Eosinopenia is associated with a high risk of serious disease during infection with the severe acute respiratory syndrome 
coronavirus 2, the causative agent of COVID-19. 
Persistent eosinopenia correlates with low rates of 
recovery, while the resolution of eosinopenia predicts 
improvement.1 Eosinophils have an important role in 
the pathogenesis of chronic respiratory diseases such 
as asthma and chronic obstructive pulmonary disease 
(COPD). In COPD, eosinopenia is associated with 
poorer patient outcomes and short-term readmission 
after discharge.2 Eosinophils also play a key role in 
allergic diseases, including asthma. Moreover, many 
patients with asthma can have intentionally induced 
eosinopenia by biological drugs. In addition, persistent 
peripheral eosinopenia indicates poor survival in 
sepsis.3 In this context, the role of eosinophils remains 
a puzzle in COVID-19, especially among those with 
severe disease or an associated obstructive lung disease. 
It is unclear if they directly play a pathobiological role 
in sepsis and lung injury or whether they are just 
sentinel cells that are harbingers of danger.

The incidence of eosinopenia in COVID-19 
patients has been shown to vary from 50.8% to 94%.3–5 
A lower prevalence of 26.93% was noted in a study 
from Spain, possibly due to a large sample size and the 
study period spanning through the course of the pollen 
season.6 Eosinopenia on admission is associated with 
a higher risk of severe disease and intensive care unit 
admissions. Yan et al. noted that eosinophil levels were 
significantly low in COVID-19 patients with critical 
disease and the eosinophil counts remained low or 
progressively declined in those with fatal outcomes.7 
Similarly, in another study, maximum reduction in 
eosinophils was observed on the fourth day from onset 
and these patients with low eosinophil counts were 
more likely to have fever, fatigue, dyspnoea and worse 
lesions in their computed tomography scan than those 
with normal counts.8 Peripheral eosinophil counts 
typically return to near normal levels as patients recover 
from moderate-to-severe infection suggesting that 
normalisation of the blood eosinophil count indicates 

recovery.9 On admission, a low eosinophil count was 
found to improve continuously, reaching significantly 
higher levels in survivors than among non-survivors 
with a greater increase indicating a better outcome.10 
Surprisingly, the prognostic utility of peripheral 
eosinophil counts varied with patient race and 
ethnicity.11 In contrast, increased levels of eosinophils 
were noted among patients with severe COVID-19 in 
a large cohort. However, this observation cannot be 
generalised as a different technique was used and low 
density eosinophils were counted.12 Thus, the current 
evidence suggests a protective role for eosinophils in 
mortality and length of hospital stay among patients 
with COVID-19.

There is mixed evidence regarding the prevalence 
of asthma in patients with COVID-19 or the effect 
of asthma and its treatment on the progression of 
the disease.13 Theoretically, patients with asthma 
could be at a higher risk considering their increased 
susceptibility to common respiratory virus-associated 
exacerbations. The prevalence of asthma was markedly 
lower among those diagnosed with COVID-19 
compared to the general population of Wuhan, China.14 
In a group of 140 hospitalised patients from Wuhan, 
no cases of asthma and allergic rhinitis were reported 
while the prevalence of asthma and allergic rhinitis in 
the province was 4.2% and 9.7%, respectively.5 A low 
incidence of 2.1% was noted in severe asthma patients 
from Belgium and none of them experienced a severe 
disease course or death.15 Similarly low incidence was 
reported from Italy, Russia and Australia.16 However, 
contradictory data were reported from Germany and 
the United States, where higher asthma prevalence 
was noted among patients with COVID-19.16 Though 
asthma was not a risk factor for poor prognosis, 
higher mortality was observed among those who had 
experienced an acute exacerbation in the previous 
year.17 Since eosinopenia is a biomarker for the 
severity of COVID-19, the eosinophil reduction/
depletion induced by anti-interleukin (IL)-5 and anti-
IL-5 receptor blocking monoclonal antibodies raises 
a real concern. However, reports on the safety of 

1Division of Pulmonology, Sultan Qaboos Comprehensive Cancer Care and Research Centre, Muscat, Oman; 2Department of Medicine, Division of Respirology, 
St Joseph’s Healthcare and Professor of Medicine, McMaster University, Hamilton, Ontario, Canada
*Corresponding Author’s e-mail: drjayakrish@hotmail.com

 This work is licensed under a Creative Commons Attribution-NoDerivatives 4.0 International License.

COVID-19, Obstructive Airway Disease and 
Eosinophils

A complex interplay

B. Jayakrishnan1 and Parameswaran Nair2

EDITORIAL

Sultan Qaboos University Med J, May 2022, Vol. 22, Iss. 2, pp. 163–166, Epub. 26 May 22
Submitted 16 Aug 21
Revision Req. 21 Oct 21;  Revision Recd. 2 Nov 21
Accepted 24 Nov 21

https://doi.org/10.18295/squmj.1.2022.001

https://creativecommons.org/licenses/by-nd/4.0/


COVID-19, Obstructive Airway Disease and Eosinophils 
A complex interplay

164 | SQU Medical Journal, May 2022, Volume 22, Issue 2

patients using the monoclonal antibodies for asthma 
or atopic dermatitis are reassuring.14,15,18 A study from 
Spain on 545 patients receiving different biologics for 
severe asthma found no increased risk, no greater 
disease severity or higher mortality.18 A large study on 
asthmatics, with infection confirmed by polymerase 
chain reaction testing, did not find anti-IL-5 biologics 
to increase the risk of infection or worsen outcomes. In 
contrast, systemic corticosteroids were an independent 
risk factor for the highest COVID-19 severity and all-
cause mortality.19 Nevertheless, there is clear evidence 
that asthma presents a lesser risk for developing severe 
COVID-19 and the current medications, including 
inhaled corticosteroids and biologics, remain safe for 
use.9,15,18

Available data certainly suggests a higher risk 
for severe COVID-19 in COPD patients. An early 
case series on COVID-19 from China reported a 
higher prevalence of COPD in patients with severe 
presentation and worse outcomes.20 A meta-analysis 
of studies in Chinese and English languages showed 
that the pre-existing COPD is associated with a 
four-fold increase in the risk of developing severe 
COVID-19.21 The prevalence of COPD among 
hospitalised COVID-19 patients ranges from 0% to 
10% in China, 2.4% to 14% in New York City and 5.6% 
to 9.2% in Italy.22 In COPD, higher blood eosinophil 
counts predict a positive response to corticosteroids 
and eosinopenia is associated with worsening of 
symptoms and severity of exacerbations.2

Eosinophils remain in the blood only for about 
8 to 12 hours before they migrate into tissues, where 
they are active for several days.9 They have potent pro-
inflammatory effects and participate in inflammation, 
immunoregulation and provide a defence against 
many diseases including viral infections.4 Proliferation, 
development and activation of eosinophils are 
controlled by IL-5, IL-3 and granulocyte-macrophage 
colony-stimulating factor (GM-CSF).23 The immune 
mechanism of eosinopenia in COVID-19 remains 
unclear. It is likely to be multifactorial, involving 
inhibition of the main steps in the eosinophil life cycle, 
apoptosis induced by type 1 interferon during acute 
infection or association with eosinophil consumption 
by their antiviral actions.1,24 It is also unclear if it is 
indeed eosinopenia that leads to poor outcomes or 
if eosinopenia is a manifestation of impaired GM-
CSF signalling, IL-33 secretion or the diminished 
expression of its receptor, ST2, in the airway 
epithelium.25 Thus, eosinopenia could either be the 
sign of host exhaustion trying to clear the COVID-19 
virus or a primary risk factor for a severe infection.24,26 
It is not clear whether the COVID-19 virus could 
involve the bone marrow and cause the decrease of 

peripheral blood eosinophils. Nevertheless, increased 
production of neutrophils in bone marrow leading to 
a reduction in eosinophil production has also been 
reported.8,27 To re-iterate, it is still not clear whether 
eosinopenia is the result of direct virus targeting or the 
result of generally impaired immunity.14 

Considering the anti-viral effects of eosinophils, 
the reported eosinopenia in COVID-19 patients is of 
special interest.28 Studies have indicated a potential 
role of eosinophils in promoting viral clearance and 
antiviral host defence. Respiratory virus infections 
are associated with asthma exacerbation in children 
and adults, among which rhinovirus is the most 
common agent.14 Asthma was identified as the 
single most common comorbid condition among 
hospitalised individuals with influenza A virus 
subtype haemagglutinine-1 neuraaminidase-1 (H1N1) 
infection, with rates of asthma ranging from 10% to 
32%.29 Interestingly, there are no reports regarding 
asthma exacerbation due to COVID-19. There were 
only a few reports on asthma exacerbation during 
the severe acute respiratory syndrome and Middle 
East respiratory syndrome epidemics as well. Though 
biological agents that induce eosinopenia reduce 
asthma exacerbations, patients enduring these 
conditions have not been reported to have increased 
viral infections.1 In fact, a large population-based 
cohort study showed that patients with nonallergic 
asthma had a higher risk of severe COVID-19 when 
compared to those with allergic asthma.30 Eosinophils 
in the respiratory tract might represent a “double-
edged sword”—promoting antiviral responses on 
the one hand and resulting in an exaggerated host 
response leading to tissue damage on the other.9 

This lack of susceptibility to COVID-19 in 
patients with pre-existing asthma and allergic airway 
disease appears in contrast with the established 
link between these chronic respiratory conditions 
and susceptibility to common respiratory viruses, 
especially rhinoviruses.6 However, rhinoviruses use 
intercellular adhesion molecule-1 as an entrance into 
respiratory epithelial cells which is overexpressed 
in allergic airways. In contrast, corona viruses use 
another host cell receptor, the angiotensin-converting 
enzyme 2 (ACE2). The expression of ACE2 on ACE 
inhibitors is increased in patients with COPD, diabetes 
mellitus and hypertension explaining their higher risk 
of developing COVID-19. On the other hand, lower 
expression of ACE has been noted in the airways of 
asthmatic patients which reduces the chances of a 
COVID-19 infection. Moreover, inhaled steroids can 
down regulate ACE2 receptors and suppress cytokine 
production and corona virus replication.31 The use of 
inhaled corticosteroids was found to be associated 



B. Jayakrishnan and Parameswaran Nair

Editorial | 165

with a decreased level of ACE2 and transmembrane 
protease serine 2 gene expression from sputum in 
asthmatic patients.32 An inhaled steroid, ciclesonide, 
reduced severe acute respiratory syndrome coronavirus 
2 (SARS-CoV-2) ribonucleic acid replication as well as 
host inflammation in the lungs in in-vitro studies.33 

Conclusion

Eosinopenia, that might also represent a low T2 
immune status, is associated with poor outcomes 
in asthmatic and possibly in non-asthmatic COPD 
patients. However, it is unclear if the eosinophils 
directly contribute to the pathobiology of SARS-CoV2 
lung injury or not. There is even less clarity around 
the role of lung eosinophils as this has not been 
extensively investigated. Eosinophils are unlikely to 
be directly involved in lung injury as the use of anti-
eosinophil biologics has not been associated with 
poor outcomes in asthma patients with COVID-19. 
Eosinophil numbers in peripheral blood are likely 
to be just a biomarker of the biological activity of T 
helper 2 cytokines. There is very little information on 
their numbers or activity in the airways in patients 
with COVID-19. The general consensus is to continue 
to manage airway diseases, both asthma and COPD, 
as per current guidelines with the appropriate use of 
corticosteroids and bronchodilators and judicious use 
of biologics as indicated.

a u t h o r s’ c o n t r i b u t i o n s
BJ conceptualised and wrote out the draft of the initial 
manuscript. BJ and PN contributed to the literature 
review. PN performed a critical review and both the 
authors approved the final version of the manuscript.

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