Rare Heterogeneous Adverse Events Associated with mRNA-Based COVID-19 Vaccines: A Systematic Review
Abstract
:1. Introduction
2. Materials and Methods
2.1. Search Strategy
2.2. Inclusion and Exclusion Criteria
2.3. Assessment of Study Quality
3. Results
3.1. Myocarditis and Pericarditis
3.1.1. Incidence of Myocarditis following Non-COVID-19 Vaccinations
3.1.2. Characteristics of Patients with Confirmed Myocarditis/Pericarditis Following mRNA COVID-19 Vaccination and Outcomes
3.1.3. Incidence of Myocarditis following mRNA COVID-19 Vaccination
3.2. Thrombocytopenia
3.3. Allergic Hypersensitivities
3.4. CNS and Orofacial Events
3.5. Dermatological Reactions
4. Discussion
Limitations
5. Conclusions
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Conflicts of Interest
References
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Reference | Study Design | Cases, n | Country | Description | Outcome | Major Findings/Conclusions |
---|---|---|---|---|---|---|
Myocarditis and Pericarditis | ||||||
Albert et al., 2021 [22] | Case report | 1 | USA | A 24-year-old male developed symptoms of myocarditis 4 days after a second dose of Moderna vaccine; time to presentation was 96 h post-vaccination. Fulfillment of Lake Louise criteria confirmed acute myocarditis diagnosis. | Transthoracic ECG and LVEF were within normal limits 4 days post-vaccination; cardiac MRI was consistent with findings of myocarditis 5 days post-vaccination. Case was non-fatal with the patient discharged after management. | Data suggested that myocarditis is a slight risk post-COVID-19 vaccination, but no definite association between the Moderna vaccine and post-immunization myocarditis can be made. |
Dickey et al., 2021 [23] | Case series | 6 | USA | Male patients were diagnosed with myocarditis within 2–4 days post-mRNA vaccination (five received second dose of Pfizer-BioNTech vaccine; one received second dose of Moderna vaccine). Time to presentation was 48–96 h post-vaccination. Myocarditis diagnosis confirmed by CMR imaging. | No patients experienced complications; all were discharged home after management. | Clinical presentation and temporal association, when paired with CMR findings, suggest association between vaccination and myocarditis development. However, no definite conclusion can be made as other etiologies cannot be ruled out. Providers should be wary of potential myocarditis development in recently vaccinated patients. |
Marshall et al., 2021 [24] | Case series | 7 | USA | Acute myocarditis or perimyocarditis in seven male adolescents who were otherwise healthy. All developed symptoms within 4 days after receiving second dose of Pfizer-BioNTech vaccine. Time to presentation was 24–48 h post-vaccination. All patients were given cardiac MRIs, which were diagnostic for myocarditis based on 2018 Lake Louise criteria. | All patients resolved symptoms rapidly. | There is no possibility of establishing a relationship between vaccination and myocarditis development based on the data from this case series. |
Rosner et al., 2021 [25] | Case series | 7 | USA | Male patients ranged in age from 19–39; one patient received Janssen vaccine; one patient received first dose of Pfizer-BioNTech vaccine; four patients received second dose of Pfizer-BioNTech vaccine; one patient received first dose of Moderna vaccine. Myocarditis diagnosis based on consistent clinical symptoms, elevated troponin levels, echocardiogram, and CMR imaging results. | All patients received therapeutic interventions (including beta blockers, steroids, colchicine, etc.) and remained in the hospital for 2–4 days. Symptoms resolved in all patients by the time of discharge. | Further studies are needed to determine if the incidence rate of myocarditis development is higher in the post-vaccinated population compared to the background population. COVID-19 vaccines are still favorable for patients to receive given the risk-benefit of COVID-19 infection. |
Vidula et al., 2021 [26] | Case series | 5 | USA | Three females and two males developed heart-related complications (two myocarditis, two pericarditis, and one cardiomyopathy) within days after vaccination (three patients received second dose of Pfizer-BioNTech vaccine; one patient received second dose of Moderna vaccine; one patient received first dose of Pfizer-BioNTech vaccine). | All patients received therapeutic interventions and were discharged. | A causal relationship between mRNA vaccines and myocarditis development cannot be completely proven. |
Singh et al., 2021 [27] | Case report | 1 | USA | A 24-year-old male received second dose of Pfizer-BioNTech vaccine; time to presentation was 72 h post-vaccination. A cardiac MRI confirmed the diagnosis of myocarditis. | Patient was hospitalized for 4 days and discharged under stable condition. Follow up 6 weeks later showed no further complications. | Other causes of myocarditis were excluded through an extensive work-up. No causal relationship between myocarditis and mRNA vaccine can be developed at this time. |
McLean and Johnson, 2021 [28] | Case report | 1 | USA | A 16-year-old male received second dose of Pfizer-BioNTech vaccine; time to presentation was 60 h post-vaccination. Patient diagnosed with suspected myopericarditis based on clinical presentation and laboratory findings. | With therapeutic intervention of 4-dose immunoglobulins, an ECG showed resolution of ST elevation on hospital day 3. Patient was discharged by day 6 on a seven-day course of ibuprofen and famotidine for symptomatic management. | Cause of myocarditis in this patient was not identified; only the temporal association between COVID-19 vaccination and myocarditis development was established. |
Muthukumar et al., 2021 [29] | Case report | 1 | USA | A 52-year-old male received second dose of Moderna vaccine; time to presentation was 72 h post-vaccination. Diagnosed myocarditis was confirmed based on 2018 Lake Louise criteria. | Symptoms were relieved 3 h after onset. Patient was discharged symptom-free after 4 days with no recurrence >3 months after. | Although this case does not prove a temporal relationship between myocarditis and mRNA vaccines, all other potential causes of myocarditis (such as cardiac injury and viral exposure) were excluded. Providers should remain watchful for the development of myocarditis symptoms following mRNA vaccination. |
Abu Mouch et al., 2021 [30] | Case series | 6 | Israel | Male patients (median age of 22) who developed myocarditis after the second (five patients, within 3 days post-vaccination) or first (one patient, after 16 days) dose of the Pfizer-BioNTech vaccine; time to myocarditis presentation was 24–384 h post-vaccination. Myocarditis was confirmed based on cardiac MRI. | Disease course was mild, leading to discharge 4–8 days after admission. | This report on the occurrence of myocarditis in patients after vaccination could potentially be considered as an adverse reaction to the immunization. |
Park et al., 2022 [31] | Case series | 2 | USA | Males aged 15 and 16 years; one patient received first dose of Pfizer-BioNTech vaccine; the other patient received second dose of Pfizer-BioNTech vaccine; time to presentation was 48–72 h post-vaccination. Myocarditis was confirmed based on elevated troponin levels, ST segment elevation, and cardiac MRI results. | Symptoms were self-limiting and both were discharged after 4 days of admission. | No other etiology of myocarditis was found in these patients. The temporal relationship between the mRNA vaccine and myocarditis development raises the possibility of a “vaccine-related self-limited myocarditis”. |
Larson et al., 2021 [32] | Case series | 8 | USA, Italy | Male patients ranging in age from 21–56; three patients received second dose of Moderna vaccine; four patients received second dose of Pfizer-BioNTech vaccine; one patient received first dose of Pfizer-BioNTech vaccine. Time to presentation was 48–96 h post-vaccination. Patients were diagnosed with myocarditis based on laboratory and cardiac MRI findings. | All were non-fatal, with symptom resolution and discharge. | Current research shows the development of post-vaccination myocarditis to be rare. Providers should remain cautious of myocarditis symptoms following vaccination, but further research is needed to fully determine whether there is a causal relationship. |
Kim et al., 2021 [33] | Case series | 4 | USA | Patients (three males and one female) ranged in age from 23–70; two received second dose of Moderna vaccine; two received second dose of Pfizer-BioNTech vaccine; time to presentation was 24–120 h post-vaccination. Myocarditis diagnosis based on elevated troponin levels, CMR imaging abnormalities, and symptom presentation. | Patients received conservative therapeutic interventions in the hospital and were discharged within 2–4 days. | Diagnosis of acute myocarditis in the patients of this case series was straightforward. It is possible that the cases represent a rare adverse effect of a mRNA vaccine. |
Bautista García et al., 2021 [34] | Case report | 1 | Spain | A 39-year-old male received second dose of Pfizer-BioNTech vaccine; time to presentation was 6 h post-vaccination. Cardiac MRI was performed, showing features compatible with acute myocarditis. Other possible cardiac events, such as coronary disease, were ruled out with testing, leading to a diagnosis of acute myocarditis. | Post-treatment clinical outcome was good; patient was discharged symptom-free after 6 days. | The temporal association between onset of myocarditis symptoms and vaccination, combined with the exclusion of other cardiological etiologies, suggested that the development of myocarditis was an adverse effect to the BNT162b2 vaccine. It is further suggested that this adverse effect could be more predominant in genetically predisposed individuals, as well as those with prior health conditions. |
Shaw et al., 2021 [35] | Case series | 4 | USA | Acute myocarditis developed in four patients (two females and two males; median age 20 years) within days of receiving the mRNA vaccines (three Pfizer-BioNTech, one Moderna) occurring post-second dose in two patients (no prior COVID-19 infection) and post-first dose in two patients with prior COVID-19 infection. Time to presentation was 48–600 h post-vaccination. All findings from patient workups were consistent with 2018 Lake Louise criteria for myocarditis. | Treatment details not provided. | Although the potential temporal association between onset of myocarditis and vaccination was possible in this case series, it does not directly prove that vaccination caused the onset. The possibility of spontaneously occurring myocarditis cannot be excluded. |
Mansour et al., 2021 [36] | Case series | 2 | USA | One male and one female aged 25 and 21 years, respectively; both patients received second dose of Moderna vaccine; time to presentation was 24–48 h post-vaccination. Myocarditis diagnosis was confirmed using 2018 Lake Louise criteria. | Both patients were treated, with symptom resolution and discharged within 3 days of admission. | A relationship between the onset of myocarditis symptoms and vaccination is purely speculation in this case. Further data are needed to determine the exact relationship between myocarditis development and vaccination. |
d’Angelo et al., 2021 [37] | Case report | 1 | Italy | A 30-year-old male received second dose of Pfizer-BioNTech vaccine; time to presentation was 72 h post-vaccination. Laboratory data of elevated cardiac and inflammatory enzymes, along with cardiac MRI, were used to confirm myocarditis diagnosis. | Case was non-fatal; patient was discharged 7 days after admission. | Authors speculated that the development of myocarditis is possibly due to recent immunization with the mRNA vaccine based on the temporal relationship between the two events. |
Starekova et al., 2021 [38] | Retrospective study | 5 | USA | Retrospective identification of four males and one female ranging in age from 17–38 years who were diagnosed with myocarditis/pericarditis within 3 days of receiving the second dose of the mRNA vaccine (three Pfizer-BioNTech, two Moderna). Confirmed diagnosis of myocarditis was based on 2018 updated Lake Louise criteria. | Treatment details not provided. | The clinical presentation and temporal relationship between onset of symptoms and time from vaccination suggests a possibility of vaccine-related myocarditis. The observations in this case series are not indicative of causation, and further research is needed to determine the true relationship between vaccination and onset to myocarditis symptoms. |
Tano et al., 2021 [39] | Case series | 8 | USA | Male patients ranging in age from 15–17 years; six patients received second dose of Pfizer-BioNTech vaccine; two patients received first dose of Pfizer-BioNTech vaccine; time to presentation was 24–96 h post-vaccination. All eight patients presented with acute onset retrosternal pain and elevated troponin levels. Seven patients had ST-segment changes on ECG. Three patients showed myocardial edema and late gadolinium enhancement with cardiac MRI. | All were discharged symptom-free within 4 days of admission. | All patients in this case study were diagnosed with perimyocarditis with no alternate etiology other than recent BNT162b2 vaccination. Although this case series cannot conclude a causal relationship between vaccination and myocarditis, providers should still be cautious when patients present with myocarditis symptoms post-vaccination. |
Watkins et al., 2021 [40] | Case report | 1 | USA | A 20-year-old male received second dose of Pfizer-BioNTech vaccine; time to presentation was 48 h post-vaccination. Myocarditis diagnosis was confirmed with cardiac MRI. | Patient recovered and was discharged on medications. | Authors suggested that this case showed a direct temporal relationship between onset of myocarditis symptoms and time from mRNA vaccination. Other potential causes of myocarditis were deemed unlikely, but this case report cannot definitely claim a cause-and-effect relationship between myocarditis and mRNA vaccination. |
Williams et al., 2021 [41] | Case report | 1 | Canada | A 34-year-old male received second dose of Moderna vaccine; time to presentation was 72 h post-vaccination. Laboratory testing and cardiac imaging were performed, which confirmed diagnosis of myocarditis per Lake Louise criteria. | Discharged without symptoms 7 days after admission. | This case report states that the purpose of the case was to bring light to a rare, but potential adverse effect of vaccinations. |
Habib et al., 2021 [42] | Case report | 1 | Qatar | Case of a 37-year-old male who developed myocarditis 3 days after receiving the second dose of the Pfizer-BioNTech vaccine. Diagnosis of myocarditis was confirmed by CMR imaging. | Discharged 6 days after admission. | The most likely diagnosis in this patient is vaccine-related myocarditis. Conclusion was based on the acute onset, temporal association, and exclusion of alternate etiologies in this patient. Further research is needed to determine the relationship between myocarditis onset and vaccination. |
Cereda et al., 2021 [43] | Case report | 1 | Italy | A 21-year-old male received second dose of Pfizer-BioNTech vaccine; time to presentation was 30 h post-vaccination. Cardiac MRI confirmed the myocarditis diagnosis. | Discharged symptom-free after a week of admission. | The development of myocarditis after vaccination can either be causally related or by chance. There are two possible hypotheses for myocarditis development in this patient. The vaccine could have triggered an autoimmune response that resulted in myocarditis, or the vaccine caused an autoimmune/inflammatory response that progressed to myocarditis. Risk-benefit decision is still in favor of patients receiving the vaccine, so providers should just be cautious. |
Hudson et al., 2021 [44] | Case series | 2 | USA | Cases of two male patients (22- and 24-year-old) who developed myocarditis within 3 days of receiving the second dose of the Pfizer-BioNTech vaccines. ECG findings, symptoms, and/or laboratory testing were used to give a diagnosis of probable myocarditis. | Patients were discharged within 3 days of hospital admission. | Further data are needed to determine a relationship between myocarditis development and vaccination, but providers should remain cautious of patients who present with symptoms of myocarditis after recent vaccination. |
Isaak et al., 2021 [45] | Case report | 1 | Germany | A 15-year-old male received second dose of Pfizer-BioNTech vaccine; time to presentation was 24 h post-vaccination. Diagnosis of myocarditis was confirmed per fulfillment of 2018 Lake Louise criteria. | Discharged within 7 days of hospitalization and treatment. | Providers should be made aware of the possibility of vaccine-related myocarditis. |
Snapiri et al., 2021 [46] | Case series | 7 | Israel | Male patients aged 16 or 17; six patients received second dose of Pfizer-BioNTech vaccine; one received first dose of Pfizer-BioNTech vaccine; time to presentation was 24–72 h post-vaccination. Diagnosis of perimyocarditis was made based on suitable clinical presentation of elevated cardiac biomarkers, abnormal echocardiogram, or ECG findings. | All cases were non-fatal with patients discharged symptom-free within 6 days of hospitalization. | COVID-19 could be responsible for the development of myocarditis in this case series. There were differential diagnoses and pathogenesis of the patients, and COVID-19 itself cannot be ruled out as a possible cause. Further research is needed to determine if vaccine-related myocarditis is an adverse effect of an mRNA vaccine. |
Hasnie et al., 2021 [47] | Case report | 1 | USA | A 22-year-old male received first dose of Moderna vaccine; time to presentation was 72 h post-vaccination. CMR imaging was consistent with diagnosis of perimyocarditis. | Symptoms resolved after treatment and patient was discharged, with joint decision to forgo the second dose. | A temporal relationship exists between the development of perimyocarditis and recent COVID-19 vaccination in this patient. Case report highlights a rare adverse effect of COVID-19 vaccinations. Further research is needed to determine the true incidence of this adverse effect in the population. |
Tailor et al., 2021 [48] | Case report | 1 | USA | A 44-year-old male received second dose of Moderna vaccine; time to presentation was 96 h post-vaccination. Cardiac MRI confirmed diagnosis of acute myocarditis. | Supportive treatment and 1 month follow-up confirmed complete symptom resolution. | The patient in this case report had typical clinical and laboratory findings consistent with myocarditis and was diagnosed with vaccine-related myocarditis due to the strong temporal relationship of his symptom development following vaccination. This adverse effect is expected to be rare, and this case report does not prove a temporal relationship. |
Patel et al., 2021 [49] | Case series | 5 | USA | Male patients ranging in age from 19–37; one patient received first dose of Pfizer-BioNTech vaccine; three patients received second dose of Pfizer-BioNTech vaccine; one patient received second dose of Moderna vaccine; time to presentation was 24–72 h post-vaccination. CMR was used to confirm diagnosis of acute myocarditis. | Three patients were treated with colchicine with or without aspirin/ibuprofen. Two patients were not medically treated. All patients were discharged in stable clinical condition. | This case series adds to the growing number of cases that suggest a relationship between mRNA vaccines and myocarditis development. Further research is needed to make a definitive conclusion about the possibility of vaccine-related myocarditis as an adverse effect of mRNA COVID-19 vaccines. |
Mevorach et al., 2021 [51] | Retrospective study | 283 | Israel | Forty-eight percent of myocarditis cases were definitive or probable after receipt of Pfizer-BioNTech mRNA vaccine. Overall risk difference between first and second dose was 1.76 per 100,000 persons. Standardized incidence ratio was 5.34. | Overall, clinical presentation was mild, but one patient experienced fulminant myocarditis that was fatal. | Incidence of myocarditis occurred predominantly in males under the age of 30. Myocarditis after second Pfizer BioNTech dose had the highest standardized incidence ratio for male recipients between the ages of 16 and 19 years (13.60 per 100,000 doses). |
Witberg et al., 2021 [52] | Retrospective cohort study | 54 | Israel | Highest incidence of myocarditis occurred among young male patients between ages of 16 and 29 that had received at least one dose of Pfizer-BioNTech (10.69 per 100,000). | Seventy-six percent of cases were mild, 22% intermediate, and one case was associated with cardiogenic shock. One patient with preexisting cardiac disease died of an unknown cause soon after hospital discharge. | Clinical presentation of myocarditis was generally mild and seen most in males under the age of 30. |
Barda et al., 2021 [53] | Retrospective observational cohort study | 884,828 | Israel | Vaccination against COVID-19 with Pfizer-BioNTech was most strongly associated with an increased risk of myocarditis, with a risk ratio of 3.24. | Not indicated | COVID-19 vaccination was associated with an excess risk of myocarditis. The risk of this adverse event, along with others, was also substantially increased after SARS-CoV-2 infection. The Pfizer BioNTech vaccine was associated with an increased risk of adverse events over a 42 day follow up period, but COVID-19 infection itself could also increase the risk of adverse events, potentially ones that are much more probable to be fatal. |
Secondary Immune Thrombocytopenia | ||||||
Tarawneh and Tarawneh, 2021 [54] | Case report | 1 | USA | Case of 22-year-old male who developed petechiae and gum bleeding 3 days after receiving the first dose of the Pfizer-BioNTech vaccine. Laboratory tests confirmed severe thrombocytopenia. | Patient received platelet transfusion and intravenous immunoglobulin. Symptoms improved and was discharged 3 days after emergency hospitalization. | There is no certainty that this case of thrombocytopenia was vaccine-induced and may have been coincidental. Another consideration is that 2 months prior, the patient’s platelet count was near the lower limit of normal, so it is difficult to exclude other causes. |
Lee et al., 2021 [55] | Case series | 20 | USA | Reports, identified through registry/databases, described cases of 20 patients with varying levels of secondary thrombocytopenia following vaccination with Moderna or Pfizer-BioNTech vaccines | Cases were nonfatal. | Authors recommend getting a baseline platelet count in patients with pre-existing thrombocytopenia before receiving either the Pfizer-BioNTech or Moderna vaccine and a follow-up platelet count after vaccination. Study also showed possible treatment options for patients with potential secondary ITP; most patients responded favorably to treatment with corticosteroids or IVIG, which points to an immune-mediated mechanism that characterizes ITP. |
Welsh et al., 2021 [56] | Case series | 28 | USA | Analysis of 28 VEARS-reported cases of thrombocytopenia (15 cases after the Pfizer-BioNTech vaccine and 13 cases after the Moderna vaccine). | Not indicated | Incidence considered rare based on the reporting rate. Many patients who were affected had comorbidities, including autoimmune disorders or prior history of ITP. Authors concluded that there is no safety concern associated with the mRNA COVID-19 vaccines at this time. |
Helms et al., 2021 [57] | Case report | 1 | USA | Case of a 74-year-old male who developed refractory thrombocytopenia within 24 h post-vaccination with the Moderna vaccine. | Patient received platelet transfusion and intravenous immunoglobulins. Patient improved and was transferred to skilled nursing facility 25 days post-vaccination. | The authors stated that it is uncertain whether refractory ITP secondary to vaccination with a mRNA COVID-19 vaccine will be a rare adverse event. Nonetheless, this uncertainty should not limit the use of mRNA vaccination as a public health measure to prevent or mitigate COVID-19 infection. |
Allergic Hypersensitivity Reactions | ||||||
Dages et al., 2021 [58] | Single-center, retrospective cohort study | 68 | USA | The goal was to determine if patients with a history of atopic disease on subcutaneous immunotherapy (SCIT) are at an increased risk of developing an allergic reaction to the COVID-19 vaccine. | Within the cohort, none of the patients experienced an allergic reaction (including an anaphylactic reaction) to a mRNA COVID-19 vaccine. | It is recommended that patients with a history of allergic reactions have an observation time of 30 min post-vaccination instead of the standard 15 min of observation. Due to the small sample size, it is difficult to recommend the timing of administration between the COVID-19 vaccine and SCIT. |
Krantz et al., 2021 [59] | Case series | 47 | USA, Denmark | Of the total patients referred for potential immediate allergic reactions to the Pfizer- BioNTech mRNA vaccine, 39 had histories of mild reactions and eight had anaphylaxis to the first vaccine dose. The eight patients with anaphylaxis were supervised during receipt of their second dose. | Eight patients with anaphylaxis to the first Pfizer-BioNTech dose tolerated the second dose. | The eight patients who tolerated a second dose despite anaphylaxis to the first suggests a non-IgE-mediated mechanism. The authors state that those with potential for anaphylaxis should undergo risk stratification to weigh the benefit and risk of a second dose. |
CNS and Orofacial Events | ||||||
Koh et al., 2021 [60] | Multi-center, prospective observational cohort study | 457 | Singapore | A total of 457 individuals out of about 1.4 million vaccinated persons developed neurological disorders. | Acute ischemic stroke was the most common cerebrovascular disorder (n = 243). The most common post-vaccination CNS syndrome was seizures (n = 33). Eleven patients experienced Bell’s Palsy after vaccination with the Pfizer vaccine. One patient who experienced cerebral venous thrombosis remained neurologically debilitated after discharge for 6 weeks. Otherwise, patients had good functional outcomes upon discharge. | No neurological morbidity was found. Authors concluded that their observational study does not establish causal relationships between the reported neurological complications and recent mRNA vaccination. The benefits of COVID-19 mRNA vaccination exceed any potential concerns for neurological adverse effects. |
García-Grimshaw et al., 2021 [61] | Prospective observational cohort study | 4258 | Mexico | Observational study of 704,003 first-doses recipients of the Pfizer-BioNTech vaccines showing an observed frequency of serious neurological adverse events at 47/million doses. | Non-serious neurological adverse events post-vaccination had an overall incidence rate of 600.7 cases per 100,000 administered doses. Headache was the most frequent (62.2%). Serious neurological adverse events post-vaccination had an overall incidence rate of 2.4 cases per 100,000. 76.3% of neurological adverse events reported in this study were female. | Pfizer-BioNTech mRNA vaccine is predominantly safe and effective. Concerns about potential neurological adverse effects should not limit the use of vaccination to reduce COVID-19 severity and mortality. |
Saito et al., 2021 [62] | Case report | 1 | Japan | Case report of 42-year-old female who developed aseptic meningitis one week after receiving the first dose of the Pfizer-BioNTech vaccine. | Five days after admission, headache and nausea were significantly improved. Patient was discharged at day 7 post-admission, and experienced no headache, nausea, or fever for at least 4 months after discharge. | Authors concluded that results suggested a rare type of immune-mediated aseptic meningitis, with molecular mimicry as a potential mechanism. |
Eom et al., 2022 [63] | Case series | 2 | Republic of Korea | Case series of male (81 years of age) and female (23 years of age) who developed acute transverse myelitis 3 days after the second dose, and 3 weeks after the first dose, respectively. Both received the Pfizer-BioNTech vaccine. | One month after the end of treatment, male patient still had limitation of finger movements. Three weeks after treatment, leg weakness in female patient improved and she could walk with unilateral assistance. | Causation could not be established between the patients’ neurological symptoms and mRNA COVID-19 vaccination. |
Chun et al., 2021 [64] | Case series | 9 | Republic of Korea | Patients (median age of 7) who developed various mild oral symptoms following a median of 3 days post-vaccination (four Pfizer-BioNTech; five Astra Zeneca). | All the patients’ symptoms responded to treatment within a short time. | This case series suggests oral mucositis, ulceration, and neuropathic pain as possible orofacial adverse effects following COVID-19 vaccination. Clinicians should understand the potential risk and guide patients appropriately to lower vaccine hesitancy. |
Mazur et al., 2021 [65] | Survey-based study | 223 | Italy, Poland, France, Germany, Switzerland, Albania, Denmark, Norway, UK, Spain | Survey of 700 individuals who received COVID-19 vaccines with 3.1% and 5.4% reportedly experiencing oral and facial symptoms, respectively. | Among oral symptoms, burning was the most common adverse effect, with 2.7% and 3.4% after the first and second dose, respectively. | This study observed no significant correlation between vaccine administration for COVID-19 and orofacial manifestations. |
Dermatological Reactions | ||||||
McMahon et al., 2021 [66] | Provider-facing registry-based study | 414 | USA | For the period analyzed, study identified 414 cutaneous reactions to mRNA COVID-19 vaccines from Moderna (83%) and Pfizer-BioNTech (17%) vaccination. | No serious adverse events developed in any registry patients following either the first or second dose of mRNA vaccine. | Reported cases were predominantly female (90%), white (78%), and from the US (98%). Cutaneous side effects of mRNA vaccination are usually self-limiting, without requiring any therapeutic intervention. The risk of cutaneous adverse events does not outweigh the benefits of COVID-19 vaccination. |
Edriss et al., 2021 [67] | Case report | 1 | USA | Case of 54-year-old male who developed a pruritic rash one week after receiving the first dose of the Pfizer-BioNTech vaccine in the same arm. | Treatment yielded improvement at the first follow-up visit. | Cutaneous reactions after receipt of the Pfizer-BioNTech mRNA vaccine are treatable; therefore, the benefit of receiving COVID-19 vaccination outweighs the risks. |
Cyrenne et al., 2021 [68] | Case series | 2 | Canada | Two cases of suspected vaccine-associated skin reactions, first in a woman in her 20s two days after her first-dose vaccination and the second in a male in his 40s three weeks after the second dose. Both received the Pfizer-BioNTech mRNA vaccine. | One female patient was treated with topical corticosteroids, and it resolved her diagnosis of a pityriasis rosea-like eruption. One male patient was given doxycycline and bilastine to resolve his pityriasis-rosea-like eruption. | Further research is needed to determine if causality exists between mRNA COVID-19 vaccination and dermatological adverse events, but providers should be aware of the various cutaneous manifestations reported. Authors recommended that clinicians consider providing pre-vaccination counseling on topical medication use and symptom alleviation. |
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Oueijan, R.I.; Hill, O.R.; Ahiawodzi, P.D.; Fasinu, P.S.; Thompson, D.K. Rare Heterogeneous Adverse Events Associated with mRNA-Based COVID-19 Vaccines: A Systematic Review. Medicines 2022, 9, 43. https://doi.org/10.3390/medicines9080043
Oueijan RI, Hill OR, Ahiawodzi PD, Fasinu PS, Thompson DK. Rare Heterogeneous Adverse Events Associated with mRNA-Based COVID-19 Vaccines: A Systematic Review. Medicines. 2022; 9(8):43. https://doi.org/10.3390/medicines9080043
Chicago/Turabian StyleOueijan, Rana I., Olivia R. Hill, Peter D. Ahiawodzi, Pius S. Fasinu, and Dorothea K. Thompson. 2022. "Rare Heterogeneous Adverse Events Associated with mRNA-Based COVID-19 Vaccines: A Systematic Review" Medicines 9, no. 8: 43. https://doi.org/10.3390/medicines9080043
APA StyleOueijan, R. I., Hill, O. R., Ahiawodzi, P. D., Fasinu, P. S., & Thompson, D. K. (2022). Rare Heterogeneous Adverse Events Associated with mRNA-Based COVID-19 Vaccines: A Systematic Review. Medicines, 9(8), 43. https://doi.org/10.3390/medicines9080043