Introduction
Since late 2019, the novel severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), known as coronavirus disease 2019 (COVID-19), has brought up many concerns due to its widespread, which has led to a considerable number of studies evaluating a variety of therapeutic approaches for COVID-19, including chloroquine, ivermectin, remdesivir, nucleoside analogs, hydroxychloroquine, monoclonal antibodies, famotidine, convalescent plasma, herbal medicine, and natural compounds [
1‐
3]. To date, utilizing vaccines is one of the most effective ways to control the pandemic. COMIRNATY (the COVID-19 mRNA vaccine BNT162b2 by BioNTech– Pfizer); COVID-19 Vaccine Moderna (mRNA-1273 by Moderna); VAXZEVRIA (ChAdOx1- nCoV19 by AstraZeneca-Oxford University); and COVID-19 Vaccine Janssen (Ad26.COV2.S by Janssen) are among the most popular vaccines used against the COVID-19 [
4]. Notwithstanding the different mechanisms of action, all these vaccines that have been administered have some local and systemic side effects after the injection, such as site pain and swallowing, fever, arthralgia, headache, and vomiting [
5,
6].
Herpesviridae consists of a DNA virus that falls into a varicella-zoster virus (VZV), cytomegalovirus (CMV), Epstein-Barr virus (EBV), and herpes simplex virus (HSV). Herpesviruses (HHV) are mostly known for their ability to cause latent infection, which can become reactivated by triggers such as stress, lack of sleep, physical fatigue, exposure to sunlight, fever, menstruation, and surgical resection [
7]. HHVs are capable of remaining in different types of body cells after the first infection and become reactivated when the host is experiencing an immunocompromised state critically ill patients, sepsis shock, intensive care unit (ICU) administration, usage of anti-inflammatory drugs, and prolonged ventilation are risk factors for the immunocompromised state which can lead to reactivation of these viruses [
8‐
11]. All these conditions can happen during severe and critical COVID-19. Preliminary work on the incidence of herpesvirus reactivation in COVID-19 patients was undertaken by Simmonet et al., which shows that 85% of critically ill patients with COVID-19 in ICU have developed EBV, CMV, and HHV-6 viremia [
9]. It may reasonably be doubted whether the vaccination for COVID-19 can be a reason for the herpes virus’s virus family's reactivation. In this connection, VZV reactivation after vaccine administration was reported in 91 patients who were mostly represented by mild to moderate cutaneous lesions [
12].
Reactivation of other HHVs (EBV, CMV, and HSV) following COVID-19 vaccination have been reported in several case reports. Taken together all these reported cases suggest that although vaccines administration rarely results in severe side effect, early diagnosis and prophylaxis would be essential for decreasing the morbidity and side effects. Therefore, the present study was designed to determine the correlation between the COVID-19 vaccine administration and reactivation of herpes virus and review the cases who have experienced this condition, to increase awareness about the clinical manifestation of herpes reactivation following COVID-19 vaccination.
Methods
We conducted a systematic review following the Preferred Reporting Items for Systematic Reviews and Meta-Analyses (PRISMA) guidelines and guideline provided by the Cochrane Handbook for Systematic Reviews of Interventions [
13,
14]. The protocol of this study was registered with the following number: IR.ABZUMS.REC.1402.116.
Search strategy
A systematic search was conducted in several international databases including Medline (via PubMed), Embase, and Web of science up to 25 September 2022. No restrictions were applied to the search results we retrieved. Furthermore, studies that were eligible were found by evaluating the references of the papers that might be included. The Boolean operators and the following keywords were combined together to create the right approach for our comprehensive search: COVID-19, SARS-CoV-2, coronavirus, Herpesviridae, HSV, herpes simplex virus, varicella-zoster virus, VZV, Epstein-Barr virus, EBV, cytomegalovirus, CMV. Additional file
1: Table S2 provides a thorough description of the search process for each database, along with exact results and performance times.
Eligibility criteria
Using the PICOT specification, the inclusion criteria were as follows: 1) Population: adults receiving COVID-19 vaccine either first or second dose; 2) Intervention: COVID-19 vaccines; 3) Comparison: If applicable (since most studies did not evaluate a control group), those who were not vaccinated against COVID-19; 4) Outcome: reactivation of Herpesviridae; and 5) Type of Study: Observational studies, case reports, and case series. Conference abstracts were also included. The exclusion criteria included review studies, opinion studies, and letters to the editor devoid of any relevant info.
Screening and data extraction
The papers were initially screened by title and abstract, and then the full texts were screened. Discussions were used to settle disagreements. A spreadsheet in Excel was used to extract the data. The extracted for observational studies were Author, Year, Country, Type of study (Registry/ Duration), Population, Total patients, Vaccine, Reactivated virus, and Main Findings of each cohort. For case reports/series we extracted Author, Year, Country, Total Patients, Age, Vaccine, Clinical manifestations/ Reactivated virus, Detection, Comorbidity, and Treatment from each study.
Quality assessment
For the quality assessment of the included studies, we used the Joanna Briggs Institute (JBI) Critical Appraisal Checklist for case reports [
15] and case series [
16]. The eight items in the JBI checklist for case reports cover the patient's demographics, medical history, present clinical state, description of diagnostic tests, therapy, post-intervention clinical state, adverse events, and the providing of takeaways. The JBI checklist for case series is a 10-item scale that assesses the inclusion criteria, method of condition measurement, validity of the diagnostic methods, whether participants were consecutively included, the extent to which participants were included, reporting of the demographic characteristics, clinical information, outcomes, presentation of clinic demographic information, and appropriateness of the statistical analysis [
17]. We used the Newcastle–Ottawa Scale (NOS) for assessing the quality of observational cohorts [
15]. The scale contains 8 signaling question in 3 different domains (Selection, Comparability, and Outcomes).
Data Synthesis
We performed a random effect meta-analysis to estimate the proportions of HHV reactivation among patients vaccinated against COVID-19. Since the incidence of reactivation was rare among the included studies, we decided to present the results as events per 1000 observations. Before pooling the effect estimates, we transformed the raw data using the Logit transformation methods to reduce the variation of the study-specific prevalence. I2 test was evaluated to test the heterogeneity among studies. Sensitivity analysis was performed to found the pooled effects in patients who were clinically diagnosed with herpes zoster. All statistical analyses and graphics were carried out using R (version 4.1.3) [
18] and the meta package (version 5.5–0) [
19]. Furthermore, we describe the results of individual cohorts and case reports/series in a manner of providing a narrative synthesis.
Discussion
This study set out with the aim of literature reviewing to examine the potential correlation between the COVID-19 vaccine administration and possible reactivation of the herpesviruses. In our study, 76 reports were included, which comprised patients who had experienced reactivation of different types of herpesviruses after administration of different types of COVID-19 vaccines. The results from observational cohorts showed that the administration of COVID-19 vaccine, especially mRNA-based ones, could be associated with VZV reactivation. It should be noted that most information available was regarding VZV, and not many reports were available for other types of herpesviruses. Few numbers of published records and the nature of observational study would suggest the evidence regarding the association between COVID-19 vaccine and VZV reactivation to be low. Therefore, in addition to the cohorts included for this study, we also reviewed the reported cases of different HHVs reactivation among those who got COVID-19 vaccines. Among different vaccines, BNT162b2 mRNA or Pfizer–BioNTech have been administrated in more than half of the reported cases. Also, among the reactivated HHVs, including VZV, EBV, CMV, HSV-1 and HSV-6, most cases had experienced the reactivation of VZV, which was reported in nearly 70% of case reports, and the less common one was HSV-6 with only 2 cases.
Close to 100% of the adult population is at least once in a lifetime infected by one of the herpes viridea family viruses [
102]. This family is known for its ability to indicate latent infection after the primary infection, which can reactivate by external or internal triggers. The latent phase of infection is defined as a situation in which the virus is quiescent, meaning the virus is not replicating which prevents the lytic infection and release of new progeny virus particles; in this mode of infection, external or internal stimuli can reactivate the virus, which defined as switching the latent phase to lytic [
103]. Expression of a variety of virus genes during lytic infection leads to make progeny virions. Based on the time of their expression concerning the initial onset of reactivation, they fall into three groups, including IE genes, early (E) genes, and late (L) genes, which encode the proteins whose role in the gene transcription, viral replication, and structural proteins, which result in virion formation and reactivation [
103]. There are different sites in which the viruses become latent; VZV mostly stays latent in neurons of dorsal root ganglia, cranial nerve ganglia, and autonomic ganglia, and EBV displays a latent phase in B lymphocytes and epithelial cells. CMV becomes latent in cells of the myeloid and HSV-1 and HSV-2 reactivate from trigeminal ganglia and sacral ganglia, respectively [
12,
104‐
106]. Based on the reactivation of which type of herpes virus family, different kinds of triggers are capable of reactivating the virus. However, on balance, the most typical stimuli are fever, microbial co-infection, tissue injury, stress, immunocompromised situations, hyperthermia, hormonal imbalance, UV light, allogenic stimulation, and cytokines [
107].
Vaccine administration can provide some of these triggers, such as hyperthermia and tissue injury as other side effects and also immunodeficiency state; in other words, it may theoretically result in the reactivation of herpes viruses. DNA repair and the immune system are known as the two essential systems for defending against threats; loss of function of DNA repair may lead to disability of production of B and T cells resulting in immunodeficiency [
108]. A recent study by Liu et al. involved the pathophysiological alterations after the COVID-19 vaccine in which CD8
+ T cells reduction, increase in classic monocyte contents, increased NF-κB signaling, and reduced type I interferon responses were reported; they have admitted that in the first 28 days after a vaccine injection, the immune system is in the vulnerable state [
109]. Type I IFN receptor signaling in CD8
+ T cells has an essential role in regulating memory cell response to viral infection and blockage of reactivation [
109,
110]. These examples suffice to show that after COVID-19 vaccine administration, reactivation of the herpes virus family may occur. One of the more significant findings to emerge from this study is that, although vaccines are critical for controlling the COVID-19 pandemic, vaccine administration could lead to the reactivation of the herpes virus family. It is true that only few complicated cases have been reported. However, the fact remains that it can influence a large number of people all around the world. Clinical awareness about ways to the early onset diagnosis, preparing the best treatment for patients, and recognizing the patients who are at risk of reactivation are essential.
The results from our study are in line with recent systematic reviews which also reported an association between COVID-19 vaccine and VZV reactivation [
111‐
114]. All previous systematic reviews only included case reports/series regarding the reactivation of VZV. In addition to case reports/series, our systematic review evaluated the available observational evidence regarding VZV reactivation following COVID-19 vaccination, including 6 cohorts. Moreover, our study focused not only on VZV but also on reporting the reported cases available in literature for HSV, EBV, CMV, and HHV-6. Recent systematic review by Martinez-Reviejo eta al. [
112] showed most reported cases of VZV reactivation have their symptoms following the first dose of mRNA vaccination and most of the patients were presented with uncomplicated course, with few having serious disease. These results were in line with our findings for HSV, EBV, and CMV.
A number of limitations need to be considered. First, the number of cases that have been reported is inadequate for certainly assessing the correlation between vaccines and HHVs reactivation. Second, these findings are limited by not using the clinical trial design and lack of comparison between vaccinated and non-vaccinated participants. Considerably more work will need to be done to determine the effect of vaccination on HHVs reactivation. On the other hand, our study is the first to review the possible correlation between COVID-19 and HHVs reactivation. The present study provides a comprehensive overview of the published literature and highlights the available data with rigorous quality assessment.
In conclusion, although vaccination has played an essential role in controlling the COVID-19 pandemic, many different side effects should be considered before administration. However, more research on this topic needs to be undertaken before the association between vaccination and reactivation of the herpes virus family is more clearly understood. To date, the reported cases have shown that clinical physicians should be prepared and aware, so they are capable of recognizing their patients who present with the symptoms of herpes virus reactivation after vaccination and providing them with the best prophylaxis and treatment.
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