Archives of Academic Emergency Medicine. 2020; 8(1): e55

OR I G I N A L RE S E A RC H

Lobar Distribution of COVID-19 Pneumonia Based on
Chest Computed Tomography Findings; A Retrospective
Study
Sara Haseli1, Nastaran Khalili2∗, Mehrdad Bakhshayeshkaram1, Morteza Sanei Taheri3,4, Yashar
Moharramzad4

1. Chronic Respiratory Diseases Research Center, National Research Institute of Tuberculosis and Lung Diseases (NRITLD), Shahid Beheshti
University of Medical Sciences, Tehran, Iran.

2. School of Medicine, Tehran University of Medical Sciences, Tehran, Iran.

3. Iranian Society of Radiology, Tehran, Iran.

4. Department of Radiology, Shohada-E-Tajrish Hospital, Shahid Beheshti University of Medical Sciences, Tehran, Iran.

Received: April 2020; Accepted: April 2020; Published online: 18 April 2020

Abstract: Introduction: Computed tomography (CT) imaging has quickly found its place as a beneficial tool in the detec-
tion of coronavirus disease 2019 (COVID-19). To date, only a few studies have reported the distribution of lung
lesions by segment. This study aimed to evaluate the lobar and segmental distribution of COVID-19 pneumo-
nia based on patients’ chest CT scan. Methods: This was a retrospective study performed on 63 Iranian adult
patients with a final diagnosis of COVID-19. All patients had undergone chest CT scan on admission. Demo-
graphic data and imaging profile, including segmental distribution, were evaluated. Moreover, a scoring scale
was designed to assess the severity of ground-glass opacification (GGO). The relationship of GGO score with age,
sex, and symptoms at presentation was investigated. Results: Among included patients, mean age of patients
was 54.2 ±14.9 (range: 26 - 81) years old and 60.3% were male. Overall, the right lower lobe (87.3%) and the
left lower lobe (85.7%) were more frequently involved. Specifically, predominant involvement was seen in the
posterior segment of the left lower lobe (82.5%). The most common findings were peripheral GGO and consol-
idation, which were observed in 92.1% and 42.9% of patients, respectively. According to the self-designed GGO
scoring scale, about half of the patients presented with mild GGO on admission. GGO score was found to be
equally distributed among different sex and age categories; however, the presence of dyspnea on admission was
significantly associated with a higher GGO score (p= 0.022). Cavitation, reticulation, calcification, bronchiecta-
sis, tree-in-bud appearance and nodules were not identified in any of the cases. Conclusion: COVID-19 mainly
affects the lower lobes of the lungs. GGO and consolidation in the lung periphery is the imaging hallmark in
patients with COVID-19 infection. Absence of bronchiectasis, solitary nodules, cavitation, calcifications, tree-
in-bud appearance, and reversed halo-sign indicates that these features are not common findings, at least in the
earlier stages.

Keywords: COVID-19; pneumonia, viral; tomography, X-ray computed; lung injury

Cite this article as: Haseli S, Khalili N, Bakhshayeshkaram M, Sanei Taheri M, Moharramzad Y. Lobar Distribution of COVID-19 Pneumonia

Based on Chest Computed Tomography Findings; A Retrospective Study. Arch Acad Emerg Med. 2020; 8(1): e55.

∗Corresponding Author: Nastaran Khalili; School of Medicine, Poursina
Avenue, Tehran University of Medical Sciences, Tehran, Iran. Tel: +98-
2122567222, Email: nkhalili71@gmail.com

1. Introduction

An outbreak of pneumonia associated with a novel coron-

avirus, now commonly known as SARS-CoV-2, emerged in
Wuhan, China in December 2019. Patients infected with this

novel virus manifested with symptoms of severe pneumonia,

including fever, fatigue, dry cough, and acute respiratory dis-

tress (1). Since the announcement of COVID-19 by the World

Health Organization (WHO) as a pandemic, elimination of

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S. Haseli et al. 2

this disease has turned into a global health priority (2). How-

ever, without optimizing our knowledge about the efficient

diagnosis and treatment of this disease, increase in infection

and mortality rates is inevitable.

Primary investigations showed that reverse transcriptase-

polymerase chain reaction (RT-PCR) is associated with a low

detection rate at initial presentation, as well as being associ-

ated with several weaknesses such as limited number of kits,

possibility of false negative RT-PCR results, and an undesir-

able delay in diagnosis (3). Thus, it was essential to find a

complementary strategy for time-efficient detection of this

disease. Imaging quickly found its place as a critical tool,

aiding in the diagnosis of patients suspicious for COVID-19

infection. So far, the literature has mainly emphasized on

the role of chest computed tomography (CT) scan for screen-

ing and identifying COVID-19 patients, as well as evaluating

severity and disease progression. In comparison to radiog-

raphy, chest CT scan imaging is a more reliable and sensi-

tive method to diagnose and assess COVID-19, especially in

epidemic regions (4). Evaluating chest CT findings in com-

bination with clinical symptoms and laboratory tests aids in

the medical decision making for COVID-19 disease. In many

regions of Iran, CT scan is more available than RT-PCR, the

current standard confirmatory test of COVID-19. In these re-

gions, chest CT is used as one of the first modalities for ini-

tial evaluation of suspected cases, aiding in prompt manage-

ment before confirmation of diagnosis by PCR (5, 6).

The primary findings of COVID-19 on CT imaging are those

of atypical pneumonia or organizing pneumonia with signifi-

cant overlap with other acute lung injuries such as viral infec-

tion (especially influenza), drug toxicity, vasculitis, and con-

nective tissue disease (7).

In a recent study evaluating prediction models for diagnosis

and prognosis of COVID-19 infection, one of the mentioned

limitations was that reported data from outside of China is

scarce (8). Moreover, although multiple studies have been

published reporting CT-imaging features of COVID-19 pneu-

monia; few studies have investigated the distribution of lung

lesions by segment. In this study, we aim to evaluate the

pattern of COVID-19 pneumonia segmental involvement, by

presenting chest CT-scan findings of 63 patients. Also, we

have designed a novel scoring scale to report the extension

and severity of ground-glass opacification (GGO) in our pa-

tients and assess its association with age, sex, and presenting

symptoms.

2. Methods

2.1. Study design and setting

This was a retrospective study performed on 63 adult pa-

tients with a final diagnosis of COVID-19 who had under-

gone chest CT-scan in a tertiary referral hospital in Tehran,

Iran, from February to March, 2020. All patients had pre-

sented within one week of symptom onset. Diagnosis of

COVID-19 was confirmed by a positive RT-PCR for SARS-

CoV-2 obtained from a nasopharyngeal swab specimen.

The study protocol was approved by the Ethics Commit-

tee of Shahid Beheshti University of Medical Sciences (code:

IR.SBMU.NRITLD.REC.1399.028). Due to the retrospective

nature of the study and no potential risk of harm to patients,

the institutional review board (IRB) of Shahid Beheshti Uni-

versity of Medical Sciences waived written informed consent.

Also, patients’ personal information was de-identified and

kept confidential.

2.2. Participants

Patients were consecutively selected. The exclusion criteria

were age < 18 years, asymptomatic cases with only abnormal

imaging, and history of previous underlying lung disease.

2.3. Data gathering

Demographic data including patients’ age, sex, and initial

symptom at presentation was collected. All patients had un-

dergone at least one non-contrast chest CT-scan with recon-

structions of the volume at 1 mm to 2.5 mm slice thickness

on the first day of admission before receiving any antiviral

treatment. In patients who had more than one chest CT im-

age, only the initial CT scan (on admission) was evaluated in

this study. CT images were reviewed by three board certified

radiologists using a viewing console. All of the radiologists

were blinded to the lab data, clinical features, and patients’

diagnosis. First, imaging findings were interpreted indepen-

dently and then, final decision was made by consensus. No

negative control cases were included in this study.

Imaging features including type of opacity, GGO severity

score, and presence of other abnormal findings (such as

pleural effusion, interlobular septal thickening, cavitation,

reticulation, calcification, bronchiectasis, presence of dis-

crete nodules, and reversed halo sign) were assessed. GGO

was defined as increased lung attenuation with preservation

of bronchial structures and pulmonary vessels, and consoli-

dation was defined as opacification with obscuration of vas-

cular margins and airway walls. Reversed halo sign was con-

sidered a focal rounded GGO surrounded by a ring-like con-

solidation.

2.4. GGO scoring

The extension of GGO was measured based on the following

scoring scale: Involvement of less than 1/3 of segments=1;

Involvement of 1/3 to 2/3 of segments=2; Involvement of

more than 2/3 of segments=3. The greatest score was con-

sidered as the final score.

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3 Archives of Academic Emergency Medicine. 2020; 8(1): e55

Table 1: Patients’ baseline characteristics

Variable Number(%)
Sex
Male 38 (60.3)
Female 25 (39.7)
Age (year)
20-39 12 (19)
40-59 28 (44.4)
≥ 60 23 (36.5)
Symptom at presentation
Dyspnea 33 (52.3)
Fever 45 (71.4)
Cough 30 (47.6)
Headache 6 (9.5)
Myalgia/ fatigue 9 (14.3)
Gastrointestinal symptoms 1 (1.5)

2.5. Statistical Analysis

Categorical variables are reported as number (percentages)

and continuous variables are reported as mean ± standard
deviation (SD). We evaluated the association of segmental

distribution with the age group and sex of patients by con-

ducting Chi-square or Fisher’s exact test. Mann-Whitney U

test or Kruskal-Wallis test was used to assess the relationship

of GGO score with age group, sex, and common initial symp-

toms (fever, dyspnea, and cough) at presentation. All statisti-

cal tests were performed using SPSS v.23 (IBM Inc., Chicago,

IL, USA). Statistical significance was fixed at 0.05.

3. Results

3.1. Baseline characteristics of participants

A total of 63 patients (38 male and 25 female) were included.

Mean age of patients was 54.2 ±14.9 (range: 26-81) years old
(60.3% male). The most common symptoms at presentation

were fever (71.4%), dyspnea (52.3%), and cough (47.6%), re-

spectively. Table 1 shows patients’ baseline characteristics.

3.2. Chest CT findings

All patients had abnormal chest CT scan consistent with vi-

ral pneumonia. Table 2 shows the frequency of lung lesions

based on segmental involvement and also the frequency of

different imaging features. The most common imaging fea-

ture among our patients was peripheral GGO (92.1%) and

consolidation (42.9%). 50.7% of the patients had a mild GGO.

Pleural effusion was seen in only one patient. Tree-in-bud

appearance, cavitation, reversed halo sign, reticulation, cal-

cification, bronchiectasis, and nodules were not identified in

any of the cases.

Overall, lower lobes of both sides were found to be more fre-

quently involved in our patients. Predominant lobar involve-

ment was seen in the posterior segment of the left lower lobe

Table 2: Chest Computed Tomography (CT) findings of COVID-19

patients

Location Number(%)
Right upper lobe
Apical 24 (38.1)
Posterior 35 (55.5)
Anterior 23 (36.5)
Right middle lobe
Lateral 41 (65.1)
Medial 11 (17.5)
Right lower lobe
Superior 49 (77.8)
Posterior 47 (74.6)
Medial 40 (63.5)
Anterior 26 (41.3)
Lateral 45 (71.4)
Left upper lobe
Apicoposterior 22 (34.9)
Anterior 24 (38.1)
Superior lingula 26 (41.2)
Inferior lingula 25 (39.7)
Left lower lobe
Superior 39 (61.9)
Anteromedial 22 (34.9)
Lateral 48 (76.2)
Posterior 52 (82.5)
Imaging Characteristics
Bilateral 53 (84.1)
Peripheral GGO 58 (92.1)
Consolidation 27 (42.9)
Peri-bronchovascular GGO 13 (20.6)
Sub pleural band 6 (9.5)
Interlobular septal thickening 4 (6.3)
Pleural effusion 1 (1.5)
GGO severity
Mild 32 (50.7)
Moderate 20 (31.7)
Severe 11 (17.4)
GGO: ground-glass opacification.

(82.5%) followed by the superior segment of the right lower

lobe (77.8%) and the lateral segment of the left lower lobe

(76.2%), respectively. On the other hand, medial segment

involvement of the right middle lobe was the least reported

finding (17.5%).

3.3. Segmental involvement based on age and sex

The inferior lingula (p = 0.012) and the apicoposterior seg-

ment of the left lower lobe (p = 0.045) showed a significantly

higher involvement among females. Moreover, the anterior

(p = 0.017) and posterior (p = 0.043) segment of the right up-

per lobe, the lateral (p = 0.019) and medial (p = 0.015) seg-

ment of the right lower lobe, and the superior segment of the

left lower lobe (p = 0.029) were more commonly involved in

patients ≥60 years old.

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S. Haseli et al. 4

3.4. GGO score

GGO score was found to be equally distributed among sex (p

= 0.098) and age (p = 0.846) categories. Existence of dysp-

nea at presentation was significantly associated with a higher

GGO score (p= 0.022)

4. Discussion

In this study we have reported chest CT imaging results of

patients with laboratory-confirmed COVID-19 pneumonia.

Our results revealed that the most common finding was pe-

ripheral GGO followed by consolidation. Cavitation, reticu-

lation, calcification, bronchiectasis, tree-in-bud appearance,

reversed halo-sign, nodules and pleural effusion were not

common findings in the chest CT scan of our patients. In

terms of segmental distribution, most commonly, involve-

ment was seen in the posterior segment of the left lower lobe.

Moreover, certain segments and lobes were more frequently

involved based on age and sex of patients.

The results of our study indicated that, overall, lower lobes

of the lungs were more frequently involved. Specifically, the

posterior segment of the left lower lobe, the superior seg-

ment of the right lower lobe and the lateral segment of the

left lower lobe were predominantly involved. Consistent with

our findings, a recent study by Song et al., also found lower

lobe involvement in 90% of COVID-19 patients (9). Another

study also pointed to the same finding that peripheral and

lower lobe involvement is more common (10). Yang et al. re-

ported the posterior basal segments of the right and left lower

lobes as the most involved sites in 102 patients with COVID-

19 pneumonia (11). However, they did not report the differ-

ence of segmental distribution with respect to age and sex.

Our study demonstrated that certain segments and lobes are

more frequently involved in females or older patients. This

might provide clue to radiologists to pay particular attention

to these segments when reviewing the imaging of these pop-

ulations; yet, more studies are warranted for a definite con-

clusion. We observed that the majority of patients presented

with peripheral distribution of lung lesions in imaging. This

observation was previously reported by several other studies

(10, 12, 13). However, one study has reported peripheral dis-

tribution in only 33% of investigated patients (14). Although

various CT findings were observed in our cases, almost all

cases had bilateral GGO in sub-pleural areas. It seems that

exudative fluid accumulation within the alveolar space is the

cause of this multi-lobar appearance. Since the predominant

pattern is GGO, the superiority of CT scan over chest radio-

graphy is justified due to its higher resolution. It is assumed

that low-dose CT scan might also be helpful; not only for di-

agnosis, but also for reducing radiation exposure, although

further studies are needed (5). The majority of studies pub-

lished so-far have also mentioned GGO, consolidation, and

bronchial dilation as the main characteristic findings (4, 5,

14-19). This pattern of involvement is not pathognomonic

and resembles that of other viral pneumonia, in particular,

influenza. Other pathologies such as aspiration pneumonia

also present with bibasilar consolidation similar to COVID-

19 infection. Similar radiologic patterns are also found in

interstitial lung diseases, such as organizing pneumonia or

non-specific interstitial pneumonitis (NSIP), in which pre-

dominant peripheral GGO or diffuse GGO is observed. Bi-

lateral patchy areas of GGO are also found in conditions such

as lung contusion in the setting of severe chest trauma (18,

20, 21). Thus, decision making based on appropriate clinical

findings is crucial for correct diagnosis.

There was no sign of cavitation, reticulation, calcification,

bronchiectasis, tree-in-bud appearance, reversed halo-sign,

and nodules in any of our patients and only one patient had

pleural effusion. Interestingly, the absence of these imaging

features in COVID-19 has also been demonstrated by several

other studies (4, 13, 14, 18). However, it is probable that these

features develop in long-term, and thus, it is not possible to

reach a conclusion through investigation of early imaging.

Reversed halo sign is usually present in invasive fungal infec-

tions such as aspergillosis, vasculitis and even tumor metas-

tasis; however, viral infection is also another cause of this ap-

pearance. Although this sign has been seen in some COVID-

19 cases, it is considered a late finding (5, 18).

Our results revealed that less than one-fifth of patients

demonstrate severe GGO on admission. It has been shown

that after two weeks from initial symptoms, as consolidation

begins to resolve, GGO becomes more extensive (15). This

might explain the low rate of severe GGO observed in this

study, as our patients were investigated within one week of

symptom onset. We observed a significant association be-

tween elevated GGO score and presence of dyspnea at pre-

sentation, although it did not correlate with other symptoms

such as cough and fever. Also, severity of GGO was not af-

fected by patients’ age and sex. Notably, Zhou and colleagues

also reported that dyspnea on admission was associated with

increased odds of death, while fever and cough were not (22).

Previous studies have stated that increase in the extent and

density of GGO on CT can be used as a prognostic marker

(13, 14). Several studies have displayed a significant associa-

tion between higher CT score (based on extent of lung opaci-

fication) and a more severe course of COVID-19 disease (11,

23-25). In a recent study by Song et al., patients were classi-

fied into severe and non-severe groups based on clinical and

imaging criteria. In this study, a self-designed CT scoring sys-

tem was used as a marker for assessing the severity of the

disease, showing a markedly higher CT score among patients

with severe disease. Consistent with our study, they did not

find a significant association between sex and disease sever-

ity; however, older cases were more likely to develop severe

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5 Archives of Academic Emergency Medicine. 2020; 8(1): e55

illness (23). Thus, although we were not able to measure the

relationship between GGO severity and disease outcome, the

significant association of dyspnea with a higher GGO score

might indicate that the existence of this symptom at presen-

tation indicates worse prognosis.

This study had various limitations. First, it only included

adult cases. Second, it had a relatively small sample size.

Moreover, we only investigated the initial CT-scans obtained

on admission and findings were not controlled in terms of

the exact number of days after symptom onset (15, 26). The

retrospective nature of the study might have also introduced

selection bias. Another major flaw was that in the major-

ity of cases, lab tests and patient outcome were not avail-

able. In addition, evaluation of features such as cavitation

and pleural effusion requires follow-up. Thus, larger multi-

center cohorts along with follow-up and complete data are

necessary to validate the results. In conclusion, consistent

with previous studies, we also determined that COVID-19

mainly affects the lower lobes of the lungs. Our study also

confirmed that ground-glass opacities and consolidation in

the lung periphery is the imaging hallmark in COVID-19 in-

fection. Bronchiectasis, tree-in-bud appearance, discrete

pulmonary nodules, cavitation, calcifications, reversed halo-

sign and pleural effusions were uncommon findings. Con-

clusively, recognition of this pattern of chest involvement, in

the proper clinical setting, is highly suggestive of COVID-19

infection. Furthermore, the association observed between

dyspnea and extensive GGO on imaging might indicate that

presentation with dyspnea is associated with worse progno-

sis compared to cough and fever. This finding could help

medical staff with limited healthcare resources to predict

cases with a possible worse outcome when triaging patients.

Overall, imaging is valuable not only for early suspicion of

the disease, but also for follow-up and evaluation of disease

severity; however, further investigations are needed to shed

light on the radio-clinical correlation of this disease.

5. Declarations

5.1. Acknowledgements

The authors wish to thank Dr. Nasrin Boroumandnia, PhD,

for providing statistical assistance.

5.2. Author contribution

S.H. conceived the original idea and supervised the study.

N.K. conducted the analysis and drafted the manuscript.

S.H., M.B., and M.S. contributed to data collection and

performed critical revision. Y.M participated in data collec-

tion. All authors read and approved the final version of this

manuscript.

Authors ORCIDs
Sara Haseli: 0000-0003-0300-5491

Nastaran Khalili: 0000-0001-8078-3591

Mehrdad Bakhshayeshkaram: 0000-0003-4864-6161

Morteza Sanei-Taheri: 0000-0002-8881-9058

Yashar Moharramzad: 0000-0002-5986-3754

5.3. Funding/Support

This research did not receive any specific grant from funding

agencies in the public, commercial, or not-for-profit sectors.

5.4. Conflict of interest

None.

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	Introduction
	Methods
	Results
	Discussion
	Declarations
	References