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. 2021 Feb 21;41(4):715–719. doi: 10.1007/s00296-021-04812-8

COVID-19 outcomes in patients with familial Mediterranean fever: a retrospective cohort study

Serdar Can Güven 1,, Abdulsamet Erden 1, Özlem Karakaş 1, Berkan Armağan 1, Eren Usul 2, Ahmet Omma 1, Orhan Küçükşahin 3
PMCID: PMC7897358  PMID: 33611656

Abstract

Aim of this study is to investigate the course of coronavirus disease 2019 (COVID-19), in our cohort of familial Mediterranean fever (FMF) patients in means of mortality, admission to hospital and/or intensive care unit and length of hospital stay.A retrospective cohort was formed from patients who have previously been followed with a diagnosis of FMF. Patients of this cohort were retrospectively evaluated for a positive severe acute respiratory syndrome-coronavirus 2 (SARS-CoV 2) polymerized chain reaction (PCR) test result and information regarding hospitalisation, intensive care unit admission and mortality were collected from medical records.Out of a total 496 FMF patients, 34 were detected to have a positive SARS-CoV 2 PCR test. Eighty-five point three percent of these patients were under colchicine treatment and 17.6% were under interleukin (IL)—1 inhibitor treatment. Eight of the 34 patients (23.9%) were found to be hospitalized, one of them was admitted to the intensive care unit and died thereafter (2.9%). An increasing trend in the frequency of comorbid diseases (presence of at least one comorbidity 64.7% in all patients vs 75.0% in hospitalized patients) and IL-1 inhibitor usage (17.6% in all patients vs 50.0% in hospitalized patients) was observed in hospitalized patients.Rates of comorbid diseases and IL-1 inhibitor use for FMF were observed to be increased in FMF patients hospitalized for COVID-19.

Keywords: Familial, Mediterranean, Fever, Coronavirus, Outcome

Introduction

Coronavirus disease 2019 (COVID-19) pandemic, caused by severe acute respiratory syndrome-coronavirus 2 (SARS-CoV 2), has become a major global health issue since December 2019. The disease course is heterogeneous. Although most patients suffer mildly, a significant portion of the patients develops fatal complications such as acute respiratory distress syndrome, multiorgan failure and a hyperimmune state so-called “cytokine storm”, which is characterized by the extreme release of various cytokines and chemokines, disequilibrium in distribution of T-cell subsets and related with a poor prognosis [13]. The true cause of this state is yet to be fully clarified but hypothetically a hyperreactive immune system, prolonged inflammatory response due to delayed viral clearance or immune dysregulation may be the underlying reasons [3].

Activation of inflammasomes by viral proteins and release of proinflammatory cytokines is a natural response of innate immunity to viral infections however, a dysregulated inflammasome activity may also result in an aberrant inflammatory response. Likewise, in Familial Mediterranean fever (FMF), a hereditary innate immunity disorder due to gain of function mutations in Mediterranean fever gene (MEFV) encoding pyrin protein, a hyperactive pyrin inflammasome leads to febrile inflammatory episodes sharing similarities with COVID-19-associated cytokine storm [4, 5]. As mentioned before, an already hyperresponsive innate immune system may increase susceptibility developing cytokine storm and severe symptoms in COVID-19. On the other hand, the presence of MEFV mutations were suggested to be advantageous against some infections [6]. Therefore it is intriguing whether the hyperactive innate immunity of FMF patients would provide protection against COVID-19 or lead to a more severe disease course.

Colchicine and interleukin 1 (IL-1) antagonists, the mainstay of treatment in FMF with well-established effectiveness in controlling hyperinflammation, have also been investigated in the management of COVID-19 and promising results have been observed [716]. It is also a matter of interest whether in FMF patients who already receive these agents, a preventive effect against the development of cytokine storm during COVID-19 would be observed.

There is scarce knowledge in the literature regarding COVID-19 course in autoinflammatory conditions like FMF, particularly in adult patients [6, 1619]. To further contribute to the knowledge in this subject, we aimed in our study to evaluate outcomes of COVID-19 in our cohort of FMF patients in means of mortality, admission to hospital and/or intensive care unit (ICU) and length of hospital stay.

Method

Study design

This study was designed as a cross-sectional, retrospective cohort study with approval by Ankara City Hospital ethics committee and was therefore performed in accordance with the ethical standards laid down in the 1964 Declaration of Helsinki and its later amendments. An official permission was obtained from the Ministry of Health, to conduct this study dated 21 Jul 2020.

Patients

A retrospective cohort was formed from FMF patients meeting Tel-Hashomer criteria [20], who have previously been followed by authors (AE, AO, BA, OK, SCG) in either Ankara City Hospital or Ankara Numune Training and Research Hospital or Ankara Atatürk Training and Research Hospital (the latter two centers were merged to found Ankara City Hospital in 2019 and have been working as a single-center since clinical records of all three centers are accessible via Ankara City Hospital database). Between December 1 and 15, 2020, patients of this cohort were retrospectively investigated for a SARS-CoV 2 polymerized chain reaction (PCR) test result from Public Health Management System (HSYS), to which all cases with a PCR test were registered during the pandemic in our country. Patients older than 18 years of age with a recorded positive PCR test result from nasopharyngeal swab between March 11 and December 1, 2020 were enrolled in the study.

Main outcomes and other variables

Rates of hospitalization, ICU admission and mortality due to COVID-19 were selected as main outcome variables and collected from medical records and HSYS. Data regarding to demographics, comorbidities, MEFV mutations and medical treatment administered for FMF were collected from the Ankara City hospital database. Adherence to medical treatments were confirmed by the presence of consecutive drug prescriptions due date of positive SARS-CoV 2 PCR test in Social Security Institution Medical Messenger (MEDULA) records since the pandemic of COVID-19 interrupted regular follow-ups.

Statistical analysis

Data were analyzed using Statistical Package for the Social Sciences (SPSS) 22.0 software. Normality of continuous variables was evaluated with Shapiro–Wilk test and with plots and histograms visually. Continuous variables were presented either with median (minimum–maximum) or mean ± standard deviation, according to normality. Categorical variables are presented with numbers and percentages.

Results

Clinical features

Our cohort included a total of 496 FMF patients. Among these, 34 patients were detected to have a positive SARS-CoV 2 PCR test. Demographics, comorbid diseases and drugs for active FMF treatment of these patients were given in Table 1. Median age was 40.5 years and 64.7% of the patients had at least one comorbid disease, hypertension being the most frequent (23.5%). Eighty-five point three percent of these patients were under colchicine treatment and 17.6% were under IL-1 inhibitor treatment (all of which was anakinra). Three of the patients (8.8%) were detected to have proteinuria exceeding 1 g per day (Table 1). Mediterranean fever gene (MEFV) mutations were obtained from hospital records in 14 out of 34 patients (five M694V homozygous, four M694V heterozygous, two V726A heterozygous, one M680I homozygous, one M680I heterozygous, one E167D/F479L compound heterozygous).

Table 1.

Demographics, comorbidities, active familial Mediterranean fever medications and coronavirus disease 2019 outcomes in familial Mediterranean fever patients with a positive severe acute respiratory syndrome-coronavirus 2 polymerized chain reaction test

All (n = 34) Hospitalized (n = 8)
Age, years, median (min–max) 40.5 (23–59) 43.5 (38–59)
Gender, male, number (%) 20 (58.8) 3 (37.5)
Patients with ≥ 1 comorbidities, number (%) 22 (64.7) 6 (75)
Patients with ≥ 2 comorbidities, number (%) 8 (23.5) 4 (50)
Comorbidities, number (%)
 Hypertension 8 (23.5) 4 (50)
 Diabetes 3 (8.8) 3 (37.5)
 Hyperlipidemia 1 (2.9) 0 (0)
 Asthma 3 (8.8) 1 (12.5)
 Hypothyroidism 3 (8.8) 2 (25)
 Coronary artery disease 2 (5.8) 1 (12.5)
 Congestive heart failure 1 (2.9) 1 (12.5)
 End-stage renal disease 1 (2.9) 0 (0)
 Spondyloarthritis 6 (17.6) 2 (25)
 Proteinuria > 1 g/day 3 (8.8) 2 (25)
 Others 7 (20.5) 1 (12.5)
Active medical treatment for familial Mediterranean fever, number (%)
 Colchicine 29 (85.3) 8 (100)
 IL-1 inhibitors 6 (17.6) 4 (50)
 TNFα inhibitors 1 (2.9) 0 (0)
Coronavirus disease 2019 outcomes
 Hospitalization, number (%) 8 (23.5)
 Length of hospital stay (days), median (min–max) 7.5 (3–19)
 ICU admission, number (%) 1 (2.9)
 Death, number (%) 1 (2.9)
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IL-1 interleukin-1, TNFα tumor necrosis factor alpha, ICU intensive care unit

Outcomes

Eight of the 34 patients (23.5%) were found to be hospitalized for COVID-19 and one of them was admitted to ICU and died thereafter (Table 1). This patient was female, aged 58 years and had multiple comorbidities including diabetes mellitus, hypertension, congestive heart failure and proteinuria > 1 gr/day. She was both under colchicine and anakinra treatments. None of the other patients were admitted to ICU or died. Median length of hospital stay was found to be 7.5 days. Fifty percent of the hospitalized patients had at least two comorbid diseases. An increasing trend in the frequency of comorbid diseases (presence of at least one comorbidity: 64.7% in all patients vs 75.0% in hospitalized patients) and IL-1 inhibitor usage (17.6% in all patients vs 50.0% in hospitalized patients) was observed in hospitalized patients (Table 1). Two out of three patients with proteinuria were hospitalized.

Discussion

Our results demonstrated that among 34 FMF patients with a positive SARS-CoV 2 PCR test, eight of them were hospitalized and one admitted to ICU and died consequently. The lost patient was relatively older, had multiple comorbidities including proteinuria and was under IL-1 inhibitor treatment. Comorbid disease burden and administration of IL-1 blockers for FMF treatment was observed to be increased in hospitalized patients.

Age, male gender, body mass index, presence of comorbid diseases and certain antirheumatic drugs (rituximab, mycophenolate mophetil, steroids) were reported to be related to worse outcomes in rheumatic conditions [19, 21]. However, there are limited knowledge about COVID-19 outcomes in FMF patients [16, 18]. Course of COVID-19 in FMF patients is a matter of interest since FMF attacks share similarities with COVID-19 related cytokine storm [3]. It can be speculated that the already hyperreactive innate immunity of FMF patients with defective inflammasomes, may increase susceptibility to hyperinflammatory response in COVID-19. In one study including a relatively large number of FMF patients, Bourguiba et al. [17], reported seven hospitalizations and two deaths out of 27 patients infected with SARS-CoV 2 in a cohort of 342 FMF patients, suggesting a similar disease course with the general population. Likewise, in a large study from France in which COVID-19 survival was evaluated in various rheumatic conditions, two deaths out of 15 periodic fever patients were reported without significantly increased risk of death when compared to other rheumatic conditions. However, the authors suggested cautious interpretation of the results for autoinflammatory diseases due to a very low number of patients [19]. We observed 23.9% hospitalization and 2.9% mortality rate in 34 patients in our study.

Mainstay treatment agents of FMF, colchicine and IL-1 inhibitors particularly anakinra, have also been considered in the treatment of COVID-19. There are several reports of anakinra administration in severe COVID-19 with promising results [1115]. However, among our FMF patients with COVID-19, four out of six anakinra users were hospitalized and one of them eventually died. Likewise, Bourguiba et al. [17] reported two deaths in four anakinra users. Since anakinra is generally used in FMF patients with amyloidosis or colchicine resistance, anakinra administration may indicate a rather severe disease course in FMF patients. Therefore, it is unclear whether this trend is due to long-term IL-1 inhibition or to disease burden.

Two out of three patients with urine protein excretion over 1 g per day were hospitalized in our study. Although such excessive proteinuria is highly suggestive of concomitant amyloidosis in FMF, none of these patients had a histopathologic confirmation therefore direct assumptions should be avoided. Regardless, the presence of severe proteinuria may be an important contributor to worse prognosis in FMF patients with COVID-19. Infections have previously been reported as the leading cause of mortality in AA amyloidosis and presence of nephrotic syndrome was discussed as a potential contributor to overall immunosuppression in these patients [22]. However, our patient population is insufficient to prove such deduction.

Retrospective nature of the study, small sample size and lack of control group indicate cautious interpretation of our results. The absence of clinical diagnosis of COVID-19 and biopsy-proven amyloidosis are other limitations of our study. In addition, the effects of chronic colchicine use on COVID-19 course cannot be interpreted with our results. Furthermore, some COVID-19 cases in our cohort may have been missed due to asymptomatic or mild disease course. Nevertheless, we think our results are still valuable since there is scarce data in the literature regarding COVID-19 outcomes in FMF patients.

Conclusions

Our results demonstrated mortality and hospitalization rates in FMF patients with COVID-19 similar to the previous reports in the literature. Frequency of comorbid diseases, proteinuria and IL-1 inhibitor use for FMF were tended to be higher in hospitalized patients. Proteinuria and IL-1 inhibitor use may be related to the disease severity of FMF. However, larger studies are needed for more accurate conclusions about COVID-19 outcomes in FMF patients.

Acknowledgements

Authors declare none.

Abbreviations

COVID-19

Coronavirus disease 2019

FMF

Familial Mediterranean fever

ICU

Intensive care unit

IL-1

Interleukin 1

MEDULA

Social Security Institution Medical Messenger

MEFV

Mediterranean fever gene

PCR

Polymerized chain reaction

SARS-CoV 2

Severe acute respiratory syndrome-coronavirus 2

SPSS

Statistical Package for the Social Sciences

TNFα

Tumor necrosis factor alpha

Author contributions

All authors substantially contributed to study design and acquisition, analysis and interpretation of the data. All authors revised the final version of the work and approved it for publication in agreement on all aspects of the study. There is no editing support to acknowledge.

Funding

This research did not receive any grant.

Data availability

The datasets used in this study are available from the corresponding author on valid request.

Compliance with ethical standards

Conflict of interest

The authors declare that they have no conflicts of interest.

Ethics approval

The study protocol was approved by the institutional committee on Human Research Ethics.

Footnotes

Publisher's Note

Springer Nature remains 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 datasets used in this study are available from the corresponding author on valid request.

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