JCB J Circ Biomark 2021; 10: 20-25ISSN 1849-4544 | DOI: 10.33393/jcb.2021.2327REVIEW

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published a study on cytokine profiling in patients with ANCA-
associated vasculitis (AAV) (6). Serum from healthy subjects 
and from patients with AAV or other autoimmune-mediated 
diseases was analyzed for concentrations of certain pro- and 
anti-inflammatory mediators. It became apparent that serum 
IL-33 was significantly higher in AAV subjects than in controls. 
Also, AAV patients with necrotizing glomerulonephritis (NGN) 
differed from AAV subjects without NGN. These findings led 
to the hypothesis of IL-33 as a potential biomarker in acute 
renal diseases, namely in AKI. The respective study has been 
initiated and is ongoing. The current article will summarize 
the most important references on IL-33 as a diagnostic tool 
and risk predictor in genetic and acquired diseases.

Interleukin-33—origin and physiology

Interleukin-33 (IL-33) belongs to the IL-1 family of cytoki-
nes (7). Common feature of the latter is a beta-trefoil struc-
ture, which has been identified in proteins such as IL-1alpha 
and -beta, IL-1Ra, and IL-18. IL-33 was initially found within 
endothelial cell nuclei of so-called human high endothelial 
venules (HEV). Baekkevold et al (8) described the protein 
as NF (nuclear factor)-HEV. Later, Pichery and colleagues (9) 
detected IL-33 within the nuclei of murine cells in various 
tissues, such as epithelial cells, lymphoid organs, brain, 
and embryonic tissue. Herein, the cytokine was expres-
sed in a constitutive manner. In contrast, blood vessels did 
not show constitutive IL-33 expression. Within nuclei, IL-33 
binds to chromatin (10); in the extracellular space however, 
it interacts with ST2. The latter exists as membrane-bound 
and soluble isoform (sST2), respectively (11). Interleukin-33 
mediates so-called alarmin function. Alarmins, which are 
represented by extracellularly secreted proteins of various 

Serum IL-33 as a biomarker in different diseases:  
useful parameter or much need for clarification?
Stefan Erfurt1, Meike Hoffmeister2, Stefanie Oess2, Katharina Asmus1, Oliver Ritter1, Susann Patschan1, Daniel Patschan1

1 Department of Medicine 1, University Hospital Brandenburg, Medical School (MHB) Theodor Fontane, Brandenburg - Germany
2 Institute of Biochemistry, Brandenburg Medical School (MHB) Theodor Fontane, Brandenburg - Germany

ABSTRACT
Interleukin-33 (IL-33), a member of the IL-1 family, is critically involved in the modulation of the activity of a 
diverse range of immunocompetent cells. Essential roles have been implicated in cardioprotection, in both in-
nate and adaptive immune responses in mucosal organs, and in the maintenance of adipose tissue cells. Over 
the past 10 years, several studies evaluated the usability of IL-33 as a biomarker in diseases of inflammatory and 
noninflammatory origin. Our group is currently evaluating the predictive role of serum IL-33 in acute kidney injury 
(AKI). The aim of the article is to discuss selected studies on IL-33 in different diseases and its potential role as a 
biomarker molecule.
Keywords: Biomarker, IL-33, Inflammatory diseases, Noninflammatory diseases

Introduction

The identification of biomarkers for either early diagnosis 
or risk prediction in various diseases remains a fundamental 
goal in the whole field of medicine. A sophisticated discussion 
of all or of at least the most important findings in recent years 
is impossible in one single article that is intended to focus on 
one potential marker molecule. The literature on biomarkers 
in even one particular disease, such as acute kidney injury 
(AKI), is vast. For illustrative purposes, it needs to be men-
tioned that more than 100 candidate molecules have been 
investigated in AKI subjects over the past 20 years (1). Only 
few parameters (e.g., NGAL, KIM-1 (2,3)) or combinations 
of two proteins such as the product of urinary insulin-like 
growth factor-binding protein (IGFBP-7) and tissue inhibi-
tor of metalloproteinase (TIMP-2) (4,5) have been proven 
as reliable tools for diagnostic/prognostic purposes under 
certain AKI-associated conditions. However, no parameter 
can truly replace serum creatinine for measuring excretory 
kidney function in daily clinical practice, despite creatinine 
far from being an “optimal” biomarker. In 2019, our group 

Received: August 3, 2021
Accepted: November 10, 2021
Published online: November 30, 2021

Corresponding author:
Daniel Patschan
Zentrum Innere Medizin 1 
Universitätsklinikum Brandenburg 
Medizinische Hochschule Brandenburg 
Hochstraße 29 
14770 Brandenburg - Germany
daniel.patschan@mhb-fontane.de

https://doi.org/10.33393/jcb.2021.2327
https://creativecommons.org/licenses/by-nc/4.0/legalcode
mailto:daniel.patschan@mhb-fontane.de


Erfurt et al J Circ Biomark 2021; 10: 21

© 2021 The Authors. Published by AboutScience - www.aboutscience.eu

origin and phenotype, indicate cell/tissue damage. Subse-
quently, immune cells are activated. In this context, IL-33 has 
been shown to modulate the activity of mast cells, group 2 
innate lymphoid cells (ILC2s), T helper 2 cells, eosinophils, 
basophils, dendritic cells, macrophages, and others (12). 
Essential roles of the cytokine have been implicated in car-
dioprotection (11), in both innate and adaptive immune 
responses in mucosal organs (13) and in the maintenance of 
adipose tissue cells (via immune cell modulation) (14).

Quantification of serum IL-33

The data on IL-33 quantification by either ELISA (enzyme-
linked immunosorbent assay) or multiplex technologies are 
heterogeneous. By far not all groups initially succeeded in 
measuring serum levels of the cytokine. Firstly, Krychtiuk 
and colleagues (15), who identified low serum IL-33 to be 
predictive in intensive care-treated patients, did not detect 
the protein in 57 out of 223 subjects. In 2016, Ketelaar et 
al (16) reported the results of serum IL-33 quantification 
by using four different ELISA kits (Quantikine and DuoSet, 
R&D systems, respectively; ADI-900-201, Enzo Life Sciences; 
SKR038, GenWay Biotech Inc, San Diego, USA). Serum sam-
ples were drawn from asthma patients. The authors included 
different numbers of samples per individual kit: Quantikine—
n = 45; DuoSet—n = 17; ADI-900-201—n = 17; SKR038—n = 
22). Surprisingly, the percentages of samples above the lower 
detection limit (LLD) were 0 (zero) in two kits (ADI-900-201 
and SKR038). The Quantikine kit showed only 2% of all sam-
ples above the LLD, the DuoSet kit was successful in at least 
76%. Comparable findings were reported by Asaka et al (17), 
who also employed the Quantikine kit. Difficulties in IL-33 
quantification were also reported by Rivière and colleagues 
(18). In this context, it needs to be noted that erythrocytes 
contain IL-33 in relevant concentrations. Thus, hemolysis 
may increase serum IL-33 concentrations and potentially 
adulterate the findings in biomarker-related studies (19). 

Aberrant IL-33 in diseases: elevation

Genetic disorders

Behairy and colleagues (20) evaluated 60 infants with 
cholestasis, assigned to one of two subgroups with ver-
sus without biliary atresia (BA and non-BA group). Subjects 
belonging to the first group showed significantly higher serum 
IL-33. Also, IL-33 was higher in both groups as compared to 
healthy controls. Finally, IL-33 correlated with aspartate and 
alanine aminotransferase (ALT), and with serum bilirubin in 
a positive manner, respectively. Since cytokine levels addi-
tionally correlated with the fibrosis stage, the authors con-
cluded a potential (pathogenic) role of IL-33 in BA disease 
progression.

Cardiovascular diseases

A study in subjects with chronic kidney disease (CKD) 
was published in 2017 (21). Two-hundred and thirty-eight 
CKD patients were followed up for 24 months. Both serum 

IL-33 and ST2, the circulating isoform of the IL-33 receptor, 
were quantified and associated with cardiovascular events 
and parameters of endothelial dysfunction (flow-mediated 
vasodilation, FMD). The two analytes increased with decre-
asing estimated glomerular filtration rate and elevated levels 
were associated with impaired FMD and cardiovascular risk. 
Nevertheless, Bao et al (22) failed to show increased IL-33 in 
CKD subjects. In experimental studies TGF-β KO (knock out) 
enhanced IL-33, and while its inflammatory regulation varies 
with the disease, in the heart it protects against pathological 
remodeling after infarction, myocyte hypoxia, pressure over-
load, and increased Ca2+ release from the SR (sarcoplasmic 
reticulum) which is tunneled to mitochondria via mitochon-
drial RyR, leading to stimulation of mitochondrial adenosine 
triphosphate production (23). 

Autoimmune-mediated diseases

In 2010, Mu et al published data on rheumatoid arthritis 
(RA) (24). Three groups were evaluated: healthy controls, RA 
subjects, and patients with osteoarthritis. The cytokine was 
not detectable in controls and osteoarthritis but in almost 
100 RA subjects (42.2%). Cytokine concentrations correlated 
with the RF and anti-CCP titers, respectively, and anti-TNF-
alpha therapy reduced IL-33 serum levels. IL-33 elevation in 
RA was also shown by Hong and colleagues (25). Borsky et al 
(26) performed a study in psoriasis vulgaris subjects, inten-
ded to quantify serum levels of alarmins. The latter act as 
danger signals. The following factors were analyzed: HMGB1, 
IL-33, S100A7, and S100A12. In total, 63 psoriasis patients 
and 95 controls were included. All four proteins were ele-
vated in a significant manner. Correlations between serum 
concentrations and disease activity were however not iden-
tified. Our group studied subjects with AAV and with other 
autoimmune-mediated diseases (6). Serum concentrations 
of the following parameters were measured: IL-1β, IL-6, IL-17 
A, IL-17 F, IL-21, IL-22, IL-23, TNF-α, sCD40L, IL-4, IL-10, IL-25, 
IL-31, IL-33, and INF-γ. A total number of 62 AAV subjects 
were included in the study (39 females; 23 males). Forty-five 
subjects were PR3+, 17 subjects showed ANCA specificity for 
MPO (myeloperoxidase). Serum IL-33 was elevated in AAV 
and SSc (systemic sclerosis). In AAV, higher levels were found 
in non-NGN. Minaga et al (27) investigated a rarer type of 
disease, type 1 autoimmune pancreatitis (type 1 AIP), belon-
ging to the heterogeneous group of IgG4-related disease 
(IgG4-RD). The study revealed higher levels of interferon-
alpha and of IL-33 in type 1 AIP subjects in comparison to 
individuals with chronic pancreatitis of other origin and to 
healthy controls. Bakr et al (28) analyzed serum IL-33 in 
patients with pemphigus vulgaris. Affected subjects showed 
higher cytokine levels than healthy controls. Also, serum 
levels significantly correlated with the activity of the disease 
(measured by the Pemphigus Disease Area Index, PDAI).

Neoplasia

A study in patients with newly diagnosed prostate can-
cer was published in 2019 (29). One-hundred and fifty indivi-
duals were included. Serum IL-33 was higher than in controls, 



Serum IL-33 as biomarker22 

© 2021 The Authors. Journal of Circulating Biomarkers - ISSN 1849-4544 - www.aboutscience.eu/jcb

particularly in subjects with higher disease stages. Neverthe-
less, cytokine concentrations did not differ between certain 
predefined genotypes. As a matter of fact, elevated IL-33 has 
also been documented in other malignant diseases such as 
gastric cancer (30), endometrial cancer (31), non-small cell 
lung cancer (32), and breast cancer (33).

Sepsis

Sepsis may be regarded as an archetype of a widespread 
inflammatory disease. In 2016, Çekmez and colleagues (34) 
reported data from 128 septic children (20 of these were 
controls). Finally, 68 individuals were excluded since blood 
cultures were negative. Serum IL-33 differed significantly 
between the two groups of controls vs sepsis (1.1 ± 0.28 ng/
mL vs 5.23 ± 1.80 ng/mL; p = 0.01). Two years later, another 
study performed in septic children (neonates) (35) showed 
comparable findings with a rapid IL-33 increase at the first 
day after diagnosis, followed by a decrease over time (days 
3 and 7).

Others

Although immune-mediated mechanisms are substan-
tially involved in the pathogenesis of asthma bronchiale, 
the disorder has been placed in this section. Bahrami and 
colleagues (36) included 61 affected children and 63 healthy 
controls in their analyses and found serum IL-33 to be 
significantly elevated. Blood cytokine levels increased with 
increasing disease severity. The predictive value of serum 
IL-33 in polytraumatized subjects was analyzed by Halát and 
colleagues (37). The specific aim was to evaluate whether 
IL-33 is suitable for the prediction of pulmonary complica-
tions. The study included 130 patients, serum samples were 
obtained at the time of hospital admission and 2 days later. 
Subjects that developed both parenchymal lung injury and 
subsequent Acute Respiratory Distress Syndrome (ARDS) 
showed particularly high serum IL-33 at the time of admis-
sion. It was hypothesized that the cytokine is involved in 
promoting sustained lung injury in traumatized patients. 
Sundnes et al (38) also published a trial in traumatized 
individuals (n = 136). Plasma samples were collected at the 
time of hospital admission and several hours later (2, 4, 6, 
and 8 hours). The analyses showed a rapid and transient 
IL-33 increase in a subset of patients. The latter presented 
with more intense tissue injuries and a higher degree of 
coagulopathy. Another study related to serum patterns of 
alarmins (Danger-Associated Molecular Patterns—DAMPs) 
focused on schizophrenia. The following molecules were 
quantified: IL-33, sST2, HMGB1, and S100B (39). The study 
included 68 patients suffering from chronic schizophre-
nia and 29 healthy controls. All four analytes were higher 
in the disease group. It was concluded that alarmins may 
be involved in latent neuroinflammation underlying/per-
petuating schizophrenia. Yuan and colleagues focused on 
chronic hepatitis B (CHB) (40). A total number of 130 CHB 
patients were included, 48 cases were defined as stable, 50 
patients showed progression to acute-on-chronic liver fai-
lure (ACLF), 30 individuals also progressed but with overall 

milder dynamics (pre-ACLF). The highest IL-33 levels were 
detected in ACLF patients, associations were found with 
serum ALT, aspartate transaminase, and the Model End-
Stage Liver Disease (MELD) score, respectively. The combi-
nation of serum IL-33 and the MELD score was predictive 
with regard to the 90-days mortality. Thus, IL-33 was propo-
sed as prognostic marker in CHB-associated liver disease. In 
2021, Venkataraman et al (41) published multiplex immune 
assay data from children with “Paediatric inflammatory 
multisystem syndrome temporally associated with SARS-
CoV-2 infection (PIMS-TS).” Numerous cytokines were ele-
vated, including IL-33. Duan and colleagues analyzed gout 
patients and found increased IL-33 in respective subjects 
with even higher levels in those individuals without impai-
red kidney function (42). Also, IL-33 was negatively correla-
ted with markers of kidney dysfunction.

Aberrant IL-33 in diseases: suppression

Cardiovascular diseases

Experimental data showed neuroprotective effects of 
IL-33 (43,44). Therefore, Chen et al (45) evaluated the rela-
tionship between serum IL-33 and the risk for hemorrhage 
transformation (HT) of acute ischemic stroke (AIS) in 
humans. More than 150 individuals were included, none of 
these received thrombolytic therapy. Patients were assigned 
to the HT group if any radiographic signs of HT became appa-
rent during the first 2 weeks after AIS diagnosis. Multivariate 
regression analysis identified IL-33 as an independent HT 
predictor (lower serum IL-33 levels were associated with 
higher HT risk). The authors expanded their analyses in the 
context of poststroke depression (46) and found a compa-
rable (inverse) association between serum IL-33 and the 
risk for depression after AIS. Together, the data confirmed 
the concept of IL-33-mediated neuroprotection, even in 
humans. In this context, an important study by Li et al (47) 
evaluated long-term outcome variables of stroke patients in 
relation to initial serum IL-33. Higher cytokine levels were 
associated with a better 2-year outcome of affected indivi-
duals. Low serum IL-33 was finally also shown to be predic-
tive in patients with intracerebral hemorrhage (48). A study 
in patients with heart failure with reduced ejection fraction 
(HF-REF) was published by Segiet et al (49). One hundred 
and fifty-five HF-REF individuals (males: 106, females: 49) 
were included, the mean left ventricular ejection fraction 
was 32.13 ±12.8%. Patients displayed lower mean serum 
IL-33 as compared to controls. Also, cytokine levels were 
lower in HF-REF of ischemic origin as opposed to HF-REF of 
other etiology.

Autoimmune-mediated diseases

A rarer autoimmune-mediated disorder (at least in cen-
tral Europe), Behçet’s disease was evaluated by Koca et al 
(50) who included 117 affected individuals. While patients’ 
serum IL-33 did not differ from control levels, active disease 
states were associated with lower IL-33. Nevertheless, cer-
tain allelic variations did not differ in serum IL-33. 



Erfurt et al J Circ Biomark 2021; 10: 23

© 2021 The Authors. Published by AboutScience - www.aboutscience.eu

Others

In contrast to the study by Halát et al (37), who found 
IL-33 to be elevated in polytraumatized patients, another 
investigation performed in critically ill subjects showed oppo-
site findings. Krychtiuk and colleagues (15) evaluated the 
predictive value of both IL-33 and sST2 with regard to the 
30 days mortality in 223 intensive care patients. IL-33 was not 
detectable at all in 57 subjects. Serum IL-33 concentrations 
below the median strongly predicted death in an indepen-
dent manner. Lower-than-normal IL-33 concentrations were 
also documented in osteoporosis (51) and in amyotrophic 
lateral sclerosis (52). Finally, Hasan et al (53) showed a nega-
tive correlation between IL-33 and the body mass index. They 
also found IL-33 to negatively correlate with HbA1C in non-
diabetic individuals.

No aberrant IL-33 in diseases

Cardiovascular diseases

Firouzabadi and colleagues (54) measured serum IL-33 
and the soluble isoform of its receptor (sST2) in 44 heart 

failure patients (n = 25 under carvedilol treatment vs n = 19 
without beta-blocker therapy) and in 22 healthy controls. 
The analyses did not reveal any differences between any of 
the three groups, which led to the conclusion that cardio-
protective effects of carvedilol are most likely not mediated 
via the IL-33/sSTs axis. Two other studies related to acute 
cardiovascular diseases did also not show any differences in 
serum IL-33 between controls and patients. Demyanets et al 
(55) investigated subjects with stable angina, NSTEMI (non-
ST-segment elevation myocardial infarction), or STEMI in 
comparison to healthy controls. Dhillon and colleagues (56) 
analyzed NSTEMI subjects. 

Table I summarizes studies on serum IL-33 in diseases, 
assigned to one out of three groups: elevation/suppression 
or constant IL-33.

Conclusions

The data on serum IL-33 in human diseases are hetero-
geneous. On the one hand, methodological difficulties in 
measuring serum IL-33 may occur and must always be put 
into consideration if low levels or no protein at all is detec-
table. The majority of studies in which IL-33 quantification 

TABLE I - Studies in serum IL-33 in inflammatory and noninflammatory disorders

IL-33 elevation IL-33 suppression Constant IL-33
Biliary atresia (20) HT of AIS (45) Heart failure (54)

CKD (21) Poststroke depression (46) CKD (22)

Rheumatoid arthritis (24) Long-term outcome after stroke (47) Stable angina pectoris, NSTEMI, STEMI (55)

Rheumatoid arthritis (25) Intracerebral hemorrhage (48) NSTEMI (56)

Psoriasis vulgaris (26) HF-REF (49)

Prostate cancer (29) Behçet’s disease (50)

Gastric cancer (30) Critically ill subjects (15)

Endometrial cancer (31) Osteoporosis (51)

Non–small cell lung cancer (32) Amyotrophic lateral sclerosis (52)

Breast cancer (33) Increased body weight (53)

Sepsis in infants (34)

Sepsis in infants (35)

Asthma bronchiale in children (36)

Polytrauma (37)

Trauma (38)

ANCA-associated vasculitis (6)

Pemphigus vulgaris (28)

Type 1 autoimmune pancreatitis (27)

Schizophrenia (39)

Hepatitis B-associated acute-on-chronic  
liver failure (40)

PIMS-TS (41)

gout (42)

References appear according to the order in the text.
AIS = acute ischemic stroke; CKD = chronic kidney disease; HF-REF = heart failure with reduced ejection fraction; HT = hemorrhage transformation; IL = interleukin; 
NSTEMI = non-ST-segment elevation myocardial infarction; PIMS-TS = pediatric inflammatory multisystem syndrome temporally associated with SARS-CoV-2 infection. 



Serum IL-33 as biomarker24 

© 2021 The Authors. Journal of Circulating Biomarkers - ISSN 1849-4544 - www.aboutscience.eu/jcb

succeeded showed higher blood concentrations of the cyto-
kine. However, to identify a pattern that potentially allowed 
conclusions on the exact role of serum IL-33 in inflammatory 
and noninflammatory diseases is quite difficult. We cited a 
total number of 21 studies that reported IL-33 elevation 
under pathological circumstances. Thirteen out of these 21 
investigations evaluated diseases with distinct inflammatory 
pathogenesis (exceptions: CKD, BA, schizophrenia, five mali-
gnancies). Two out of 10 studies reporting lower IL-33 were 
nevertheless also performed in inflammatory disease states 
(Behçet’s disease, critically ill subjects). Thus, it may be con-
cluded that elevation of serum IL-33 should be expected with 
higher probability in inflammatory than in noninflammatory 
disorders. The references on malignancies with elevated IL-33 
were all referring to carcinomas. Activation of the immune 
system is known to significantly occur in malignant disorders. 
It is therefore not surprising that diseases such as heart failure 
with preserved or reduced ejection fraction, ischemic stroke, 
or even most cases of AKI are not associated with increased 
serum IL-33. Regarding the heterogeneity of diseases with 
either IL-33 elevation or suppression, it is hardly possible to 
propose the molecule as specific biomarker at the moment. 

Disclosures
Conflict of interest: The authors declare no conflict of interest.
Financial support: This research received no specific grant from any 
funding agency in the public, commercial, or not-for-profit sectors.
Authors’ contributions: SE searched for literature and corrected the 
article. He also performed experiments related to IL-33. MH cor-
rected the article and is involved in a project related to IL-33. SO 
provided additional references and helped in structuring the article. 
KA assisted in writing. OR assisted in writing. SP corrected the article 
and designed the table. DP initiated writing, finalized the current 
version, and is also involved in a project related to IL-33.

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