Immunogenicity, Effectiveness, and Safety of COVID-19 Vaccines in Rheumatic Patients: An Updated Systematic Review and Meta-Analysis
Abstract
:1. Introduction
2. Materials and Methods
2.1. Literature Search
2.2. Study Selection
2.3. Data Extraction
2.4. Statistical Analysis
3. Results
3.1. Study Characteristics
3.2. Immunogenicity of COVID-19 Vaccines in Rheumatic Patients
3.3. Influencing Factors of Immunogenicity after COVID-19 Vaccination in Rheumatic Patients
3.4. Effectiveness of COVID-19 Vaccines in Rheumatic Patients
3.5. Adverse Events of COVID-19 Vaccines in Rheumatic Patients
3.6. The Influence of COVID-19 Vaccines on Disease Activity of Rheumatic Diseases
3.7. Publication Bias
4. Discussion
5. Conclusions
Supplementary Materials
Author Contributions
Funding
Informed Consent Statement
Data Availability Statement
Acknowledgments
Conflicts of Interest
References
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Author | Country | Sample Size of Rheumatic Patients (n) | Proportion of Female | Mean/Median Age (Years) | Vaccine | Rheumatic Diseases | Humoral Immunogenecity Measurement | Cellular Immunogenecity Measurement | Documentation of Adverse Events |
---|---|---|---|---|---|---|---|---|---|
Ammitzbøll et al. [25] | Denmark | 134 | 72% | 66 | BNT | RA 54%, and SLE 46% | Anti-SARS-CoV-2 antibody CLIA (Ortho Clinical Diagnostics) | N.A. | N.A. |
Barbhaiya et al. [26] | USA | 1101 | 81% | 61 | BNT 54%, Moderna 44%, J&J 2%, and AZ 0.3% | N.A. | N.A. | N.A. | Online survey |
Bartels et al. [27] | Denmark | 282 | 79% | 59 | BNT | RA 55%, and SLE 45% | N.A. | N.A. | Questionnaire |
Benucci et al. [28] | Italy | 14 | N.A. | 57 | BNT | RA | Anti-RBD IgG antibodies FEIA (ThermoFisher) | IGRA (Euroimmun) | N.A. |
Bixio et al. [29] | Italy | 77 | 81% | 62 | BNT | RA | N.A. | N.A. | Clinical record |
Boekel et al. [30] | Netherlands | 505 | 65% | 64 | AZ 46%, BNT 41%, and Moderna 13% | RA 40%, PsA 10%, and MS 16% | N.A. | N.A. | Online questionnaire |
Boekel et al. [31] | Netherlands | 632 | 67% | 63 | AZ 54%, BNT 38%, and Moderna 8% | RA 41%, PsA 11%, AS 11%, and MS 9% | Anti-RBD IgG antibody ELISA (in-house) | N.A. | N.A. |
Boyarsky et al. [32] | USA | 123 | 95% | 50 | BNT 52%, and Moderna 48% | Inflammatory arthritis 28%, overlap syndrome 29%, SLE 20%, and PSS 13% | Anti-RBD antibody ECLIA (Roche) | N.A. | N.A. |
Braun-Moscovici et al. [33] | Isreal | 264 | 76% | 58 | BNT | RA 37%, PsA 12%, and SpA 8% | Anti-RBD IgG CLIA (Abbott) | N.A. | Clinical record |
Bugatti et al. [34] | Italy | 140 | 68% | 56 | BNT | RA 59%, PsA 21%, and SpA 20% | Anti-S1/S2 protein antibodys IgG CLIA (DiaSorin) | N.A. | N.A. |
Cherian et al. [35] | India | 513 | 83% | 58 | AZ 87%, and Covaxin 10% | RA 44%, inflammatory arthritis 16%, SpA 13%, and SLE 10%, | N.A. | N.A. | Clinical record |
Chiang et al. [36] | USA | 1039 | 94% | 46 | mRNA vaccines 96%, and J&J 4% | Inflammatory arthritis 44%, overlap syndrome 21%, SLE 21%, and PSS 5% | Anti-RBD antibody ECLIA (Roche) | N.A. | N.A. |
Connolly et al. [37] | USA | 1377 | 92% | 47 | BNT 55%, and Moderna 45% | Inflammatory arthriitis 47%, SLE 20%, and overlap syndrome 20% | N.A. | N.A. | Online questionnaire |
Cuomo et al. [38] | Italy | 27 | 78% | 49 | BNT | Inflammaory arthritis 48%, RA 22%, and SSc 19% | N.A. | N.A. | Telephone interview |
Deepak et al. [39] | USA | 133 | 74% | 46 | mRNA vaccines | IBD 32%, RA 29%, SpA 15%, and SLE 11% | Anti-S protein IgG ELISA (in-house) | N.A. | N.A. |
Delvino et al. [40] | Italy | 81 | 68% | 76 | BNT | GCA | N.A. | N.A. | Written questionnaire |
Dimopoulou et al. [24] | Greece | 21 | 76% | 17 | BNT | JIA | N.A. | N.A. | N.A. |
Embi et al. [41] | USA | 5024 | N.A. | N.A. | Moderna 40%, and BNT 60% | Rheumatic or inflammatory disorders | N.A. | N.A. | N.A. |
Esquivel-Valerio et al. [42] | Mexico | 225 | 95% | 51 | BNT 48%, Convidecia 13%, Moderna 13%, AZ 12%, CoronaVac 10%, and J&J 2% | RA 59%, SLE 11%, and axial SpA 10% | N.A. | N.A. | Survey |
Ferri et al. [43] | Italy | 478 | 84% | 59 | BNT 94%, and Moderna 6% | SSc 55%, RA 21%, CV 13%, and SLE 8%, | Anti- S1/S2 protein antibodys IgG CLIA (Abbott) | N.A. | Telephone interview |
Firinu et al. [44] | Italy | 95 | 73% | 56 | BNT | SLE 24%, RA 24%, PsA, PsO and AS 25% | Anti-RBD IgG CLIA (Snibe Diagnostics) | N.A. | N.A. |
Fragoulis et al. [45] | Greece | 441 | 76% | 56 | BNT 86%, AZ 10%, Moderna 3%, and J&J 1% | Inflammatory arthritis 59%, CTD 27%, and vasculitis 11% | N.A. | N.A. | Telephone interview |
Furer et al. [13] | Isreal | 686 | 69% | 59 | BNT | RA 38%, PsA 24%, SLE 15%, vasculitis 10%, and SpA 10% | Anti-S1/S2 protein antibodys IgG CLIA (DiaSorin) | N.A. | Telephone questionnaire |
Geisen et al. [22] | Germany | 26 | 64% | 51 | 81% BNT, and Moderna 19% | RA 31%, PsO 12%, SpA 12%, and IBD 12% | Anti-SARS-CoV-2 ELISA (Euroimmun) | N.A. | Online survey |
Haberman et al. [46] | USA | 51 | 71% | 56 | BNT | RA 43%, and PsO/PsA 47% | Anti-S1 protein antibody ELISA (in-house) | N.A. | N.A. |
Germany | 31 | 71% | 51 | BNT | GCA and PMR | Anti-S1 protein antibody ELISA (Euroimmun) | N.A. | N.A. | |
Izmirly et al. [47] | USA | 90 | 88% | 46 | BNT 68%, Moderna 15%, and J&J 5.5% | SLE | Anti-RBD IgG ELISA (in-house) | IFN-γ ELISpot assay (in-house) | N.A. |
Kant et al. [48] | USA | 48 | 35% | 67 | Moderna 52%, BNT 40%, and J&J 8% | AAV | N.A. | N.A. | N.A. |
Li et al. [49] | Hong Kong | 1324 | 75% | 58 | CoronaVac 51%, and BNT 49%, | RA | N.A. | N.A. | Clinical record |
Machado et al. [50] | EULAR COVID-19 Vaccination Registry | 1519 | 68% | 63 | BNT 78%, AZ 16%, and Moderna 5% | Inflammatory arthritis 51%, CTD 19%, and vasculitis 16% | N.A. | N.A. | Clinical record |
Medeiros-Ribeiro et al. [12] | Brazil | 910 | 77% | 51 | CoronaVac | Inflammatory arthritis 50% | Anti-S1/S2 protein antibodys IgG CLIA (DiaSorin) | N.A. | Diary |
Moyon et al. [51] | France | 126 | 91% | 47 | BNT | SLE | SARS-CoV-2 multi-antigenphotonic ring immunoassay(Genalyte) | IGRA (Qiagen) | Clinical record |
Mrak et al. [52] | Austria | 45 | 78% | 64 | BNT 82%, and Moderna 18% | RA 53%, CTD 27%, and vasculitis 16% | N.A. | IFN-γ ELISpot assay (in-house) | N.A. |
Papagoras et al. [53] | Greece | 48 | 69% | 51 | BNT 79%, and AZ 21% | Inflammatory arthritis 58%, CTD and vasculitis 40% | N.A. | N.A. | N.A. |
Picchianti-Diamanti et al. [54] | Italy | 35 | 77% | 59 | BNT | RA | Anti-RBD IgG CLIA (Abbott) | IFN-γ whole-blood assay (in-house) | N.A. |
Prendecki et al. [19] | UK | 119 | 48% | 53 | mRNA vaccines 71%, and AZ 29%, | AAV/anti-GBM 38%, MCD/FSGS 24%, MGN 19%, and SLE 16% | Anti-S1/S2 protein antibodys IgG CLIA (Abbott) | T SPOT (Oxford Immunotec) | N.A. |
Rotondo et al. [55] | Italy | 137 | 70% | 57 | BNT 78%, and AZ 22% | Arthritis 78%, and CTD 18% | N.A. | N.A. | Questionnaire |
Rubbert-Roth et al. [56] | Switzerland | 53 | 55% | 65 | BNT 83%, and Moderna 17% | RA | Anti-RBD antibody ECLIA (Roche) | N.A. | N.A. |
Ruddy et al. [57] | USA | 404 | 96% | 44 | Moderna 51%, and BNT 49% | Inflammatory arthritis 45%, and SLE 22% | Anti-RBD antibody ECLIA (Roche) | N.A. | N.A. |
Sattui et al. [58] | Global RheumatologyAlliance | 2860 | 87% | 55 | BNT 53%, AZ 23%, Moderna 21%, and J&J 2% | RA 42%, IIM 17%, PSS 15%, and SLE 14% | N.A. | N.A. | Online survey |
Schmiedeberg et al. [59] | Switzerland | 17 | 47% | 67 | BNT 82%, and Moderna 12% | RA | Anti-RBD antibody ECLIA (Roche) | N.A. | N.A. |
Sciascia et al. [60] | Italy | 102 | 85% | 52 | BNT 66%, and Moderna 34% | APS 51%, and aPL 49% | N.A. | N.A. | Clinical record |
Seyahi et al. [61] | Turkey | 104 | 66% | 48 | CoronaVac | SpA 23%, RA 18%, CTD 16%, BS 14%, and FMF 10% | Anti-RBD antibody ECLIA (Roche) | N.A. | N.A. |
Simon et al. [62] | Germany | 84 | 66% | 53 | BNT | SpA 32%, RA 30%, IBD 10%, and PsO 10% | Anti-S1 protein antibody ELISA (Euroimmun) | N.A. | Clinical record |
Spiera et al. [59] | USA | 89 | 76% | 61 | BNT 57%, and Moderna 43% | RA 26%, GPA 13%, PSS 11%, and SLE 10% | Anti-RBD antibody ECLIA (Roche) | N.A. | N.A. |
Tzioufas et al. [63] | Greece | 605 | 71% | 58 | BNT 95%, and Moderna 5% | RA 28%, seronegative arthritis 21%, SLE 20%, and vasculitis 11%, | Anti-S1 protein antibody ELISA (Euroimmun) | N.A. | Questionnaire |
Yang et al. [64] | USA | 70 | 69% | 48 | mRNA vaccines | RA 30%, SpA 30%, SLE 11%, and IBD 10% | N.A. | N.A. | Clinical record |
Zavala-Flores et al. [65] | Peru | 100 | 94% | 39 | BNT | SLE | N.A. | N.A. | Clinical record |
Factors |
---|
Older age |
Lower B lymphocyte count |
Lower serum IgG |
Shorter interval between vaccination and last infusion of anti-CD20 therapy |
Not achieving B cell reconstitution after anti-CD20 therapy |
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Tang, K.-T.; Hsu, B.-C.; Chen, D.-Y. Immunogenicity, Effectiveness, and Safety of COVID-19 Vaccines in Rheumatic Patients: An Updated Systematic Review and Meta-Analysis. Biomedicines 2022, 10, 834. https://doi.org/10.3390/biomedicines10040834
Tang K-T, Hsu B-C, Chen D-Y. Immunogenicity, Effectiveness, and Safety of COVID-19 Vaccines in Rheumatic Patients: An Updated Systematic Review and Meta-Analysis. Biomedicines. 2022; 10(4):834. https://doi.org/10.3390/biomedicines10040834
Chicago/Turabian StyleTang, Kuo-Tung, Bo-Chueh Hsu, and Der-Yuan Chen. 2022. "Immunogenicity, Effectiveness, and Safety of COVID-19 Vaccines in Rheumatic Patients: An Updated Systematic Review and Meta-Analysis" Biomedicines 10, no. 4: 834. https://doi.org/10.3390/biomedicines10040834
APA StyleTang, K. -T., Hsu, B. -C., & Chen, D. -Y. (2022). Immunogenicity, Effectiveness, and Safety of COVID-19 Vaccines in Rheumatic Patients: An Updated Systematic Review and Meta-Analysis. Biomedicines, 10(4), 834. https://doi.org/10.3390/biomedicines10040834