Haemophagocytic lymphohistiocytosis following COVID-19 mRNA vaccination

  1. Vernon Wu 1,
  2. Carlos A Lopez 1,
  3. Adam M Hines 1 and
  4. Jacqueline C Barrientos 1 , 2
  1. 1 Monter Cancer Center, Northwell Health, New Hyde Park, New York, USA
  2. 2 CLL Research & Treatment Program, Northwell Health Feinstein Institutes for Medical Research, Manhasset, New York, USA
  1. Correspondence to Dr Jacqueline C Barrientos; jcb5y@yahoo.com

Publication history

Accepted:25 Jan 2022
First published:16 Mar 2022
Online issue publication:16 Mar 2022

Case reports

Case reports are not necessarily evidence-based in the same way that the other content on BMJ Best Practice is. They should not be relied on to guide clinical practice. Please check the date of publication.

Abstract

The development of vaccinations has been instrumental in the ongoing effort to combat the COVID-19 pandemic. Although the benefits of vaccination are unquestionable, there have been reports of potentially rare life-threatening complications following vaccination including thrombocytopaenia, haemolytic anaemia, vasculitis and myocarditis. Haemophagocytic lymphohistiocytosis (HLH), a rare but life-threatening inflammatory condition, has also been described postadenoviral vector COVID-19 vaccination but it has never been reported post-messenger RNA (mRNA) COVID-19 vaccination. We report two cases of HLH admitted to our hospital after administration of COVID-19 mRNA vaccines. We also searched the vaccine adverse event reporting system and found 50 reports of suspected HLH following COVID-19 vaccination. Presently, we cannot define a causality between COVID-19 mRNA vaccination and HLH development. However, we hope the reporting of our two cases (and additional cases seen in the adverse event reporting database) will help us determine whether there is a potential relationship. Prompt recognition of this condition is of utmost importance to initiate life-saving therapy.

Background

Over 200 million cases of COVID-19 infections have been confirmed worldwide. Multiple platforms were used to develop vaccine candidates, including messenger RNA (mRNA) vaccines encoding the SARS-CoV-2 spike glycoprotein. The mRNA vaccines, tozinameran and elasomeran, were approved by the US Food and Drug Administration (FDA) under emergency use authorisations; currently only tozinameran has full FDA approval. Both are highly efficacious in preventing serious outcomes, including hospitalisation, severe illness and death. Current knowledge about the safety of COVID-19 vaccines relies on data from phase 1–3 randomised controlled trials and vaccine safety surveillance systems.1 2 Due to the highly contagious nature of the disease and the pandemic straining healthcare systems, the benefits of mass vaccination efforts are unquestionable.3 Nonetheless it is important to recognise that similar to post-COVID-19 infectious complications, rare life-threatening complications post vaccination have also been reported including thrombocytopaenia, haemolytic anaemia, vasculitis and myocarditis.4–9

Haemophagocytic lymphohistiocytosis (HLH) is a rare, severe, uncontrolled hyperinflammatory reaction where activated lymphocytes and histiocytes infiltrate all organs and secrete large amounts of cytokines, leading to tissue damage and organ failure. Characteristic features include prolonged fever, splenomegaly, pancytopenia and haemophagocytosis. Biochemical markers include hyperferritinaemia, hypertriglyceridaemia and hypofibrinogenaemia. Due to its rarity and variable clinical presentation, an accurate diagnosis may be delayed, leading to substantial morbidity and mortality. Although HLH has been described post-Covid-19 infection as well as postadenoviral vector vaccination,10–14 it has never been reported post-mRNA vaccination. We report two cases of HLH admitted to our hospital from June to August 2021 after administration of mRNA vaccines. We also searched the vaccine adverse event reporting system (VAERS) (last release 09/10/21) for ‘HLH’ and found 50 reports of suspected HLH postvaccination.15 We cannot currently define a causal relationship between vaccination and the development of HLH, additional surveillance is needed to understand whether a relationship exists, if any, between them.

Case presentation

Patient 1 is a 60-year-old man with a history of Barrett’s esophagus who developed altered mental status and slurred speech 6 days after the first dose of tozinameran (BNT162b2 Pfizer-BioNTech vaccine). He was initially diagnosed with transient ischaemic attack, but progressively deteriorated over the next month developing fevers, drenching night sweats, loss of appetite, unintentional weight loss, delirium and became non-ambulatory.

Patient 2 is a 32-year-old woman with no prior medical history who developed high fevers 4 weeks after the second dose of tozinameran. She was briefly hospitalised at an outside hospital with new anaemia (haemoglobin 80 g/L), hyperferritinaemia (35 000 ng/mL) and elevated transaminases. Rheumatological, oncological and infectious workups were negative, and fevers worsened despite 8 weeks of prednisone 50 mg daily. By the ninth week of worsening symptoms as an outpatient, fevers reached 40°C and became debilitating. She was re-admitted and was transferred to our institution for further management. By this time her ferritin had increased to 68 212 ng/mL (normal range 15–150 ng/mL) and neopterin was 9.5 ng/mL (normal range <2.5 ng/mL).

Investigations

Acute COVID-19 infection was ruled out in both patients based on negative PCR tests of nasopharyngeal specimens. Negative nucleocapsid and positive anti-spike antibodies confirmed no prior COVID-19 infection.

Patient 1 met 6/9 HLH criteria including a bone marrow biopsy that showed haemophagocytosis (table 1, figure 1A). Patient 2 met 7/9 HLH criteria including haemophagocytosis on bone marrow biopsy (table 1, figure 1A). The diagnosis of HLH was made in both patients based on these criteria. Table 1 details the extensive infectious, malignant and rheumatological workups that were obtained in both patients to rule out alternate aetiologies for HLH.

Table 1

Patientcharacteristics and clinical data

Patient 1 Patient 2
ANC, absolute neutrophil count; BAL, bronchoalveolar lavage; CCP, cyclic citrullinated peptide; CSF, cerebrospinal fluid; Hgb, haemoglobin; HLH, haemophagocytic lymphohistiocytosis; RF, rheumatoid factor; SS-A, Sjogren's Syndrome A; SS-B, Sjogren's Syndrome B.
Age (years) 60 32
Sex Male Female
Type of vaccine received Tozinameran (Pfizer-BioNTech COVID-19) Tozinameran (Pfizer-BioNTech COVID-19)
Total doses of COVID-19 vaccine received 2 2
Days between first and second vaccine administrations 22 22
Symptom onset (days since first vaccine) 6 52
Symptoms experienced Altered mental status, fevers, malaise, night sweats, unintentional weight loss Arthralgias, fevers, myalgias, shortness of breath, weakness
Days since first vaccine to HLH diagnosis 59 59
HLH criteria met at diagnosis
 Fever (Tmax 38.3°C) Fever (Tmax 40.8°C)
Haemophagocytosis (bone marrow) Haemophagocytosis (bone marrow)
Anaemia (Hgb 88 g/L, nadir 69 g/L) Anaemia (Hgb 74 g/L, nadir 68 g/L)
Thrombocytopaenia (platelets 43 k/µL, nadir 17 k/µL) Thrombocytopaenia (platelets 79 k/µL, nadir 64 k/µL)
Ferritin (1365 ng/mL) Ferritin (68 212 ng/mL)
Splenomegaly (18.4 cm) Fibrinogen (118 mg/dL)
Soluble IL-2R (33 903.1 pg/mL) Triglycerides (527 ng/mL)
Triglycerides (360) Soluble IL-2R (14 130.2 pg/mL)
CXCL9 (16 347 pg/mL)
HLH criteria not met at diagnosis Fibrinogen (291 mg/dL) Splenomegaly (outside imaging unavailable)
NK cell activity (unavailable) NK cell activity (unavailable)
ANC 2.02 k/uL ANC 8.25 k/uL
CXCL9 (unavailable)
Total HLH criteria met 6 7
HLH-probability calculator (HScore) 198 271
(80%–88% probability of HLH) (>99% probability of HLH)
Treatment Etoposide +Dexamethasone (HLH-94) Etoposide +dexamethasone (HLH-94); emapalumab-lzsg +dexamethasone
Date of treatment (days since first vaccine) 61 116
Outcome to date Partial remission. Posthospitalisation has ongoing night sweats and malaise that worsen on steroid discontinuation. Repeat biopsies off therapy of two mildly hypermetabolic areas show no malignancy or infection. HLH markers are rising despite weeks on steroids. Improved initially on HLH-94 treatment, but became intolerant of chemotherapy due to neutropaenia. HLH markers and fevers began to reoccur through treatment; due to suspected HLH refractoriness, emapalumab-lzsg was started. Currently improving.
Notes Initially failed to improve on prednisone 1 mg/kg×5 days prior to definitive HLH treatment Failed to improve on solumedrol 1000 mg×2 doses prior to definitive HLH treatment
Infectious Workup (negative) Aspergillus, Babesiosis, Bartonellosis, Brucellosis, Creutzfeld-Jacob disease, cryptococcus neoformans (CSF), cytomegalovirus (serum +CSF), enterovirus (CSF), Epstein-Barr Virus, Haemophilus influenzae (CSF), herpes simplex virus 1/2 (CSF), HIV 1/2, human herpesvirus 6 (CSF), human parechovirus (CSF), JC virus (CSF), leptospirosis, listeria (CSF), neisseria (CSF), neurosyphilis, parvovirus, Q fever, SARS CoV-2, streptococcus agalactiae (CSF), streptococcus pneumonia (CSF), tuberculosis, tularaemia, varicella (CSF), West Nile Virus (CSF), cultures (BAL +CSF) Anaplasmosis, Aspergillus, Babesiosis, Bartonellosis, BK Virus, Brucellosis, Cryptococcus (CSF), Cytomegalovirus (CSF), Epstein-Barr Virus (Serum +CSF), ehrlichiosis, hepatitis A/B/C, histoplasmosis, herpes simplex virus 1/2, HIV, legionella, leptospirosis, lyme (blood +CSF), parvovirus, neurosyphilis, Rocky Mountain Spotted Fever, SARS CoV-2, Tuberculosis (Quantiferon-Gold, Sputum Cultures and PCR), Tularaemia, West Nile Virus (CSF), cultures (blood +CSF)
Rheumatologic workup (negative) Dermatomyositis/polymyositis/antisynthetase syndrome (anti Jo Ab, anti PL-7 Ab, anti PL-12 Ab, anti EJ Ab, anti OJ Ab, anti SRP Ab, anti Mi-2 Ab, anti U3 RNP Ab, anti MDA5 Ab, anti NXP-2 Ab, anti-TIF gamma Ab, anti PM-Scl 100 Ab, anti U2 snRNP Ab, anti U1-RNP Ab, anti Ku Ab, anti SS-A-52kD Ab, anti SAE1 Ab), IgG4-related disease (IgG4), mixed connective tissue disorder (anti-RNP), rheumatoid arthritis (CCP, RF), sarcoidosis (ACE), SLE (ANA, anti-dsDNA Ab, anti-Smith A/B Ab), vasculitis (c-ANCA, p-ANCA) Mixed connective tissue disorder (anti-RNP), SLE (ANA, anti-Smith Ab, anti dsDNA Ab, C3, C4), scleroderma (anti SS-A/SS-B Ab), systemic sclerosis (anti centromere Ab), vasculitis (c-ANCA, p-ANCA)
Oncological workup (negative) CT scan of chest, abdomen and pelvis; mediastinal excisional lymph node biopsy; peripheral blood flow cytometry; bone marrow biopsy and aspirate; lumbar puncture (flow cytometry and cytopathology); positron emission tomography (PET) scan; PET scan-guided biopsy of FDG-avid mediastinal lymph node; esophagogastroduodenoscopy CT scan of chest, abdomen and pelvis; left axillary lymph node biopsy; bone marrow biopsy and aspirate; peripheral blood flow cytometry; lumbar puncture (flow cytometry and cytopathology).

Differential diagnosis

The differential diagnosis was very broad in both patients. Table 1 lists the complete work up for each patient, which aimed to rule out not only an aetiology for their fevers but also an underlying aetiology that could result in secondary HLH. Given their high fevers, infectious aetiologies were high on the differential for both patients. In addition to blood cultures and ruling out SARS CoV-2 infection, evaluation for Aspergillus, Babesia, Bartonella, Brucella, Leptospira, Tuberculosis and Francisella tularensis in the serum were performed. Both patients also had lumbar punctures to evaluate for bacterial, fungal and viral aetiologies; studies included evaluation for Cryptococcus, Epstein-Barr virus, cytomegalovirus and West Nile virus.

When infectious aetiologies were negative, both patients also underwent an extensive rheumatologic workup which included evaluation for systemic lupus erythematosus, mixed connective tissue disorder and vasculitis.

CT, including positron emission tomography CT, was also performed to evaluate for oncological explanations for their symptoms. Although lymphadenopathy was seen in both patients, biopsies of suspicious lymph nodes were non-diagnostic for malignancy. Additionally, both patients had bone marrow biopsies as part of the workup for fever of unknown origin, both to evaluate for HLH as well as to rule out a haematological malignancy which subsequently revealed evidence of haemophagocytosis. A final diagnosis of HLH was even more suggestive following drastic clinical response to HLH-directed treatment as well as further serological testing (elevated CXCL9, neopterin).

Treatment

Patient 1 was initially treated with 5 days of prednisone 1 mg/kg prior to the diagnosis of HLH but his symptoms were refractory to this treatment, and he continued to deteriorate. He was subsequently started on HLH-directed therapy with etoposide and dexamethasone.

Patient 2 had initial improvement in her symptoms and pancytopenia after starting etoposide and dexamethasone but after her fourth etoposide dose she developed neutropenic fevers and haemodynamic instability without identifiable infectious source. Due to concern for disease refractoriness, she was started on emapalumab-lzsg.

Outcome and follow-up

Patient 1 had dramatic improvement in his speech, ambulation and pancytopenia within 48 hours of starting etoposide and dexamethasone (figure 1B,C). He was discharged 13 days after his first etoposide dose and he initially continued to improve on outpatient follow-up visits, however, symptoms (night sweats, malaise) relapse and his HLH biomarkers worsen (worsening thrombocytopaenia, rising triglycerides, elevated ferritin) anytime he is tapered off steroids. He has been started on cyclosporine without meaningful improvement, so we have restarted steroids.

Patient 2 similarly had rapid improvement in her symptoms and laboratory markers after starting second line HLH-directed therapy. She was discharged home after 5 weeks and continues to improve on outpatient follow-up visits. She completed eight treatments of emapalumab-lzsg and on discontinuation, laboratory markers worsened, so we plan for a longer course of emapalumab-lzsg.

For patient 1, we considered intrathecal methotrexate as treatment for the neurological manifestations of HLH. Although intrathecal therapy has been used in thrombocytopenic patients, there is no consensus on a safe cut-off value of platelet counts. The patient had profound thrombocytopaenia (<20 000/µL), which was unresponsive to platelet transfusions during his hospital course. Given the risks of haemorrhagic complications, we were unable to offer this therapeutic intervention during the hospitalisation. Additionally, his neurological symptoms improved rapidly with systemic first line treatment for HLH with etoposide and steroids.

For patient 2, we discussed pursuing an allogeneic haematopoietic stem cell transplant as she initially had worsening laboratory HLH markers after emapalumab was being tapered. We are currently awaiting results of genetic testing to rule out hereditary HLH mutations that may have predisposed her to developing HLH before we subject her to transplant considering that she is being weaned off the emapalumab. Her biomarkers have also improved with prolonged emapalumab so we have currently deferred pursuit of transplant.

Elevated D-dimer can also be seen in HLH as many patients will have hepatitis and abnormal coagulation parameters. Although D-dimer is not included in the diagnostic criteria for HLH, it may be of interest to trend this lab to evaluate for response to HLH directed therapy.

Discussion

Over 350 million mRNA-vaccine doses have been administered in the USA without reported cases of HLH post-mRNA vaccination in the literature.16 In addition to our two patients, we found 48 additional reports of HLH following COVID-19 infection in the VAERS database (table 2 and online supplemental table S1). There were 25 females/25 males with a median age of 58-years-old. The distribution of vaccines was Pfizer (34), Moderna (14) and Janssen (2). Symptoms developed a median of 8 days (0–61 days) post first (22) and second (24) dose. All but one case required hospitalisation (median 14 days). At the time of the reporting, only 20% had recovered and seven patients had died. It is unclear if all patients met criteria for HLH with several reports indicating an alternative diagnosis was suspected.

Supplementary data

[bcr-2021-247022supp001.pdf]
Table 2

Reported cases of HLH related to SARS/CoV-2 vaccine to the VAERS database

Case* Age (years) Sex SARS/CoV-2 Vaccine Vaccine # Symptom onset from vaccine (days) Symptoms HLH criteria Days Hospitalised Death Other diagnosis considered Reference
Data collected from National Vaccine Information Centre’s Vaccine Adverse Events Reporting System (https://www.medalerts.org/vaersdb).15
1 80 M Moderna 2 1 Fever, haematoma, weakness Bicytopaenia, ferritin, fever, haemophagocytosis, IL-2R 15 No 15
2 30 M Moderna 1 30 Abdominal pain, fever, shortness of breath Ferritin, fever, haemophagocytosis, hypertriglyceridaemia 7 No 15
3 59 F Pfizer 2 1 Weakness, shortness of breath Haemophagocytosis 7 Yes 15
4 57 F Moderna 1 42 Altered mental status, weakness Haemophagocytosis 7 No 15
5 77 M Moderna 2 13 Headache Ferritin, haemophagocytosis, hypertriglyceridaemia Unknown No 15
6 67 M Pfizer 1 9 Dizziness, fever, shortness of breath Fever, haemophagocytosis 12 No 15
7 74 F Moderna 2 17 Fever, weakness Haemophagocytosis, hypofibrinongenaemia 8 No 15
8 40 F Pfizer 1 16 Abdominal pain, diarrhoea, dizziness, jaundice, shortness of breath Unknown Unknown No 15
9 30 M Pfizer 2 41 Fever Fever, haemophagocytosis 8 No 15
10 62 M Moderna 2 4 Fever, shortness of breath Ferritin, haemophagocytosis 8 No 15
11 65 M Moderna Unknown 4 Fatigue Ferritin, sIL2r 9 No 15
12 46 M Moderna 1 5 Altered mental status, fatigue, shortness of breath Haemophagocytosis 30 No 15
13 56 M Janssen Unknown 0 Fever Fever, haemophagocytosis 34 No 15
14 23 F Moderna 2 8 Fever, rash Haemophagocytosis 22 No Macrophage activation syndrome 15
15 62 M Pfizer 2 38 Swollen lymph nodes Ferritin, haemophagocytosis, splenomegaly 12 No 15
16 16 M Pfizer 2 1 Dizziness, fever, weight loss Bicytopaenia, ferritin, fever, haemophagocytosis, hypertriglyceridaemia 16 No 15
17 15 F Pfizer 1 7 Abdominal pain, altered mental status, diarrhoea, fever Ferritin, fever 5 No Lamitcal-induced HLH 15
18 22 F Moderna 2 0 Arthralgias, fever Fever 16 No Macrophage activation syndrome 15
19 16 F Pfizer 1 21 Chest pain Haemophagocytosis 32 Yes 15
20 20 M Pfizer 2 34 Diarrhoea, fever Bicytopaenia, fever, haemophagocytosis 21 No 15
21 45 F Pfizer 1 19 Fever, rash, weakness Fever, haemophagocytosis 20 No Macrophage activation syndrome 15
22 Unknown F Pfizer 2 14 Altered mental status Haemophagocytosis 61 Yes 15
23 60 M Pfizer 2 6 Altered mental status, fever Bicytopaenia, ferritin, fever, haemophagocytosis, sIL2r, splenomegaly 69 No 15
24 Unknown F Pfizer 1 Unknown Unknown Unknown Unknown No EBV infection 15
25 64 F Pfizer 1 47 Fevers, decreased appetite, lymphadenopathy, weakness, weight loss Fever 20 No Lymphoma 15
26 Unknown Unknown Moderna 1 Unknown Unknown Unknown Unknown No 15
27 58 F Moderna 2 29 Fatigue, fever Bicytopaenia, fever, haemophagocytosis Unknown No 15
28 15 M Pfizer 2 2 Fever Bicytopaenia, ferritin, fever, sIL2r Unknown No 15
29 31 F Pfizer 2 61 Blurry vision, chest pain, fever, headache, myalgias, rash, shortness of breath, weakness Bicytopaenia, ferritin, fever, haemophagocytosis, hypertriglyceridaemia, sIL2r 93 No 15
30 26 M Pfizer 1 17 Shortness of breath Unknown 8 Yes HSV pneumonia 15
31 43 M Pfizer 1 1 Rash Ferritin Unknown No Macrophage activation syndrome 15
32 90 F Pfizer Unknown 21 Altered mental status, weakness Ferritin, haemophagocytosis Unknown No Macrophage activation syndrome 15
33 98 M Pfizer 2 2 Unknown Bicytopaenia, haemophagocytosis Unknown No Macrophage activation syndrome 15
34 82 M Pfizer 2 6 Arthralgias, fever, myalgia, weakness Bicytopaenia, ferritin, fever, haemophagocytosis, hypertriglyceridaemia Unknown No 15
35 60 F Pfizer 1 5 Unknown Haemophagocytosis Unknown No 15
36 76 M Pfizer 2 0 Weakness Fever 10 Yes Macrophage activation syndrome 15
37 80 F Pfizer 1 10 Stroke Unknown Unknown Yes 15
38 22 M Pfizer 2 1 Fever, swollen lymph nodes, weakness Fever, ferritin haemophagocytosis 5 No 15
39 80 M Moderna 1 21 Unknown Ferritin Unknown No Macrophage activation syndrome 15
40 50 F Pfizer 2 35 Fever, headache, swollen lymph nodes Fever, ferritin 50 No Macrophage activation syndrome 15
41 Unknown M Pfizer 1 3 Diarrhoea, fatigue, fever, myalgias Ferritin, fever, hypertriglyceridaemia 14 No Macrophage activation syndrome 15
42 72 F Moderna 1 8 Fever Fever N/A No 15
43 69 F Pfizer 1 9 Fever Fever 10 No 15
44 Unknown M Pfizer 2 Unknown Shortness of breath Unknown Unknown No 15
45 82 F Pfizer 2 1 Fever, malaise Fever Unknown No Relapsed lymphoma 15
46 53 F Pfizer 1 3 Fever, night sweats, polydipsia, shortness of breath, weight loss Fever, ferritin Unknown No 15
47 86 F Pfizer 1 12 Fever Fever, bicytopaenia Unknown No 15
48 54 F Janssen Unknown 8 Unknown Unknown Unknown No Macrophage activation syndrome 15
49 36 M Pfizer 1 28 Unknown Ferritin, haemophagocytosis, hpertriglyceridaemia, sIL2r Unknown No Macrophage activation syndrome 15
50 76 F Pfizer 2 2 Fever Fever, haemophagocytosis Unknown Yes 15

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Footnotes

  • Contributors VW and JCB designed the research. VW, CL, AH and JCB contributed equally to performing the research, analysing the data and writing the paper.

  • Funding The authors have not declared a specific grant for this research from any funding agency in the public, commercial or not-for-profit sectors.

  • Case reports provide a valuable learning resource for the scientific community and can indicate areas of interest for future research. They should not be used in isolation to guide treatment choices or public health policy.

  • Competing interests VW, CL and AH declare no conflicts of interest. JCB has served on advisory boards for Janssen, Pharmacyclics/AbbVie, BeiGene, AstraZeneca, Innate Pharma and receives institutional research support from Oncternal, Velosbio, Pharmacyclics/Abbvie and Acerta/AstraZeneca. She has received honoraria from Janssen.

  • Provenance and peer review Not commissioned; externally peer reviewed.

  • Supplemental material This content has been supplied by the author(s). It has not been vetted by BMJ Publishing Group Limited (BMJ) and may not have been peer-reviewed. Any opinions or recommendations discussed are solely those of the author(s) and are not endorsed by BMJ. BMJ disclaims all liability and responsibility arising from any reliance placed on the content. Where the content includes any translated material, BMJ does not warrant the accuracy and reliability of the translations (including but not limited to local regulations, clinical guidelines, terminology, drug names and drug dosages), and is not responsible for any error and/or omissions arising from translation and adaptation or otherwise.

References

    1. Polack FP ,
    2. Thomas SJ ,
    3. Kitchin N , et al
    . Safety and efficacy of the BNT162b2 mRNA Covid-19 vaccine. N Engl J Med 2020;383:260315.doi:10.1056/NEJMoa2034577 pmid:http://www.ncbi.nlm.nih.gov/pubmed/33301246
    1. Baden LR ,
    2. El Sahly HM ,
    3. Essink B , et al
    . Efficacy and safety of the mRNA-1273 SARS-CoV-2 vaccine. N Engl J Med 2021;384:40316.doi:10.1056/NEJMoa2035389 pmid:http://www.ncbi.nlm.nih.gov/pubmed/33378609
    1. Barda N ,
    2. Dagan N ,
    3. Ben-Shlomo Y , et al
    . Safety of the BNT162b2 mRNA Covid-19 vaccine in a nationwide setting. N Engl J Med 2021;385:107890.doi:10.1056/NEJMoa2110475 pmid:http://www.ncbi.nlm.nih.gov/pubmed/34432976
    1. Lee E-J ,
    2. Cines DB ,
    3. Gernsheimer T , et al
    . Thrombocytopenia following Pfizer and Moderna SARS-CoV-2 vaccination. Am J Hematol 2021;96:5347.doi:10.1002/ajh.26132 pmid:http://www.ncbi.nlm.nih.gov/pubmed/33606296
    1. Gerber GF ,
    2. Yuan X ,
    3. Yu J , et al
    . COVID-19 vaccines induce severe hemolysis in paroxysmal nocturnal hemoglobinuria. Blood 2021;137:36703.doi:10.1182/blood.2021011548 pmid:http://www.ncbi.nlm.nih.gov/pubmed/33945618
    1. Hines AM ,
    2. Murphy N ,
    3. Mullin C , et al
    . Henoch-Schönlein purpura presenting post COVID-19 vaccination. Vaccine 2021;39:45712.doi:10.1016/j.vaccine.2021.06.079 pmid:http://www.ncbi.nlm.nih.gov/pubmed/34247902
    1. Diaz GA ,
    2. Parsons GT ,
    3. Gering SK , et al
    . Myocarditis and pericarditis after vaccination for COVID-19. JAMA 2021;326:1210.doi:10.1001/jama.2021.13443
    1. Rodríguez Y ,
    2. Novelli L ,
    3. Rojas M , et al
    . Autoinflammatory and autoimmune conditions at the crossroad of COVID-19. J Autoimmun 2020;114:102506.doi:10.1016/j.jaut.2020.102506 pmid:http://www.ncbi.nlm.nih.gov/pubmed/32563547
    1. Zacharias H ,
    2. Dubey S ,
    3. Koduri G , et al
    . Rheumatological complications of Covid 19. Autoimmun Rev 2021;20:102883.doi:10.1016/j.autrev.2021.102883 pmid:http://www.ncbi.nlm.nih.gov/pubmed/34237419
    1. Flower L ,
    2. Laundy N ,
    3. Khosravi M , et al
    . Haemophagocytic lymphohistiocytosis secondary to COVID-19: a case series. Lancet Rheumatol 2021;3:e7447.doi:10.1016/S2665-9913(21)00248-4 pmid:http://www.ncbi.nlm.nih.gov/pubmed/34423317
    1. Schnaubelt S ,
    2. Tihanyi D ,
    3. Strassl R , et al
    . Hemophagocytic lymphohistiocytosis in COVID-19: case reports of a stepwise approach. Medicine 2021;100:e25170.doi:10.1097/MD.0000000000025170 pmid:http://www.ncbi.nlm.nih.gov/pubmed/33761694
    1. Soy M ,
    2. Atagündüz P ,
    3. Atagündüz I , et al
    . Hemophagocytic lymphohistiocytosis: a review inspired by the COVID-19 pandemic. Rheumatol Int 2021;41:718.doi:10.1007/s00296-020-04636-y pmid:http://www.ncbi.nlm.nih.gov/pubmed/32588191
    1. Ai S ,
    2. Awford A ,
    3. Roncolato F
    . Hemophagocytic lymphohistiocytosis following ChAdOx1 nCov-19 vaccination. J Med Virol 2022;94:14-16.doi:10.1002/jmv.27279 pmid:http://www.ncbi.nlm.nih.gov/pubmed/34406660
    1. Attwell L ,
    2. Zaw T ,
    3. McCormick J , et al
    . Haemophagocytic lymphohistiocytosis after ChAdOx1 nCoV-19 vaccination. J Clin Pathol 2021. doi:doi:10.1136/jclinpath-2021-207760. [Epub ahead of print: 22 Jul 2021].pmid:http://www.ncbi.nlm.nih.gov/pubmed/34301797
    1. National Vaccine Information Center
    . Vaccine adverse events reporting system (VAERS), 2021. Available: https://www.medalerts.org/vaersdb [Accessed 22 Sep 2021].
    1. Center for Disease Control and Prevention
    . COVID-Data Tracker: COVID-19 vaccinations in the United States, 2021. Available: https://covid.cdc.gov/covid-data-tracker/#vaccinations_vacc-total-admin-rate-total [Accessed 22 Sep 2021].

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