Abstract
Vulnerable subjects, including systemic lupus erythematosus (SLE) patients, have been prioritised to receive anti-SARS-CoV-2 vaccines. Few data about the safety of these vaccines in SLE are available. The aim of our study is to investigate the safety of anti-SARS-CoV-2 vaccines in SLE. We included 452 SLE patients, referring to seven tertiary centres, who were immunised. A total of 119 (26%) reported side effects (SE) after the first and/or the second shot (the most frequent SE were fever, local reaction, fatigue, and arthralgia). Patients with constitutional symptoms and those on an immunosuppressive regimen (especially belimumab) showed more SE. In addition, 19 (4%) had a flare after the immunisation (flares classified by organ involvement: six musculoskeletal with constitutional symptoms, four renal, three cardio-respiratory, three haematological, two mucocutaneous). None of the patients needed hospitalisation and none died. Moreover, 15 required a transient increase in corticosteroids and four were treated with steroid pulses. One patient required an additional rituximab course. Anti-dsDNA, moderate/high DAS before vaccine, and belimumab were found more frequently in patients with disease flare. Anti-SARS-CoV-2 vaccines are safe in SLE patients, and they should be recommended in these patients, as the potential benefits widely outweigh the risk of SE. Treatment adjustment might be considered with the aim of minimising SE risk and flare.
Keywords: systemic lupus erythematous, SARS-CoV-2 infection, SARS-CoV-2 vaccine, flare, side effect, immunisation
1. Introduction
Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) infection can cause serious respiratory complications including interstitial pneumonia and acute respiratory distress syndrome, frequently requiring intensive care and associated with elevated mortality rates [1].
Since the onset of the COVID-19 pandemic, great effort has been made to develop a vaccine against the SARS-CoV-2 virus, particularly for patients with a higher susceptibility to life-threatening severe complications.
Patients with inflammatory rheumatic diseases (RDs) are at greater risk of infections compared to the general population. Among RDs, patients with systemic lupus erythematosus (SLE) represent a unique population, prone to infections due to concomitant disease-related immune dysfunction, immunosuppressive therapy, and comorbidities [2]. In this clinical scenario, the use of vaccines represents one of the most effective strategies to limit infection-related morbidity and mortality. However, many questions have been raised about the effects of vaccines on the immune system and their potential role as a trigger for SLE onset or flare. Although a small study on 10 patients reported a temporal relationship between hepatitis B vaccine and the occurrence of SLE and another study showed a transient increase in anti-dsDNA antibody titres without disease flares after seasonal flu vaccination, to the best of our knowledge, none of the available vaccines have been recognised to be able to induce SLE [3,4,5]. Consequently, EULAR has recently highlighted the importance of immunisation against the most common vaccine-preventable diseases, advocating for an annual assessment of vaccine status in SLE patients [6].
Among the anti-SARS-CoV2 vaccines available on the market in Italy, Pfizer–BioNTech mRNA COVID-19 BNT162b2 and Moderna COVID-19 mRNA-1273 have been licensed and used both in Europe and North America, while AstraZeneca ChAdOx1-S was authorised in Europe only. Few data about the safety and efficacy of these vaccines are available in SLE patients, as these patients are generally excluded from all the phases of vaccine development [7].
A survey-based study reported that anti-SARS-CoV-2 vaccines were well tolerated in a large cohort of SLE patients, with a minimal rate of disease flare, in comparison to the annual rate of flare observed in the same population in the previous year [8]. Conversely, in a recent study on 100 SLE patients, there were 27 flares after the immunisation (9% and 20% after the first and the second dose, respectively). Seven patients presented flare after both doses [9].
In a recent review, the benefits of the anti-SARS-CoV-2 vaccine far outweighed the potential risks of side effects or disease flares [10].
The aim of our study is to investigate the safety of different anti-SARS-CoV-2 vaccines in SLE patients in a multicentre cohort of tertiary hospitals of Northern Italy.
2. Material and Methods
2.1. Study Design
The study was designed as a retrospective, observational, multicentre cohort study.
2.2. Setting
Data regarding SLE patients who had been administered the anti-SARS-CoV-2 vaccine between December 2020 and October 2021 were retrospectively collected. The patients included in the study referred to seven SLE tertiary centres: Lupus Clinic, Clinical Rheumatology Division of ASST Pini-CTO, Milan; CMID-Nephrology Unit of Ospedale Giovanni Bosco, Turin; IRCCS Humanitas Research Hospital; Renal and Rheumatology Units, San Gerardo Hospital, Monza; ASST Spedali Civili; Lupus Clinic at Unit of Immunology, Rheumatology, Allergy and Rare Diseases, IRCCS Ospedale San Raffaele, Milan; Referral Center for Systemic Autoimmune Diseases, Fondazione IRCCS Ca’ Granda Ospedale Maggiore Policlinico, Milan. The analysis is part of a study to collect observational data from SLE patients and it was approved by the Ethics Committee Comitato Etico Milano Area 2 (approval no. 0002450/2020). The study was conducted conforming to the Declaration of Helsinki.
2.3. Participants
All consecutive adult patients (≥18 years of age) referring to participant centres with a previous diagnosis of SLE who had received anti-SARS-CoV-2 vaccines between 29 December 2020 and 31 October 2021 (BNT162b2 mRNA COVID-19 vaccine by Pfizer or mRNA-1273 by Moderna Biotech or ChAdOx1-S by AstraZeneca) were included in the study. All patients provided written informed consent. The diagnosis of SLE was made in accordance with the 1997 ACR classification criteria or the 2019 EULAR–ACR criteria [11,12].
2.4. Variables
Data regarding demographics and clinical and serological features of SLE (including organ involvement, disease duration, autoimmune profile, ongoing treatment, disease activity before and after anti-SARS-CoV-2 vaccine, possible treatment modifications related to vaccination and comorbidities) were collected and gathered in a database for statistical analysis. A history of confirmed SARS-CoV-2 infection before and/or after immunisation was recorded. Moreover, when available, laboratory parameters (CRP, ESR, gamma globulins) were collected at the last follow-up visit before and at the first follow-up visit after the vaccine. Disease activity was assessed according to the British Isles Lupus Assessment Group (BILAG) 2004 index [13]. Disease flare was defined as an increase of at least 4 points in SLEDAI-2K score, or a new “A” or “B” score at BILAG in at least one domain. Disease manifestations were classified as “flare” when they were persistent, in contrast to “side effects” when manifestations were transient and self-limited.
2.5. Statistical Analysis
Descriptive statistics were used to summarise patients’ demographic and clinical data by using median, interquartile range (IQR), absolute numbers, and percentages. All these variables were then investigated as risk factors of the following outcomes: side effects and SLE flare(s) after SARS-CoV-2 vaccination. The comparisons of continuous variables between groups of patients were assessed through the Mann–Whitney nonparametric test. The association between categorical variables was assessed by performing Fisher’s exact test. A p-value < 0.05 was considered significant. All analyses were performed using R software version 3.5.2 (R Foundation for Statistical Computing, Vienna, Austria) with package Rcmdr (version 2.5-1).
3. Results
Four hundred fifty-two patients, who had received the anti-SARS-CoV-2 vaccine, were included in the study. Demographic, comorbidity, and SLE disease characteristics and therapies before SARS-CoV-2 vaccination are reported in Table 1. At the last visit, 12 (3%) were not receiving therapy, 322 (71%) were on prednisone at a low–medium dose, 374 (83%) were taking hydroxychloroquine, and 228 (50%) were being treated with an immunosuppressive drug (Table 1). Only nine patients had transiently discontinued immunosuppressants before vaccination. At the time of first vaccine injection, almost 90% of patients were in remission or low disease activity according to the Low Disease Activity State (LLDAS) [14].
Table 1.
Demographics | |
---|---|
Age, years, median (IQR) | 48 (35–56) |
Disease duration, months, median (IQR) | 128 (73,75–197,25) |
Female, n (%) | 417 (92.25) |
Laboratory, median (25th–75th) | |
ESR, mm/h + | 13 (7–21) |
CRP, mg/dL | 0.5 (0.29–0.51) |
IgG, mg/dL £ | 1138 (882.5–1405) |
Serology and organ involvement ever, n (%) | |
Anti-dsDNA positivity § | 382 (85) |
Anti-Sm positivity $ | 48 (11) |
Low complement (C3 and/or C4) | 159 (35) |
Musculoskeletal involvement | 382 (85) |
Mucocutaneus involvement | 294 (65) |
Renal involvement | 224 (50) |
Urinary abnormalities | 84 (19) |
NPSLE involvement | 46 (10) |
Cardiopulmonary involvement | 93 (21) |
Haematological involvement | 149 (33) |
Constitutional symptoms | 158 (35) |
Gastrointestinal involvement | 16 (4) |
Ophthalmic involvement | 12 (3) |
Anti-phospholipid antibodies positivity | 142 (31) |
Secondary anti-phospholipid syndrome | 48 (11) |
Therapy, n (%) | |
No therapy | 12 (3) |
Hydroxychloroquine | 374 (83) |
Prednisone | 322 (71) |
Immunosuppressor * | 228 (50) |
Cyclophosphamide ever | 112 (25) |
Rituximab ever | 59 (13) |
Disease activity before SARS-CoV-2 vaccination, n (%) | |
Remission/LLDAS | 402 (89) |
Moderate/High DAS | 50 (11) |
SARS-CoV-2 infection, n (%) | |
Infection before vaccination | 13 (3) |
Infection after vaccination | 77 (17) |
+ not available for 3 patients. £ not available for 286 patients. § not available for 17 patients. $ not available for 1 patient. * Azathioprine, mycophenolate, belimumab, cyclophosphamide, leflunomide, adalimumab, rituximab, tocilizumab, tacrolimus. IQR: interquartile range. ESR: erythrocyte sedimentation rate. CRP: C-reactive protein. NPSLE: neuropsychiatric involvement in systemic lupus erythematosus. LLDAS: lupus low disease activity score, DAS: disease activity score.
Most patients (411, 90.93%) received the BNT162b2 mRNA COVID-19 vaccine by Pfizer, 34 (7.52%) received mRNA-1273 by Moderna Biotech, and the remaining patients (7) received ChAdOx1-S by AstraZeneca. Thirteen patients had a confirmed SARS-CoV-2 infection before immunisation. Infections occurred with a median time of 6.5 months before immunisation (interquartile range: 4.5–10.75).
As reported in Table 2, 119 (26.33%) patients reported adverse symptoms after the first or second shot. Fifty-six (12.38%) showed side effects after the first and 96 (20.80%) after the second shot. Among side effects, the most frequent were fever, pain, swelling and redness at the site of injection, fatigue, and arthralgia.
Table 2.
After first shot, n (%): 56 (12.38) | |
---|---|
Headache | 7 |
Arthralgia | 12 |
Myalgia | 7 |
Fever | 19 |
Local reaction | 17 |
Gastrointestinal symptoms | 6 |
Lymphadenopathy | 2 |
Fatigue | 12 |
Rash | 3 |
Other | 2 |
After second shot, n (%): 94 (20.80) | |
Headache | 6 |
Arthralgia | 28 |
Arthritis | 1 |
Myalgia | 9 |
Fever | 36 |
Local reaction | 17 |
Gastrointestinal symptoms | 11 |
Lymphadenopathy | 3 |
Fatigue | 20 |
Rash | 3 |
After first or second shot, n (%): 119 (26.33) |
According to data reported in Table 3, patients with constitutional symptoms and those treated with at least one immunosuppressant (especially those on belimumab) showed an increased rate of side effects. Conversely, patients with no therapy before the vaccine had a reduced risk of adverse events. There was no association between the history of infection before vaccination and the risk of adverse reactions. Seventy-seven (17%) of patients experienced SARS-CoV-2 infection after vaccination, with a median time to infection of 7 months (IQR 6–8 months).
Table 3.
Side Effects after First or Second Shot (n = 119) |
No Side Effects after First or Second Shot (n = 333) |
p-Value (<0.05) | |
---|---|---|---|
Age, years, median (IQR) | 46 (33.5–54) | 48 (35.75–57) | 0.1817 |
Disease duration, months, median (IQR) | 138 (76–262.5) | 126 (73–193) | 0.3016 |
Musculoskeletal involvement, % (n) | 84.9 (101) | 84.4 (281) | 1.00 |
Mucocutaneus involvement, % (n) | 71.4 (85) | 62.8 (205) | 0.09403 |
Renal involvement, % (n) | 42.0 (50) | 52.3 (174) | 0.06917 |
NPSLE, % (n) | 13.4 (16) | 9 (30) | 0.2151 |
Cardiopulmonary involvement, % (n) | 22.7 (27) | 19.8 (66) | 0.5109 |
Haematological involvement, % (n) | 32.8 (39) | 33 (110) | 1.00 |
Constitutional symptoms, % (n) | 48.7 (58) | 30 (100) | 0.000325 * |
Gastrointestinal involvement, % (n) | 4.2 (5) | 3.3 (11) | 0.7726 |
Ophthalmic involvement, % (n) | 0.8 (1) | 3.3 (11) | 0.1973 |
Secondary anti-phospholipid syndrome, % (n) | 10.9 (13) | 10.5 (35) | 0.8641 |
Anti-phospholipid antibodies positivity, % (n) | 26.2 (31) | 33.6 (112) | 0.1366 |
Anti-dsDNA positivity, % (n) | 30.7 (35) | 27.4 (88) | 0.5453 |
Anti-Sm positivity, % (n) | 12.6 (15) | 9.9 (33) | 0.4881 |
Low complement (C3 and/or C4), % (n) | 37.8 (45) | 34.2 (114) | 0.5033 |
ESR, mm/h, median (IQR) | 14 (7.25–19.75) | 13 (7–22) | 0.7303 |
CRP, mg/dL, median (IQR) | 0.5 (0.1–0.5) | 0.5 (0.3–0.6) | 0.3122 |
Presence of urinary abnormalities, % (n) | 9.2 (11) | 21.9 (73) | 0.002311 |
Moderate or high DAS before vaccine, % (n) | 16 (19) | 9.3 (31) | 0.06011 |
No therapy before vaccine, % (n) | 0 (0) | 3.6 (12) | 0.0419 * |
At least 1 immunosuppressant #, % (n) | 63 (75) | 46.8 (156) | 0.002751 * |
Mycophenolate, % (n) | 31.9 (38) | 23.1 (77) | 0.06606 |
Methotrexate, % (n) | 5.9 (7) | 6.6 (22) | 1.00 |
Belimumab, % (n) | 21.8 (26) | 13.5 (45) | 0.03956 * |
Rituximab ever, % (n) | 11.8 (14) | 13.5 (45) | 0.7515 |
Prednisone therapy, % (n) | 74.8 (89) | 70 (233) | 0.3468 |
* p-Value < 0.05. # Azatioprine, mycophenolate, belimumab, cyclophosphamide, leflunomide, adalimumab, rituximab, tocilizumab, tacrolimus. IQR: interquartile range. ESR: erythrocyte sedimentation rate. CRP: C-reactive protein. NPSLE: neuropsychiatric involvement in systemic lupus erythematosus. DAS: disease activity score.
There was no significant difference in the percentage of active BILAG domains before and after vaccination (Table 4). Nineteen (4%) patients flared up after immunisation, with a median time to relapse of 7 ± 2 days. The incidence rate of flare after immunisation was not superior to that observed in the same cohort during the period between 2015 and 2019.
Table 4.
BILAG before SARS-CoV-2 Vaccination, n (%) | |||||
---|---|---|---|---|---|
A | B | C | D | E | |
Musculoskeletal | 1 (0) | 13 (3) | 22 (5) | 355 (79) | 61 (13) |
Mucocutaneus | 0 (0) | 6 (1) | 11 (2) | 270 (60) | 165 (37) |
Renal | 7 (2) | 41 (9) | 15 (3) | 157 (35) | 232 (51) |
NPSLE | 1 (0) | 3 (1) | 3 (1) | 42 (9) | 403 (89) |
Cardiopulmonary | 1 (0) | 1 (0) | 2 (0) | 71 (16) | 377 (83) |
Haematological | 0 (0) | 2 (0) | 27 (6) | 125 (28) | 298 (66) |
Constitutional | 0 (0) | 2 (0) | 5 (1) | 150 (33) | 295 (65) |
Gastrointestinal | 0 (0) | 1 (0) | 0 (0) | 18 (4) | 433 (96) |
Ophthalmic | 0 (0) | 0 (0) | 0 (0) | 14 (3) | 438 (97) |
BILAG after SARS-CoV-2 Vaccination, n (%) | |||||
A | B | C | D | E | |
Musculoskeletal | 3 (1) | 11 (2) | 17 (4) | 340 (75) | 81 (18) |
Mucocutaneus | 0 (0) | 5 (1) | 11 (2) | 256 (57) | 180 (40) |
Renal | 10 (2) | 35 (8) | 14 (3) | 141 (31) | 252 (56) |
NPSLE | 0 (0) | 3 (1) | 3 (1) | 38 (8) | 408 (90) |
Cardiopulmonary | 0 (0) | 3 (1) | 2 (0) | 63 (14) | 384 (85) |
Haematological * | 1 (0) | 2 (0) | 26 (6) | 112 (25) | 308 (68) |
Constitutional | 3 (1) | 5 (1) | 6 (1) | 143 (32) | 295 (65) |
Gastrointestinal | 0 (0) | 2 (0) | 0 (0) | 16 (4) | 434 (96) |
Ophthalmic | 0 (0) | 0 (0) | 0 (0) | 11 (2) | 441 (98) |
* Not available for 3 patients. NPSLE: neuropsychiatric involvement in systemic lupus erythematosus.
The differential distribution of baseline characteristics among patients with vs. without flares after SARS-CoV-2 vaccination is reported in Table 5.
Table 5.
Disease Flare after Vaccine (n = 19) |
No Disease Flare after Vaccine (n = 430) |
p-Value (<0.05) | |
---|---|---|---|
Age, years, median (IQR) | 52 (39.5–56.0) | 48 (35.0–56.9) | 0.8487 |
Disease duration, months, median (IQR) | 144 (122–242.5) | 127 (73–195) | 0.2489 |
Musculoskeletal involvement, % (n) | 78.9 (15) | 84.8 (367) | 0.5142 |
Mucocutaneus involvement, % (n) | 57.9 (11) | 64.5 (283) | 0.6237 |
Renal involvement, % (n) | 52.6 (10) | 49.4 (214) | 0.8187 |
NPSLE, % (n) | 5.3 (1) | 10.4 (45) | 0.708 |
Cardiopulmonary involvement, % (n) | 26.3 (5) | 20.3 (88) | 0.5617 |
Haematological involvement, % (n) | 42.1 (8) | 32.6 (141) | 0.4554 |
Constitutional symptoms, % (n) | 26.3 (5) | 35.3 (153) | 0.473 |
Gastrointestinal involvement, % (n) | 5.3 (1) | 3.5 (15) | 0.5029 |
Ophthalmic involvement, % (n) | 0 (0) | 2.8 (12) | 1.00 |
Secondary anti-phospholipid syndrome, % (n) | 5.3 (1) | 10.9 (47) | 0.7079 |
Anti-phospholipid antibodies positivity, % (n) | 26.3 (5) | 31.9 (138) | 0.802 |
Anti-dsDNA positivity, % (n) | 55.6 (10) | 27.1 (113) | 0.01419 * |
Anti-Sm positivity, % (n) | 15.8 (3) | 10.4 (45) | 0.4414 |
Low complement (C3 and/or C4), % (n) | 52.6 (10) | 34.2 (149) | 0.1391 |
ESR, mm/h, median (IQR) | 19 (10–24.5) | 13 (7–21) | 0.1247 |
CRP, mg/dL, median (IQR) | 0.42 (0.135–0.50) | 0.50 (0.30–0.53) | 0.4638 |
Presence of urinary abnormalities, % (n) | 21.1 (4) | 18.5 (80) | 0.7643 |
Moderate or high DAS before vaccine, % (n) | 26.3 (5) | 10.4 (45) | 0.04739 * |
No therapy before vaccine, % (n) | 0 (0) | 2.8 (12) | 1.00 |
At least 1 immunosuppressant #, % (n) | 73.7 (14) | 50.1 (217) | 0.0593 |
Mycophenolate, % (n) | 42.1 (8) | 24.7 (107) | 0.106 |
Methotrexate, % (n) | 5.3 (1) | 6.5 (28) | 1.00 |
Belimumab, % (n) | 36.8 (7) | 14.8 (64) | 0.01838 * |
Rituximab ever, % (n) | 5.3 (1) | 13.4 (58) | 0.4904 |
Prednisone therapy, % (n) | 78.9 (15) | 70.9 (307) | 0.6069 |
Side effects after vaccination, % (n) | 63.2 (12) | 24.7 (107) | 0.00062 * |
* p-Value < 0.05. # Azatiopryne, mycophenolate, belimumab, cyclophosphamide, leflunomide, adalimumab, rituximab, tocilizumab, IMP, tacrolimus. IQR: interquartile range. ESR: erythrocyte sedimentation rate. CRP: C-reactive protein. NPSLE: neuropsychiatric involvement in systemic lupus erythematosus. DAS: disease activity score.
Anti-dsDNA positivity, moderate or high DAS before vaccine, and the use of belimumab were significantly more frequent in patients who experienced a flare. Moreover, patients who experienced a flare after SARS-CoV-2 vaccination displayed a significantly higher rate of adverse events after vaccination: 63% of those who had a flare also had an adverse reaction to the vaccination, while only 25% of those who did not have a flare had an adverse reaction.
Among these 19 patients, 84.2% were on hydroxychloroquine, 78.9% were taking low-dose prednisone, 77.3% were being treated with immunosuppressants (mycophenolate 42.1%, belimumab 36.8%, methotrexate 5.1%, azathioprine 5.1%, and cyclophosphamide 5.1%). None of these patients discontinued therapy before the vaccination.
None of the patients experiencing a flare had a history of SARS-CoV-2 infection before vaccination.
Qualitatively, six (31.6%) patients experienced a musculoskeletal flare associated with constitutional symptoms (one patient experienced constitutional symptoms only and one patient musculoskeletal symptoms only), four (21%) patients had a renal flare, three (16%) had cardio-respiratory manifestations, three (16%) haematological, and two (10%) a mucocutaneous flare.
In 79% (15) of the cases, the flare was treated with a transient increase in oral steroid dosage, while in four cases, intravenous steroid pulses were required. Moreover, in one case, a rituximab course was repeated in a patient who had received the first course nine months before. None of the patients needed to be hospitalised and no case of death was recorded.
Moreover, anti-dsDNA antibodies became positive in 36 patients, although this finding was not associated with a higher disease flare rate.
4. Discussion
Our study explored the safety of anti-SARS-CoV-2 vaccination in a large multicentric cohort of SLE patients from Northern Italy. Our data showed that anti-SARS-CoV-2 vaccines are overall safe in SLE patients as we recorded a very low rate of side effects and none of the side effects were severe or required hospitalisation. The number of patients experiencing moderate to severe local or systemic adverse reactions in our study is lower than previous studies, both including RD patients and the healthy population [15].
In our cohort, the most frequent post-injection systemic manifestations were fever, arthralgia and fatigue, both after the first and the second boost. Compared to other studies, all these symptoms were less frequent than previously described (in few studies evaluating SLE patients separately, fatigue and headache were reported by 30–70% of patients) [9,10,16,17,18]. Interestingly, fever was much less frequent (15–20%), but still considerably more than what we observed (4–8% after the first and second boost). Diverging methodological approaches might account for this finding. In previously available studies, local and systemic reactions were self-reported surveys or questionnaires. The data included in our study were collected during outpatient visits with an accurate oral face-to-face interview performed by a trained physician. Moreover, because our data were collected over a longer period of time than the other studies, patients who received immunisation more recently could have been more reassured by clinicians, who were supported by the encouraging literature and who tended to pay less attention to non-specific symptoms (disease flare vs. side effects after the vaccine).
The presence of constitutional symptoms, the absence of therapy, and the use of at least one immunosuppressant, particularly belimumab, before vaccination were factors found to be significantly associated with a higher risk of having side effects after immunisation. To our knowledge, this is the first study evaluating this aspect in SLE patients. We can speculate that patients with constitutional symptoms are more likely to experience a worsening after vaccination. The association with the use of immunosuppressants can suggest that a more severe disease, requiring a disease-modifying drug (DMARDs), could facilitate the occurrence of side effects. The identification of belimumab, as the most implicated therapy, is in line with this hypothesis as more than 50% of patients were receiving this therapy in addition to conventional treatments, probably identifying a subgroup of patients with a more aggressive disease (in Italy, due to eligibility criteria, belimumab can be prescribed only in patients with an active disease despite the conventional immunosuppressive therapy). The lack of any association with the serological profile is reassuring: our data confirmed that positive anti-phospholipid antibodies do not represent a major concern for the risk of thrombosis in patients undergoing anti-SARS-CoV-2 vaccination [19].
Another important safety issue regards the effects of vaccination on disease activity. The potential of vaccines and adjuvants to trigger SLE reactivation has been a matter of concern for many years. Less is known about the impact of novel vaccine technologies, such as liposomal RNA, in triggering inflammation. However, recent studies on different types of live-attenuated or inactivated vaccines, including papilloma virus and influenza vaccines, did not report an increased risk of flare and vaccinations are currently recommended, also by EULAR, in these patients [20]. In our study, the incidence of a new disease flare after the first and/or the second dose was very low (not superior when compared to the period 2015–2019): reported manifestations were mainly involving the musculoskeletal, renal, and cutaneous domains. Mean BILAG scores did not change over time and disease flares were usually mild or moderate and none of them required hospitalisation. These observations are in line with previous studies, both considering patients with SLE and other RDs. Most studies reported a rate of flare ranging from 3% to 12%, with a preponderance of musculoskeletal and constitutional involvement [21,22,23,24]. Interestingly, patients, who experienced an adverse reaction, also had a higher disease flare rate. However, caution is warranted in interpreting these data, as some of the most frequent adverse events can mimic SLE clinical manifestations. In this regard, fever, arthralgias, or mild arthritis could have been misinterpreted and attributed to both an adverse reaction to immunisation and to SLE. We can also assume that some side effects of vaccination can trigger disease flares. In line with this assumption, we observed a case of renal flare after metabolic acidosis induced by diarrhoea. Conversely, our data also suggest that the prompt treatment of adverse events might potentially prevent further complications in the disease course.
Risk factors for SLE reactivation were positive anti-dsDNA, moderate/high disease activity before vaccination, and the use of belimumab. This is not surprising, as SLE patients with high disease activity and severity have been identified as risk factors for flares in different disease settings [25,26] and constitute the reference target for belimumab treatment. Moreover, this finding is in line with a previous study that identified a history of at least one flare during the past year, an indirect indicator of unstable disease, as the most relevant risk factor for further flares [8].
The lack of immunogenicity and efficacy data constitutes a major limitation of our study. We also did not obtain experimental data, which could have offered potential hints to understand immune dynamics in patients with SLE challenged with either anti-SARS-CoV-2 vaccines or wild-type infection. In particular, data about interferon alpha responses, which appear dysregulated both in SARS-CoV-2 infection and SLE, are warranted for a comprehensive understanding of the immunological profile of patients with connective tissue disorders facing SARS-CoV-2 infection. Moreover, almost all the included patients were Caucasian and, therefore, our data should be replicated in other populations. Conversely, the strength of our study lies in the large number of clinically and serologically well-characterised SLE patients, regularly followed in seven tertiary referral centres.
5. Conclusions
Our data are reassuring and confirms that anti-SARS-CoV-2 vaccination is overall safe in SLE patients. Immunisation against SARS-CoV-2, according to the EULAR and ACR recommendations, should be recommended in this clinical setting since the potential benefits widely outweigh the risk of adverse events. Therapy adjustment could be required to minimise the risk of side effects and disease flare, consequently ensuring satisfying protection against SARS-CoV-2 infection. Our work suggests to carefully follow up with SLE patients in the weeks following active immunisation to promptly identify disease flares and to start adequate treatment.
Acknowledgments
The authors acknowledge Maria Rosa Pozzi (ASST Monza, Monza, Italy), Ilaria Suardi and Giulia Carrea (University of Milan and ASST Pini-CTO, Milan, Italy), Gabriele Gallina and Nicola Farina (IRCCS Ospedale San Raffaele, Milan, Italy), and Stefania Affatato (University of Brescia, Brescia, Italy) for their contributions to the study.
Author Contributions
Conceptualization, M.G., S.S., G.A.R., G.M., R.A.S. and L.B.; Methodology, T.S. and L.M.A.; Software, T.S. and L.M.A.; Validation and data integrity, M.G., T.S. and L.M.A.; Formal Analysis, T.S.; Writing—Original Draft Preparation, M.G., T.S. and L.M.A.; Writing—Review & Editing, S.S., G.A.R., G.B., F.A., F.M., L.M., F.T., P.M., C.B.; Supervision, G.M., R.A.S., D.R., L.D., L.B., E.B. and R.C. Acquisition, analysis, or interpretation of data: G.B., F.A., F.M., L.M., F.T., P.M., C.B., D.R. Final approval of the version to be published: M.G., T.S., L.M.A., S.S., G.A.R., G.M., R.A.S., G.B., F.A., F.M., L.M., F.T., P.M., C.B., L.B., D.R., L.D., E.B., R.C.; All authors agree to be accountable for all aspects of the work in ensuring that questions related to the accuracy or integrity of any part of the work are appropriately investigated and resolved. All authors have read and agreed to the published version of the manuscript.
Funding
No specific funding was received from any bodies in the public, commercial, or not-for-profit sectors to carry out the work described in this article.
Institutional Review Board Statement
The study was conducted according to the guidelines of the Declaration of Helsinki and approved by the Ethics Committee of Comitato Etico Milano Area 2 (approval no. 0002450/2020).
Informed Consent Statement
Informed consent was obtained from all subjects involved in the study.
Data Availability Statement
The data presented in this study are available on request from the corresponding author. The data are not publicly available due to privacy reasons.
Conflicts of Interest
The authors declare no conflict of interest.
Footnotes
Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations.
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Associated Data
This section collects any data citations, data availability statements, or supplementary materials included in this article.
Data Availability Statement
The data presented in this study are available on request from the corresponding author. The data are not publicly available due to privacy reasons.