Departments of 1Internal Medicine and 3Physiology, Sultan Qaboos University, Muscat, Oman; 2Department of Clinical Physiology, Sultan Qaboos 
University Hospital, Muscat, Oman
*Corresponding Author’s e-mail: deepali@squ.edu.om

Pulmonary Function Test Outcomes in Adult 
Omani Patients

Preliminary findings from a single-centre study

Anan Al Jabri,1 Ruqaiya Al Hinai,1 Ruth Balaji,2 Sharifa Al Harrasi,2 *Deepali S. Jaju,2 Hajar Al Rajaibi3

Sultan Qaboos University Med J, August 2022, Vol. 22, Iss. 3, pp. 400–404, Epub. 25 Aug 22
Submitted 13 Oct 20
Revisions Req. 7 Dec 20, 27 Jan & 21 Mar 21; Revisions Recd. 30 Dec 20, 21 Feb & 11 Apr 21
Accepted 5 May 21

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

https://doi.org/10.18295/squmj.6.2021.088

BRIEF COMMUNICATION

abstract: Objectives: This study aimed to document the distribution of PFT outcomes among adult Omani 
patients. There is limited information regarding the distribution of pulmonary diseases (PD) in Oman. Pulmonary 
function test (PFT) outcome patterns could indicate an indirect distribution of PD. Methods: This retrospective 
cross-sectional study was conducted from January to December 2015 at a tertiary hospital in Oman. A total of 1,118 
adults referred for PFTs during this period were included. Results: There were 605 (54.1%) female and 513 (45.9%) 
male patients. The mean age of the patients was 47.11 ± 18.1 years. Most patients underwent spirometry with 
reversibility (36.8%) or full lung function testing with reversibility (29.7%). Among the 1,064 patients with conclusive 
PFT outcomes, 39.9% had normal findings, 26.1% had obstructive defects, 19.6% demonstrated restrictive defects 
and 10.6% had mixed obstructive/restrictive defects. Conclusion: This study generated important preliminary data 
regarding PFT outcomes (defects) in Omani patients.

Keywords: Pulmonary Function Tests; Spirometry; Pulmonary Diseases; Asthma; Chronic Obstructive Pulmonary 
Disease; Oman.

According to the world health organiz- ation, chronic obstructive pulmonary disease (COPD) will become the third leading cause 
of death by 2030.1 It is therefore essential that all 
countries work towards practicing evidence-based 
policymaking and resource planning in order to tackle 
the increasing burden of non-communicable diseases 
such as bronchial asthma and COPD. Although the 
prevalence of chronic pulmonary diseases in the 
Eastern Mediterranean region (EMR) is rising, the 
overall research output in this field is still low.2–4 A 
recent systematic review was able to substantiate 
this finding by noting a similar under-representation 
of data from the EMR and the Southeast Asian and 
African regions as well.5 

Pulmonary diseases (PDs) can be monitored and 
distinguished using pulmonary function tests (PFTs).6,7 
Generally, PDs can be classified into obstructive or 
restrictive diseases. Obstructive diseases—asthma, 
chronic bronchitis and emphysema—are characterised 
by airflow limitations due to narrowing of the anat- 
omic airway or loss of elastic recoil, thereby leading to 
partial or complete obstruction and increased resistance 
to air movement.8 Restrictive diseases, including sarcoi- 
dosis, pneumoconiosis, acute respiratory distress 
syndrome and interstitial fibrosis of unknown aetiology, 
are all denoted by reduced total lung capacity. This is 
primarily due to factors such as pleural diseases, obesity, 
interstitial lung disease (ILD) or chest wall disorders 
that restrict the expansion of the lung parenchyma. In 

certain cases, obstructive and restrictive lung diseases 
can overlap as well.6 

In Oman, there is limited information with respect 
to the burden of common respiratory diseases in the 
country. In particular, COPD remains underdiagnosed, 
undertreated and limited data are available regarding 
rates of restrictive diseases or asthma in adults.9,10 
PFT outcomes are typically corroborated by referring 
patients to clinicians to help confirm the presence of 
PDs. This study aimed to document the distribution 
of PFT outcomes as obstructive, restrictive and mixed 
obstructive/restrictive defects in adult Omani patients 
referred for PFTs to a tertiary hospital in Muscat, 
Oman. 

Methods

This retrospective study of PFTs was conducted at 
a tertiary care hospital in Muscat from January to 
December 2015. All adult Omani patients referred 
by clinicians for PFTs to assess lung function were 
included in the study.

Patients underwent either spirometry using 
the Platinum Elite™ Body Plethysmograph (MGC 
Diagnostics Corp., Saint Paul, Minnesota, USA) and 
the PowerCube® System (Ganshorn Medizin Electronic, 
Niederlauer, Germany) or full lung function (FLF) 
testing using the PowerCube® System (Ganshorn 
Medizin Electronic). In the pulmonary laboratory of the 

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


Anan Al Jabri, Ruqaiya Al Hinai, Ruth Balaji, Sharifa Al Harrasi, Deepali S. Jaju and Hajar Al Rajaibi

Brief Communication | 401

current study centre, spirometry includes estimation 
of forced vital capacity and forced expiratory volume 
in the first second, while FLF includes spirometry and 
estimations of lung volumes and diffusion functions. 
Reference equations standardised to an Asian 
population were used to estimate predicted values.6 
All patients were instructed to avoid bronchodilators 
the morning prior to the test to avoid altering any 
baseline spirometry indices. 

All of the PFT results were interpreted by a 
specialist according to the criteria of the American 
Thoracic Society and European Respiratory Society.6 
Information regarding the patients’ sociodemographic 
characteristics, referring physician, hospital, reasons 
for referral and PFT outcomes was collected. The PFT 
outcomes were categorised into the following groups: 
normal findings, obstructive defects, restrictive 
defects, mixed obstructive/restrictive defects and 
isolated diffusion impairment. The patients with 
inconclusive findings were excluded from the analysis 
of PFT outcomes. 

Data were analysed using the Statistical Package 
for the Social Sciences (SPSS), Version 22.0 (IBM 
Corp., Armonk, New York, USA). The results were 
presented using descriptive statistics including 
frequencies and percentages and associations between 
gender and type of test, referring hospital, specialty 
and PFT outcomes were assessed using a Chi-squared 
test. Gender differences in age and body mass index 
(BMI) were calculated using student’s t-test.

Ethical approval for this study was obtained 
from the Medical Research & Ethics Committee of 
the College of Medicine & Health Sciences, Sultan 
Qaboos University, Muscat, Oman (MREC 1326).

Results

A total of 1,118 adult patients underwent PFTs during 
the study period. Among these patients, 513 (45.9%) 
were male and 605 (54.1%) were female. Compared 
to female patients, male patients were significantly 
younger (P = 0.007) and had lower BMI values (P 
<0.001). Most patients underwent spirometry with 
reversibility (36.8%), followed by full lung function 
testing with reversibility (29.7%). The majority were 
referred from a national-level tertiary hospital (76.4%). 
Over half of the sample (52.4%) was referred from the 
pulmonary medicine department while the remaining 
patients were referred from other specialties [Table 1].

A total of 890 patients (79.6%) were referred 
for PFTs due to respiratory symptoms or conditions 
including asthma (41.2%), shortness of breath 
(17.6%), cough (15.5%), ILD (8.9%), COPD (8.2%), 
bronchiectasis (7.8%), wheezing (4.1%), obstructive 
sleep apnoea (2.5%), sarcoidosis (1.9%), systemic 
lupus erythematosus (1.3%), cystic fibrosis (0.4%) 
and lung carcinoma (0.3%). The remaining 228 
patients (20.4%) were referred for other conditions, 
including presurgical assessment (11.8%), pre/post-

Table 1: Characteristics of adult Omani patients referred for pulmonary function tests to a tertiary hospital in Muscat, 
Oman (N = 1,118)

Characteristic n (%) P value

Total Male (n = 513) Female (n = 605)

Mean age in years ± SD 47.11 ± 18.1 46.57 ± 18.8 47.57 ± 17.5 0.007

Mean BMI in kg/m2 ± SD - 26.95 ± 7.2 30.64 ± 8.80 <0.001

Type of PFT performed 0.061

Baseline spirometry 107 (9.6) 39 (36.4) 68 (63.6)

Spirometry with reversibility 411 (36.8) 179 (43.6) 232 (56.4)

Baseline full lung function testing 268 (24.0) 131 (48.9) 137 (51.1)

Full lung function testing with reversibility 332 (29.7) 164 (49.4) 168 (50.6)

Referring hospital 0.001

National tertiary hospital 854 (76.4) 356 (41.7) 498 (58.3)

Other hospitals or health centres 264 (23.6) 157 (59.5) 107 (40.5)

Referring specialty 0.002

Pulmonary medicine 586 (52.4) 243 (41.5) 343 (58.5)

Other* 532 (47.6) 270 (50.8) 262 (49.2)

SD = standard deviation; BMI = body mass index; PFT = pulmonary function test. *Including cardiology, internal medicine, haematology, oncology, 
rheumatology, immunology, surgery and family medicine specialties.



Pulmonary Function Test Outcomes in Adult Omani Patients 
Preliminary findings from a single-centre study

402 | SQU Medical Journal, August 2022, Volume 22, Issue 3

bone marrow transplant assessment (5.5%), genetic or 
immunological diseases (3%), pre/post-chemotherapy 
assessment (2.1%) and pre-hyperbaric oxygen therapy 
assessment (0.2%). A total of 271 patients (24.2%) 
suffered from two or more conditions for a PFT 
referral. 

Overall, the PFT findings for 54 patients (4.8%) 
were inconclusive. Of the remaining 1,064 patients 
(95.2%) with conclusive results, 425 (39.9%) had 
normal PFT findings. However, 311 patients out of 425 
suffered from respiratory symptoms or conditions. A 
total of 278 patients (26.1%) had obstructive defects, 
209 (19.6%) had restrictive defects, 113 (10.6%) had 
mixed obstructive/restrictive defects and 39 (3.7%) 
had isolated diffusion impairment. A total of 48.9% 
(n = 136/278) of obstructive defects were evident 
from spirometry with reversibility. About 60.8% (n 
= 127/209) of the restrictive defects were identified 
through FLF testing; restrictive signs were evident 
through spirometry in 82 cases (39.2%) [Table 2]. 

The frequency of isolated diffusion impairment 
was significantly higher in females compared to males 
(χ2 = 23.21; P <0.001) [Table 3]. 

Discussion 

The current study aimed to consolidate relevant 
information regarding the obstructive and restrictive 
defects as outcomes of PFTs among Omani adults. The 
distribution of PFT defect patterns could indirectly 
indicate the distribution of PD patterns. It must be 
reiterated that although the majority of PFTs were 
done for respiratory symptoms or conditions, one 
fifth of the PFTs were provided for preoperative 
assessment, obesity, pre-drug and pre-bone marrow 
studies in which the presence of any defect may not 
have indicated a respiratory disease.

 Researchers have proposed that spirometry 
can be incorporated into the assessment of airflow 
obstruction; however, estimates of spirometry-
assessed COPD burden from epidemiological studies 
are often inconsistent due to variations in methodology 
and use of different spirometry cut-off values for 
interpretation.11 In the current study, spirometry was 
considered in order to document obstructive defects 
using standard guidelines.6 Alzaabi et al. conducted a 
review of prevalence studies from the EMR and Middle 
Eastern and North African regions, excluding Oman;12 
the researchers noted that the prevalence of COPD in 
these regions was likely underestimated due to an over-
reliance on clinical diagnosis rather than spirometry 
findings or international diagnostic guidelines. In the 
current study centre, patients were usually referred 
for PFTs by a clinician based on suspicion of an 
obstructive disease. Spirometry indices allow for 
the objective assessment of obstructive impairment 
compared to reliance on a purely physician-diagnosed 
conclusion. In the Gulf region, lung function testing 

Table 2: Outcomes of various types of pulmonary function tests among adult Omani patients referred to a tertiary 
hospital in Muscat, Oman (n = 1,064)*

Outcome Type of PFT performed, n (%)

Baseline 
spirometry

Spirometry with 
reversibility

Baseline full lung 
function testing

Full lung function testing 
with reversibility

Total

Normal findings 66 (15.5) 136 (32.0) 140 (32.9) 83 (19.5) 425 (39.9)

Obstructive PD 2 (0.7) 136 (48.9) 15 (5.4) 125 (45.0) 278 (26.1)

Restrictive PD 31 (14.8) 51 (24.4) 67 (32.1) 60 (28.7) 209 (19.6)

Combined obstructive/ 
restrictive PD

3 (2.7) 61 (54.0) 7 (6.2) 42 (37.2) 113 (10.6)

Diffusion impairment N/A N/A 25 (64.1) 14 (35.9) 39 (3.7)

PFT = pulmonary function test; PD = pulmonary disease; N/A = not applicable. *Excluding patients with inconclusive findings.

Table 3: Gender differences according to pulmonary func- 
tion test outcomes among adult Omani patients referred 
to a tertiary hospital in Muscat, Oman (n = 1,064)*

Outcome 
of PFT

n (%) χ2 P 
value

Total Male Female

Normal 
findings

425 
(39.9)

184 
(43.3)

241 
(56.7)

23.21 <0.001

Obstructive 
PD 

278 
(26.1)

142 
(51.1)

136 
(48.9)

Restrictive 
PD

209 
(19.6)

102 
(48.8)

107 
(51.2)

Combined 
obstructive/
restrictive 
PD

113 
(10.6)

59 
(52.2)

54 
(47.8)

Diffusion 
impairment 

39 
(3.7)

7 
(17.9)

32 
(82.1)

PFT = pulmonary function test ; PD = pulmonary disease. *Excluding 
patients with inconclusive findings.



Anan Al Jabri, Ruqaiya Al Hinai, Ruth Balaji, Sharifa Al Harrasi, Deepali S. Jaju and Hajar Al Rajaibi

Brief Communication | 403

is generally underutilised with one study reporting 
that up to 66% of patients had never undergone a 
PFT.3 Moreover, peak expiratory flow is rarely used as 
an indicator of breathing difficulty.13 Classifying PDs 
into restrictive, obstructive or other categories is only 
possible with full lung function testing. The current 
study utilised data based on both spirometry and FLF 
testing, including the assessment of lung volume and 
diffusion capacity.

The present study showed that obstructive defects 
were most prevalent, followed by restrictive defects in 
this limited sample. In 2012, the World Health Survey 
reported that the prevalence of physician-diagnosed 
asthma in the EMR region was considerably lower at 
2.93%; however, data for this region were limited to 
a few countries, including Pakistan (3.12%), United 
Arab Emirates (5.30%), Morocco (2.76%) and Tunisia 
(2.74%).14 A recent meta-analysis found that the 
pooled crude prevalence of spirometry-defined COPD 
in the EMR was 13.20%.5 In their study, Masjedi et al. 
reported the pooled prevalence of asthma and COPD 
in the EMR to be 9.38% and 5.39%, respectively.4 

In the present study, 39.9% of patients with 
conclusive PFT results demonstrated normal findings 
despite having been referred for respiratory symptoms 
or conditions. A possible reason behind this could be 
the fact that respiratory symptoms of such patients 
were being controlled with various pharmaceutical 
treatments or that the PFTs were performed to assess 
presenting symptoms. Further research to explore 
reasons for this finding is recommended since this was 
beyond the scope of the current study. In addition, a 
significant association was noted between pulmonary 
defect patterns and gender. In particular, the frequency 
of obstructive and mixed obstructive/restrictive 
pulmonary defects were significantly higher in males 
compared to females, whereas the opposite was true 
for isolated diffusion impairment. The reasons for 
these associations are unclear. Isolated diffusion 
impairment could be an indicator of restrictive 
pulmonary disease, suggesting an early lung disease or 
an infiltrative process. However, the restrictive defects 
and low diffusion shown in this study are similar to 
those from other studies in the region.15,16 

A major limitation of the current study was that 
pulmonary defect patterns could not be meaningfully 
considered as PD patterns. Moreover, isolated diffusion 
impairment can be documented in non-pulmonary 
diseases such as cardiac failure; however, this issue was 
not considered in the current research. Furthermore, 
the present findings cannot be generalized to the 
country as the entire study sample belonged to a single 
center.

Conclusion

Given the recent increase in the prevalence COPD 
in the EMR, the present study was conducted to 
expand the availability of prevalence data in the 
aforementioned region. Among adult Omanis referred 
to a tertiary hospital for PFTs, obstructive defects 
were found to be present in one-fourth of the sample. 
Restrictive defects were observed in one-fifth of the 
sample while mixed obstructive restrictive defects 
were found in one-tenth of the sample. Finally, 4% of 
the sample had isolated diffusion impairment among 
the referred patients. These preliminary findings 
of distribution of defects could indicate an indirect 
distribution of PDs in this particular set-up. These 
statistics also provide baseline evidence and estimates 
for sample size calculations for future researchers.

a u t h o r s’ c o n t r i b u t i o n
DSJ conceptualised and designed the study and drafted 
the manuscript. AAJ and RAH collected and compiled 
the data. RB and SAH provided technical assistance for 
spirometry procedure. DSJ and AAJ analysed the data 
and interpreted the results. HAR critically reviewed 
the manuscript. All authors approved the final version 
of the manuscript. 

c o n f l i c t o f i n t e r e s t
The authors declare no conflicts of interest. 

f u n d i n g

No funding was received for this study.

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