilancia_epidemiologica_eventos_adversos_pos_vacinacao.pdf
https://bvsms.saude.gov.br/bvs/publicaco... )

The methodological quality of this study provided evidence-based data to estimate the incidence and risk of adverse events following immunization among vaccinated individuals. The cohort study provides better association estimates and allows for an accurate chronology between exposures and the event. However, it should be considered that the existence of a causal link between the event and possible exposure factors is complex and presupposes careful analysis of data quality and consistency. Cohort studies on Adverse events following immunization after vaccine licensing are still scarce, with most based on records of immunization information systems.(⁸8. Sato AP, Ferreira VL, Tauil MC, Rodrigues LC, Barros MB, Martineli E, et al. Use of electronic immunization registry in the surveillance of adverse events following immunization. Rev Saude Publica. 2018;52:4.,⁹9. Santos MC, Pontes Netto VB, Andrade MS. Prevalence and factors associated with the occurrence of adverse events following immunization in children. Acta Paul Enferm. 2016;29(6):626-32.)

With the results of this study, the importance of nursing professionals’ conduct in the guidance in the immunization room is advanced in the knowledge, to increase the reporting and investigation of adverse events following immunization and, consequently, the strengthening of their active surveillance.

As a limitation of this study, the inclusion of all age groups in the identification of adverse events following immunization made it difficult to compare the results with the scientific literature, since much of the research on this subject is carried out in children. Another limiting factor is the short follow-up period after vaccination (72 hours), which may have contributed to the non-observation of other possible events that occurred in the upper period of hours compared to that established for this cohort.

Conclusion

The study reinforces the importance of active surveillance of adverse events following immunization in Brazil and points to deficiencies in passive surveillance in the immunization rooms of PHC units, since it does not portray all cases of such events that occurred. The results evidenced contribute to highlight the underreporting of adverse events following immunization and the importance of nursing professionals’ conduct in relation to vaccination guidelines. These findings may support the implementation of good practices in the immunization rooms of PHC units and be useful for future epidemiological studies related to immunization errors identified but not explored in this study.

Acknowledgments

To the Minas Gerais State Research Support Foundation (FAPEMIG - Fundação de Amparo à Pesquisa do Estado de Minas Gerais) and the Ministry of Health - SUS Research Program (PPSUS (Programa de Pesquisa do SUS) - APQ-03509-13). To the Coordination for the Improvement of Higher Education Personnel (CAPES (Coordenação de Aperfeiçoamento de Pessoal de Nível Superior) - Financing Code 001).

Referências

¹
Di Pasquale A, Bonanni P, Garçon N, Stanberry LR, El-Hodhod M, Tavares Da Silva F. Vaccine safety evaluation: Practical aspects in assessing benefits and risks. Vaccine. 2016;34(52):6672-80. Review.
²
Brasil. Ministério da Saúde. Secretaria de Vigilância em Saúde. Departamento de Vigilância das Doenças Transmissíveis. Manual de vigilância epidemiológica de eventos adversos pós-vacinação. 3a ed. Brasília (DF): Ministério da Saúde; 2014 [citado 2020 Dez 30]. Disponível em: https://bvsms.saude.gov.br/bvs/publicacoes/manual_vigilancia_epidemiologica_eventos_adversos_pos_vacinacao.pdf
» https://bvsms.saude.gov.br/bvs/publicacoes/manual_vigilancia_epidemiologica_eventos_adversos_pos_vacinacao.pdf
³
Santos SS, Oliveira VC, Ribeiro HC, Alves TG, Cavalcante RB, Guimarães EA. Analysis of adverse events following immunization in Minas Gerais, Brazil, 2011: a cross-sectional study. Epidemiol Serv Saúde. 2016;25(1):45-54.
⁴
Donà D, Masiero S, Brisotto S, Gottardello L, Lundin R, Borgia E, et al. Special Immunization Service: a 14-year experience in Italy. PLoS One. 2018;13(4):e0195881.
⁵
Stone CA Jr, Rukasin CRF, Beachkofsky TM, Phillips EJ. Immune-mediated adverse reactions to vaccines. Br J Clin Pharmacol. 2019;85(12):2694-706. Review.
⁶
Danova J, Kocourkova A, Celko AM. Active surveillance study of adverse events following immunisation of children in the Czech Republic. BMC Public Health. 2017;17(1):167.
⁷
Haber P, Parashar UD, Haber M, DeStefano F. Intussusception after monovalent rotavirus vaccine-United States, Vaccine Adverse Event Reporting System (VAERS), 2008-2014. Vaccine. 2015;33(38):4873-7.
⁸
Sato AP, Ferreira VL, Tauil MC, Rodrigues LC, Barros MB, Martineli E, et al. Use of electronic immunization registry in the surveillance of adverse events following immunization. Rev Saude Publica. 2018;52:4.
⁹
Santos MC, Pontes Netto VB, Andrade MS. Prevalence and factors associated with the occurrence of adverse events following immunization in children. Acta Paul Enferm. 2016;29(6):626-32.
¹⁰
Yamoah P, Bangalee V, Oosthuizen F. Knowledge and perceptions of adverse events following immunization among healthcare professionals in Africa: a case study from Ghana. Vaccines (Basel). 2019;7(1):28.
¹¹
Bisetto LH, Ciosak SI, Cordeiro TL, Boing MS. Adverse events following immunization of the elderly. Cogitare Enferm. 2016;21(4):1-10.
¹²
Heininger U, Holm K, Caplanusi I, Bailey SR; CIOMS Working Group on Vaccine Safety. Guide to active vaccine safety surveillance: Report of CIOMS working group on vaccine safety - executive summary. Vaccine. 2017;35(32):3917-21.
¹³
Mantwill S, Fiordelli M, Ludolph R, Schulz PJ. EMPOWER-support of patient empowerment by an intelligent self-management pathway for patients: study protocol. BMC Med Inform Decis Mak. 2015;15:18.
¹⁴
Bisetto LH, Ciosak, SI. Analysis of adverse events following immunization caused by immunization errors. Rev Bras Enferm. 2017;70(1):81-89.
¹⁵
Lopes SR, Perin JL, Prass TS, Carvalho SM, Lessa SC, Dórea JG. Adverse Events Following Immunization in Brazil: Age of Child and Vaccine-Associated Risk Analysis Using Logistic Regression. Int J Environ Res Public Health. 2018;15(6):1149.
¹⁶
Stefanizzi P, Stella P, Ancona D, Malcangi KN, Bianchi FP, De Nitto S, et al. Adverse Events Following Measles-Mumps-Rubella-Varicella Vaccination and the Case of Seizures: a Post Marketing Active Surveillance in Puglia Italian Region, 2017-2018. Vaccines (Basel). 2019;7(4):140.
¹⁷
Loiola HA, Almeida AA, Pereira FM, Sardinha AH. Eventos adversos pós-vacinação ocorridos em crianças no município de São Luís, Maranhão. Rev Pesq Saúde. 2016;17(1):17-22.
¹⁸
Mrozek-Budzyn D, Majewska R, Kiełtyka A. Early exposure to thimerosal-containing vaccines and children’s cognitive development. A 9-year prospective birth cohort study in Poland. Eur J Pediatr. 2015;174(3):383-91.
¹⁹
Salik E, Løvik I, Andersen KE, Bygum A. Persistent Skin Reactions and Aluminium Hypersensitivity Induced by Childhood Vaccines. Acta Derm Venereol. 2016;96(7):967-71.
²⁰
Sebastian J, Gurumurthy P, Ravi MD, Ramesh M. Active surveillance of adverse events following immunization (AEFI): a prospective 3-year vaccine safety study. Ther Adv Vaccines Immunother. 2019;7:2515135519889000.
²¹
Santos CA, Costa RS, Silva JL, Santos MR, Gomes BL. Conhecimento, atitude e prática dos vacinadores sobre vacinação infantil em Teresina-PI, 2015. Epidemiol Serv Saúde. 2017;26(1):133-40.
²²
Trucchi C, Zoppi G. Decennial diphtheria-tetanus adult boosters: are they really necessary? J Prev Med Hyg. 2015;56(1):E44-E8. Review.
²³
Myers TR, McNeil MM, Ng CS, Li R, Lewis PW, Cano MV. Adverse events following quadrivalent meningococcal CRM-conjugate vaccine (Menveo®) reported to the Vaccine Adverse Event Reporting system (VAERS), 2010-2015. Vaccine. 2017;35(14):1758-63.
²⁴
Zafack JG, De Serres G, Kiely M, Gariépy MC, Rouleau I, Top KA; Canadian Immunization Research Network. Risk of Recurrence of Adverse Events Following Immunization: a Systematic Review. Pediatrics. 2017;140(3):e20163707. Review.
²⁵
Martins JR, Alexandre BG, Oliveira VC, Viegas SM. Permanent education in the vaccination room: what is the reality? Rev Bras Enferm. 2018;71(Suppl 1):668-76.

Publication Dates

Publication in this collection
26 Nov 2021
Date of issue
2021

History

Received
25 Aug 2020
Accepted
8 Mar 2021

This is an Open Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

[1] ¹
Di Pasquale A, Bonanni P, Garçon N, Stanberry LR, El-Hodhod M, Tavares Da Silva F. Vaccine safety evaluation: Practical aspects in assessing benefits and risks. Vaccine. 2016;34(52):6672-80. Review.

[2] ²
Brasil. Ministério da Saúde. Secretaria de Vigilância em Saúde. Departamento de Vigilância das Doenças Transmissíveis. Manual de vigilância epidemiológica de eventos adversos pós-vacinação. 3a ed. Brasília (DF): Ministério da Saúde; 2014 [citado 2020 Dez 30]. Disponível em: https://bvsms.saude.gov.br/bvs/publicacoes/manual_vigilancia_epidemiologica_eventos_adversos_pos_vacinacao.pdf
» https://bvsms.saude.gov.br/bvs/publicacoes/manual_vigilancia_epidemiologica_eventos_adversos_pos_vacinacao.pdf

[3] ³
Santos SS, Oliveira VC, Ribeiro HC, Alves TG, Cavalcante RB, Guimarães EA. Analysis of adverse events following immunization in Minas Gerais, Brazil, 2011: a cross-sectional study. Epidemiol Serv Saúde. 2016;25(1):45-54.

[4] ⁴
Donà D, Masiero S, Brisotto S, Gottardello L, Lundin R, Borgia E, et al. Special Immunization Service: a 14-year experience in Italy. PLoS One. 2018;13(4):e0195881.

[5] ⁵
Stone CA Jr, Rukasin CRF, Beachkofsky TM, Phillips EJ. Immune-mediated adverse reactions to vaccines. Br J Clin Pharmacol. 2019;85(12):2694-706. Review.

[6] ⁶
Danova J, Kocourkova A, Celko AM. Active surveillance study of adverse events following immunisation of children in the Czech Republic. BMC Public Health. 2017;17(1):167.

[7] ⁷
Haber P, Parashar UD, Haber M, DeStefano F. Intussusception after monovalent rotavirus vaccine-United States, Vaccine Adverse Event Reporting System (VAERS), 2008-2014. Vaccine. 2015;33(38):4873-7.

[8] ⁸
Sato AP, Ferreira VL, Tauil MC, Rodrigues LC, Barros MB, Martineli E, et al. Use of electronic immunization registry in the surveillance of adverse events following immunization. Rev Saude Publica. 2018;52:4.

[9] ⁹
Santos MC, Pontes Netto VB, Andrade MS. Prevalence and factors associated with the occurrence of adverse events following immunization in children. Acta Paul Enferm. 2016;29(6):626-32.

[10] ¹⁰
Yamoah P, Bangalee V, Oosthuizen F. Knowledge and perceptions of adverse events following immunization among healthcare professionals in Africa: a case study from Ghana. Vaccines (Basel). 2019;7(1):28.

[11] ¹¹
Bisetto LH, Ciosak SI, Cordeiro TL, Boing MS. Adverse events following immunization of the elderly. Cogitare Enferm. 2016;21(4):1-10.

[12] ¹²
Heininger U, Holm K, Caplanusi I, Bailey SR; CIOMS Working Group on Vaccine Safety. Guide to active vaccine safety surveillance: Report of CIOMS working group on vaccine safety - executive summary. Vaccine. 2017;35(32):3917-21.

[13] ¹³
Mantwill S, Fiordelli M, Ludolph R, Schulz PJ. EMPOWER-support of patient empowerment by an intelligent self-management pathway for patients: study protocol. BMC Med Inform Decis Mak. 2015;15:18.

[14] ¹⁴
Bisetto LH, Ciosak, SI. Analysis of adverse events following immunization caused by immunization errors. Rev Bras Enferm. 2017;70(1):81-89.

[15] ¹⁵
Lopes SR, Perin JL, Prass TS, Carvalho SM, Lessa SC, Dórea JG. Adverse Events Following Immunization in Brazil: Age of Child and Vaccine-Associated Risk Analysis Using Logistic Regression. Int J Environ Res Public Health. 2018;15(6):1149.

[16] ¹⁶
Stefanizzi P, Stella P, Ancona D, Malcangi KN, Bianchi FP, De Nitto S, et al. Adverse Events Following Measles-Mumps-Rubella-Varicella Vaccination and the Case of Seizures: a Post Marketing Active Surveillance in Puglia Italian Region, 2017-2018. Vaccines (Basel). 2019;7(4):140.

[17] ¹⁷
Loiola HA, Almeida AA, Pereira FM, Sardinha AH. Eventos adversos pós-vacinação ocorridos em crianças no município de São Luís, Maranhão. Rev Pesq Saúde. 2016;17(1):17-22.

[18] ¹⁸
Mrozek-Budzyn D, Majewska R, Kiełtyka A. Early exposure to thimerosal-containing vaccines and children’s cognitive development. A 9-year prospective birth cohort study in Poland. Eur J Pediatr. 2015;174(3):383-91.

[19] ¹⁹
Salik E, Løvik I, Andersen KE, Bygum A. Persistent Skin Reactions and Aluminium Hypersensitivity Induced by Childhood Vaccines. Acta Derm Venereol. 2016;96(7):967-71.

[20] ²⁰
Sebastian J, Gurumurthy P, Ravi MD, Ramesh M. Active surveillance of adverse events following immunization (AEFI): a prospective 3-year vaccine safety study. Ther Adv Vaccines Immunother. 2019;7:2515135519889000.

[21] ²¹
Santos CA, Costa RS, Silva JL, Santos MR, Gomes BL. Conhecimento, atitude e prática dos vacinadores sobre vacinação infantil em Teresina-PI, 2015. Epidemiol Serv Saúde. 2017;26(1):133-40.

[22] ²²
Trucchi C, Zoppi G. Decennial diphtheria-tetanus adult boosters: are they really necessary? J Prev Med Hyg. 2015;56(1):E44-E8. Review.

[23] ²³
Myers TR, McNeil MM, Ng CS, Li R, Lewis PW, Cano MV. Adverse events following quadrivalent meningococcal CRM-conjugate vaccine (Menveo®) reported to the Vaccine Adverse Event Reporting system (VAERS), 2010-2015. Vaccine. 2017;35(14):1758-63.

[24] ²⁴
Zafack JG, De Serres G, Kiely M, Gariépy MC, Rouleau I, Top KA; Canadian Immunization Research Network. Risk of Recurrence of Adverse Events Following Immunization: a Systematic Review. Pediatrics. 2017;140(3):e20163707. Review.

[25] ²⁵
Martins JR, Alexandre BG, Oliveira VC, Viegas SM. Permanent education in the vaccination room: what is the reality? Rev Bras Enferm. 2018;71(Suppl 1):668-76.

Clinical and epidemiological variables	n(%)
Type of reported reactions
Local events	71(55.9)
Simultaneous local and systemic events	39(30.7)
Systemic events	17(13.4)
Abdominal distension
Local pain and redness	120(31.2)
Edema and hardening	36(9.3)
Systemic reactions
Fever ≥37.5ºC	23(6.0)
Headache, nausea, and diarrhea	17(4.3)
Persistent crying and HHE	8(2.1)
Time of onset of symptoms
1-12 hours	51(40.2)
12-72 hours	50(39.3)
15 minutes to 1 hour	18(14.2)
<15 minutes	8(6.3)
None	89(70.1)
PHC units immunization room	20(15.8)
Hospital	7(5.5)
Private physician’s office	6(4.7)
Up to 72 hours of hospitalization
No	121(95.3)
Yes	6(4.7)
AEFI reported and investigated
No	105(82.6)
Yes	22(17.3)
AEFI classification confirmed
AEFI not serious	18(81.9)
Severe AEFI	4(18.1)

Variables	Total n(%)	AEFI (%)		P value
Variables	Total n(%)	Yes	No	P value
Sex
Female	209(54.4)	6.7	93.3
Male	175(45.6)	4.5	95.5	0.372
Age group, years
≥20	242(57.0)	5.0	95.0
1-4	54(19.8)	6.6	93.4	0.915
<1	48(12.5)	6.3	93.7
5-19	40(10.7)	7.3	92.7
Ethnicity
White	202(52.6)	6.4	93.6	0.530
Non-white	182(47.4)	4.9	95.1
Pregnant women
No	374(97.4)	5.8	94.2
Yes	10(2.6)	-	100.0	0.430
Childlike
No	323(84.1)	5.2	94.8
Yes	61(15.9)	8.2	91.8	0.366
Guidance on the vaccine
No	236(61.5)	3.4	96.6
Yes	148(38.5)	9.4	90.6	0.013
Specific information about AEFI
No	228(59.4)	3.5	96.5
Yes	156(40.6)	9.0	91.0	0.024
Conduct in case of AEFI
No	267(69.5)	3.7	96.3
Yes	117(30.5)	10.6	89.8	0.012
Number of vaccines received
One	239(62.2)	6.3	93.7
Three or more	74(19.3)	4.0	96.0
Two	71(18.5)	5.6	94.4	0.772
Intramuscular injection
No	337(87.8)	4.4	95.6	0.004
Yes	47(12.2)	14.9	85.1
Subcutaneous route
Yes	290(75.5)	9.5	90.5
No	94(24.5)	4.5	95.5	0.065
Oral route
Yes	347(90.4)	16.2	83.8
No	37(9.6)	4.6	95.4	0.004

Vaccines	Total (%)	AEFI (%)		P value^*
Vaccines	Total (%)	Yes	No	P value^*
Hepatitis B
No	71.4	7.3	92.7
Yes	28.6	1.8	98.2	0.037
dT
No	76.3	4.8	95.2
Yes	23.7	8.8	91.2	0.150
Penta
No	93.2	5.8	94.2
Yes	6.8	3.8	96.2	0.669
FLU3V
No	70.3	7.4	92.6
Yes	29.7	1.8	98.2	0.029
SCR
No	88.5	5.0	95.0
Yes	11.5	11.4	88.6	0.087
Yellow fever
No	89.3	5.5	84.5
Yes	10.7	7.3	92.7	0.643
VIP
No	91.9	5.9	94.1
Yes	8.1	3.2	96.8	0.532
Pneumo 10
No	91.1	6	94
Yes	8.9	2.9	97.1	0.464
Meningo C
No	91.9	6.3	93.7
Yes	8.1	-	100	0.152
DTP
No	95.8	5.4	94.6
Yes	4.2	12.5	87.5	0.234
Varc
No	95.6	5.7	94.3
Yes	4.4	5.9	94.1	0.978
HPV
No	96.6	5.6	94.4
Yes	3.4	7.7	92.3	0.757
VOP
No	96.1	5.4	95.6
Yes	3.9	13.3	86.7	0.196
ROTA
No	94.8	5.2	94.8
Yes	5.2	15	85	0.067
Hepatitis A
No	98.7	5.4	94.6
Yes	1.3	20	80	0.167
SCRV
No	99.5	5.8	842
Yes	0.5	-	100	0.727
dTpa
No	98.4	5.8	94.2
Yes	1.6	-	100	0.543

Variables	RR	95%CI	p-value^†
Guidance on vaccines
Yes	3.4	1.53-7.68	0.003
No	1	-
Intramuscular injection
Yes	6.1	2.55-14.63	<0.001
No	1	-
Hepatitis B vaccine
Yes	0.1	0.03-0.85	0.031
No	1	-
dT vaccine
Yes	7.9	2.77-22.46	<0.001
No	1	-