Ahmed P, Eaty M, Alam N, Anthony L, Yasmin N. Respiratory symptoms among urban traffic 
policemen in Bangladesh: A cross-sectional study (Original research). SEEJPH 2022, posted: 19 
June 2022. DOI: 10.11576/seejph-5534 

 

P a g e  1 | 13 

 ORIGINAL RESEARCH   

 
Respiratory symptoms among urban traffic policemen in Bangladesh: A 

cross-sectional study 
 

 
Parvez Ahmed1, Mahim Eaty2, Nazmul Alam3, Leela Anthony4, Nawzia Yasmin1 

 
1 State University of Bangladesh, Dhaka, Bangladesh; 
2 PLAN International, Bangladesh; 
3 Asian University for Women, Chittagong-4000, Bangladesh; 
4 AIMST University, Kedah, Malaysia.  
 
 
 
Corresponding author: Dr. Parvez Ahmed MBBS MPH Ph.D.; 
Address: State University of Bangladesh, 77 Satmasjid Road, Dhanmondi, Dhaka -1205, 
Bangladesh;  
Telephone: +88 01713 485394;  
Email: parvez.epidemiology@gmail.com 
 
 
 
  



 

Ahmed P, Eaty M, Alam N, Anthony L, Yasmin N. Respiratory symptoms among urban traffic 
policemen in Bangladesh: A cross-sectional study (Original research). SEEJPH 2022, posted: 19 
June 2022. DOI: 10.11576/seejph-5534 

 

P a g e  2 | 13 

Abstract 
 
Aim: There is accumulating evidence that roadside pollution is detrimental to health. This study 
aims to compare the risk of adverse respiratory symptoms in different categories of traffic police 
including traffic constables, sergeants, and inspectors working in the polluted environment.  
 
Methods: The study population consisted of 369 randomly selected traffic police personnel from 
the city of Chittagong in Bangladesh. Information on their occupation and respiratory health 
symptoms were collected. The health outcomes were coughing, coughing sputum, coughing up 
blood, shortness of breathing, wheezing, and chest pain with deep breathing. 
  
Results: The risk of coughing [adjusted Odds Ratio (AOR) = 4.469, 95% CI=1.265-15.793], 
coughing sputum [AOR= 3.687, 95% CI= 1.004 -13.540], coughing up blood [AOR=1.040, 95% 
CI=0.227-6.162], shortness of breathing [AOR=3.937, 95% CI=1.069-14.500], wheezing [AOR= 
2.464, 95% CI= 0.613-9.906] and chest pain with deep breathing [AOR=2.163,95% CI= 0.560-
8.349] was higher in traffic constables on comparison to inspectors. In sergeants odds increased 
for coughing up blood [AOR=1.102, 95% CI= 0.283-4.286] and wheezing [AOR=1.260, 95% CI= 
0.304-5.229]. 
 
Conclusion: There was a substantial difference in the risk of studied respiratory symptoms 
between different categories of traffic police jobs.  
 
Keywords: Bangladesh, epidemiology, occupational and environmental health, respiratory 
symptoms, traffic police.  
 
Conflicts of interest: None declared. 
  



 

Ahmed P, Eaty M, Alam N, Anthony L, Yasmin N. Respiratory symptoms among urban traffic 
policemen in Bangladesh: A cross-sectional study (Original research). SEEJPH 2022, posted: 19 
June 2022. DOI: 10.11576/seejph-5534 

 

P a g e  3 | 13 

Introduction 
Environmental exposures during work 
activities can affect health. Traffic police 
personnel spend a long duration of time by 
roadside due to the nature of their job and are 
exposed to roadside vehicular emissions that 
can cause both long- and short-term health 
problems. Previously conducted 
epidemiological studies reported the 
association of occupational health hazards 
such as environmental pollution due to 
vehicular emission and adverse respiratory 
health outcomes in traffic police personnel 
(1,2).  
Road traffic generates volatile organic 
compounds, suspended particulate matter, 
oxides of nitrogen, sulfur oxides, and carbon 
monoxide which impose a wide range of 
adverse health effects on the exposed 
population (3). Vehicular emission-related 
deterioration in air quality has been shown to 
produce significant morbidity and mortality 
by affecting multiple organs and systems (4). 
These pollutants cause respiratory 
morbidities, reduced lung function, and 
chronic exposure may even cause lung 
cancers and COPD (5,6).  
Bangladesh, one of the most densely 
populated countries in the world, is going 
through economic transition and rapid 
urbanization in recent years. Major cities of 
Bangladesh, particularly Chittagong and 
capital city Dhaka is congested with a large 
number of motor vehicles, including local 
transport buses, long route buses, diesel-run 
local passenger vans, passenger cars, 
commercial vans, private cars, compressed 
natural gas (CNG)-run auto-rickshaws, and 
heavy-duty diesel-powered lorry trucks for 
the shipment of garment products to the 
Chittagong port. Most of these vehicles are 
run by high-sulfur diesel (7). The air quality 
of Dhaka is considered to be one of the most 
polluted in the world, at 82 µg/m3 annual 
average PM2.5 concentration from a variety 
of pollution sources and ranked as the third 

most polluted city among the megacities with 
at least 14 million people (8). According to 
the Bangladesh Road and Transport 
Authority (BRTA), there were 504,130.000 
registered motor vehicles in 2019 in 
Bangladesh, most of which were decades old 
and unfit for the road, polluting the 
environment severely (9). Exhaust and fumes 
of these vehicles are a major source of NO2 
emissions and CO emissions in Chittagong 
and Dhaka, accounting for some 58.6% of the 
total annual NO2 emissions and 40.5% of the 
total CO emissions (10). The concentration of 
PM particles, SO2, Ozone, Carbon monoxide 
in some cities of Bangladesh including 
Chittagong city has been found well above 
the recommended level of the World Health 
Organization (WHO) (11,12).  
Despite the high pollution and vulnerability 
of the traffic police of  Bangladesh, 
there are hardly any studies that have been 
done on them. Therefore, this study aims to 
assess the risk of adverse respiratory health 
outcomes in different categories of traffic 
police including constables, sergeants, and 
inspectors of Bangladesh.  
 
Methods 
 

Study setting 
A cross-sectional study was conducted in 
Chittagong city of Bangladesh. The data 
collection process was carried out from June 
1st, 2018 to August 31st, 2018. 
 

Study population and work environment 
Study participants were traffic police 
personnel working in different areas in the 
city of Chittagong of Bangladesh. In 
Bangladesh, traffic police constables, by job 
definition are assigned in traffic control and 
management at traffic junctions, traffic 
inspectors coordinate scheduled service 
within assigned territory of streetcar, bus, or 
railway transportation system with the 
periodical investigation in schedule delays 
for accidents, equipment failures, complaints 



 

Ahmed P, Eaty M, Alam N, Anthony L, Yasmin N. Respiratory symptoms among urban traffic 
policemen in Bangladesh: A cross-sectional study (Original research). SEEJPH 2022, posted: 19 
June 2022. DOI: 10.11576/seejph-5534 

 

P a g e  4 | 13 

and files written report, and sergeants 
perform patrol duties to address traffic 
infringement or violation and is responsible 
for the initial scene management of incidents. 
The road traffic is very dense at most of the 
traffic junctions in Chittagong city either 
because of nonfunctional traffic lights or due 
to traffic snarl-ups. Traffic police personnel 
aged 20 years or over were invited for the 
study. 
 
Determination of sample size 
The sample size for the prevalence of the 
respiratory disease among traffic police was 
determined using single proportion formula 
with the following assumptions: level of 
significance (α) =5%, (at a confidence level 
of 95%), p= 68% (According to a study done 
in India, 68% traffic police personnel had 
frequent coughing and other complications 
with various percentages due to occupational 
exposure. India was considered for 
expectation prevalence for this study since 
India and Bangladesh are located in the same 
geographical region and both countries share 
similar types of exposures) (13).  
Z value=1.96, marginal error d=7% of p,  
 n= z2 * p * (1-p)/d=369 
A simple random sampling technique was 
used to collect police personnel following 
STROBE guidelines.      
 
Variables 
The survey about respiratory symptoms in 
traffic policemen was based on a 
questionnaire adapted from the Standard 
Respirator Medical Evaluation Questionnaire 
(14). The questionnaire covered the 
following respiratory symptoms: coughing, 
coughing sputum, wheezing, coughing up 
blood, shortness of breathing, and chest pain 
with deep breathing. Respiratory symptoms 
were recorded as being present if a 
participant answered, "Yes", to a relevant 
question. The participants were provided 
with explanations about each respiratory 

symptom. The questionnaire also included 
socio-demographic information of the 
participants including age, height, weight, 
marital status, job information including job 
title, preventive measures such as using the 
face mask, information about behavioral 
factors including smoking and workout habit 
(exercise), and history of a previous 
respiratory disease diagnosed by a doctor 
including Asthma, Tuberculosis, Chronic 
Bronchitis, Emphysema, Pneumonia, 
Pneumothorax, Cancer, Tuberculosis, chest 
injury or surgery, broken ribs, allergic 
reaction interfering with breathing. 
Three trained data collectors went to the site 
with the questionnaire after obtaining 
approval from the local police authority and 
conducted face-to-face interviews. 
Validation of respiratory symptoms was done 
by a registered medical doctor (first author). 
 
Research approach  
The research approach of the present study 
was the identification of the type of industries 
where there is an excess risk of adverse health 
outcomes. Focus on workers in this 
occupation can lead to recognition of one or 
several factors, which may have independent 
or synergic effects (15).  
 
Data management and analysis  
All data were recorded and analyzed in 
Statistical Package for the Social Sciences 
(SPSS) version 22. 
Traffic inspectors were used as a reference 
category to compare the risk of respiratory 
health outcomes among traffic police as 
traffic inspectors are considered least 
exposed to roadside pollution. To determine 
the risk of respiratory outcomes among 
traffic police, a two-step statistical model 
approach was undertaken. First, the 
prevalence of adverse respiratory health 
outcomes in different traffic police by job 
title was measured. Second, the risk of 
adverse respiratory outcomes was compared 



 

Ahmed P, Eaty M, Alam N, Anthony L, Yasmin N. Respiratory symptoms among urban traffic 
policemen in Bangladesh: A cross-sectional study (Original research). SEEJPH 2022, posted: 19 
June 2022. DOI: 10.11576/seejph-5534 

 

P a g e  5 | 13 

to different traffic jobs by job title. Odds 
Ratio with 95% confidence interval (CI) was 
the measure of association. Logistic 
regression analysis was conducted to 
estimate adjusted Odds Ratio where 
covariates such as age, BMI, education, 
smoking status, use of mask, workout 
(exercise), previous respiratory disease were 
adjusted for each of the other. 
 
Ethical considerations 
The study was approved by the Research and 
Ethics Committee of the Asian University for 
Women, Bangladesh. Informed verbal 
consents of the participants were obtained 
before data collection. 
 
Results 

Table 1 describes the sample characteristics 
according to the job title. Out of a total of 369 
traffic police personnel, 25 (6.7%) were 
inspectors, 145 (39.3%) were sergeants, and 
199 (53.9%) were constables. There was a 
substantial difference was in the distribution 
of socio-demographic determinants, which 
could be partly explained by relatively small 
numbers in some groups. For example, the 
prevalence of using masks at the workplace 
was 16.0% in traffic inspectors, 34.5% 
among sergeants, and 13.6% among 
constables. However, the distribution of 
workout habits and smoking status was found 
almost the same in all the occupational 
groups.  
 

Table 1. Characteristics of participants according to job title (N=369) 
 

Variable 
Job title  

Inspector  
(n/%) 

Sergeant  
(n/%) 

Constable  
(n/%) 

Total  
(n/%) 

Age (years) 

<30 0 (0.0%) 4 (2.9%) 21 (23.6%) 25 (6.8%) 
30-40 48 (33.8%) 86 (62.3%) 11 (12.4%) 145 (39.3%) 
>40 94 (66.2%) 48 (34.8%) 57 (64.0%) 199 (53.9%) 
X2 =101.019, df=4, p<0.001 

Education 

School 9 (36.0%) 0 (0.0%) 25 (12.6%) 34 (9.2%) 
High school 9 (36.0%) 0 (0.0%) 141 (70.9%) 150 (40.7%) 
Undergraduate 
and higher 

7 (28.0%) 145 (100.0%) 33 (16.6%) 185 (50.1%) 

BMI  

Underweight 0 (0.0%) 2 (1.4%) 3 (1.5%) 5 (1.4%) 
Normal 4 (16.0%) 81 (55.9%) 113 (56.8%) 198 (53.7%) 
Overweight 16 (64.0%) 62 (42.8%) 79 (39.7%) 157 (42.5%) 
Obese 5 (20.0%) 0 (0.0%) 4 (2.0%) 9 (2.4%) 
X2 =101.019, df=6, p<0.001 

Marital 
status 

Single 4 (16.0%) 12 (8.3%) 63 (31.7%) 79 (21.4%) 
Married 21 (84.0%) 133 (91.7%) 136 (68.3%) 290 (78.6%) 
X2= 27.723, df=2, p<0.001  

Physical 
exercise 
(workout) 

Yes (always) 3 (12.0%) 11 (7.6%) 14 (7.0%) 28 (7.6%) 
No  4 (16.0%) 83 (57.2%) 72 (36.2%) 159 (43.1%) 
Sometimes  18 (72.0%) 51 (35.2%) 113 (56.8%) 182 (49.3%) 

Workplace 

Yes 4 (16.0%) 50 (34.5%) 27 (13.6%) 81 (21.9%) 
Sometimes 14 (56.0%) 60 (41.4%) 124 (62.3%) 198 (53.7%) 
No 7 (28.0%) 35 (24.1%) 48 (24.1%) 90 (24.4%) 
X2 =24.168, df=4, p<0.001  
No 25 (100.0%) 125 (86.2%) 189 (95.0%) 339 (91.9%) 



 

Ahmed P, Eaty M, Alam N, Anthony L, Yasmin N. Respiratory symptoms among urban traffic 
policemen in Bangladesh: A cross-sectional study (Original research). SEEJPH 2022, posted: 19 
June 2022. DOI: 10.11576/seejph-5534 

 

P a g e  6 | 13 

Smoking 
status 

Yes  0 (0.0%) 20 (13.8%) 10 (5.0%) 30 (8.1%) 
X2 = 11.007, df=2, p=0.004  

 
Table 2 shows the prevalence of present 
respiratory symptoms and previous 
respiratory illness diagnosed by a doctor 
according to the job title. There was a 
substantial difference in the prevalence of all 
present respiratory symptoms according to 

the job title. For example, the prevalence of 
coughing was 24% in the inspectors, 7.6% in 
the sergeants, and 21.6% in constables while 
corresponding estimates for cough sputum 
were 24.0%, 7.6%, and 19.1% respectively. 

 
Table 2. Prevalence of respiratory symptoms according to the job title (n=369) 

 

Respiratory symptoms 
Job title 

Inspectors  
(n/%)  

Sergeants  
(n/%) 

Constables 
 (n/%) 

Total  
(n/%) 

Coughing 6 (24.0% 11 (7.6%) 43 (21.6%) 60 (16.3%) 
Coughing sputum 6 (24.0%) 11 (7.6%) 38 (19.1%) 55 (14.9%) 
Coughing up blood 5 (20.0%) 11 (7.6%) 41 (20.6%) 57 (15.4%) 
Shortness of breathing  6 (24.0%) 11 (7.6%) 39 (19.6%) 56 (15.2%) 
Wheezing 4 (16.0%) 11 (7.6%) 39 (19.6%) 54 (14.6%) 
Chest pain with deep breathing 12 (48.0%) 12 (8.3%) 41 (20.6%) 65 (17.6%) 

 
Table 3 shows the distribution of previous 
respiratory illnesses in the traffic police 
personnel according to the job title. The 
participating traffic inspectors, sergeants, and 
constables were found to have almost no 
history of previous respiratory diseases, 

which could be partly explained by the 
recruitment of personnel with no history of a 
previous disease or chronic illness in the 
police service including the traffic police 
service of Bangladesh.

 
Table 3. Distribution of previous respiratory illness according to the job title (n=369) 

 

Respiratory symptoms 
Job title 

Inspectors  
(n/%)  

Sergeants  
(n/%) 

Constables 
 (n/%) 

Total  
(n/%) 

History of pneumonia 0 1 (0.7%) 1 (0.5%) 1 (0.3%) 
History of tuberculosis 0 0 0 0 
History of chronic bronchitis  0 0 1 (0.5%) 1 (0.3%) 
History of asthma 0 0 0 0 
History of pneumothorax 0 0 0 0 
History of lung cancer 0 0 0 0 
History of chest injury or surgery 0 0 0 0 
History of broken ribs  0 0 0 0 
Allergic reaction interfering with 
breathing 0 1 (0.7%) 1 (0.5%) 2 (0.5%) 

Table 4 shows logistic regression analysis of 
respiratory symptoms according to job title 
(duty type). Constables were found at risk for 

all the studied respiratory symptoms in 
comparison to the reference group for 
coughing (adjusted Odds Ration=4.469, 95% 



 

Ahmed P, Eaty M, Alam N, Anthony L, Yasmin N. Respiratory symptoms among urban traffic 
policemen in Bangladesh: A cross-sectional study (Original research). SEEJPH 2022, posted: 19 
June 2022. DOI: 10.11576/seejph-5534 

 

P a g e  7 | 13 

CI = 1.265-15.793), coughing sputum 
(adjusted odds ratio=3.687, 95% CI= 1.004 -
13.540), shortness of breathing (Adjusted 
Odds Ratio = 3.937, 95% CI=1.069-14.500). 
Risk also increased for wheezing (adjusted 
odds ratio=2.464, 95% CI=0.613-9.906), 
chest pain with deep breathing (adjusted 
Odds Ratio=2.163, 95% CI=0.560-8.349), 
and coughing up blood (adjusted odds 

ration=1.040, 95% CI=0.227-6.162), 
however, the risk was not significant 
statistically. Risk moderately increased in 
sergeants for coughing up blood 
[AOR=1.102, 95% CI= 0.283-4.286] and 
wheezing [AOR=1.260, 95% CI= 0.304-5.2 
on comparison to traffic constables, however, 
the risk was not significant. 

 
Table 4.  Logistic regression analysis of respiratory symptoms according to job title 

 

Outcomes  Job title 
Crude Odds Ratio Adjusted Odds Ratio* 

PE 95% CI PE 95% CI 

Coughing 
Inspector  reference  -  
Sergeants  1.429 0.299-6.817 0.841 0.230-3.075 
Constables  3.358 1.665-6.771 4.469 1.265-15.793 

Coughing 
sputum 

Inspector  reference  -  
Sergeants  1.727 0.467-29.761 0.573 0.151-2.169 
Constables  2.875 1.415-5.843 3.687 1.004 -13.540 

Coughing up 
blood  

Inspector  reference  -  
Sergeants  1.038 0.367-2.932 1.102 0.283-4.286 
Constables  3.161 1.563-6.392 1.040 0.227-6.162 

Shortness of 
breathing 

Inspector  reference    
Sergeants  .772 0.289-2.061 0.612 0.163-2.291 
Constables  2.969 1.464-6.024 3.937 1.069-14.500 

Wheezing 
Inspector  reference  -  
Sergeants  1.280 0.415-3.942 1.260 0.304-5.229 
Constables  2.969 1.464-6.024 2.464 0.613-9.906 

Chest pain  
Inspector reference  -  
Sergeants 0.281 0..119-0.662 0.741 0.302-1.821 
Constables  2.876 1.452-5.696 2.163 0.560-8.349 

 
 

* Logistic regression analysis adjusting for age, BMI (body mass index), education, marital status, 
smoking, use of mask and work out (exercise), history of respiratory disease.  

 
Discussion 
Air pollution in Bangladesh is a major public 
health hazard, especially among those who 
live and work in cities. The growing number 
of vehicles is one of the contributing factors 
for the deteriorating air quality. Traffic police 
personnel who are continuously exposed to 
air pollutants are at high risk. 
The present study was designed to assess the 
prevalence and risk of respiratory symptoms 
between traffic police personnel. The study 
explored a high prevalence of respiratory 

symptoms in different categories of traffic 
police. This finding corroborates with the 
result of studies conducted before among 
traffic police personnel in Thailand and India 
(16,17). 
The use of a questionnaire was useful to take 
into account a large number of potential 
confounders in the current study. After 
adjustment of potential covariates, constables 
were found at risk of coughing, cough 
sputum, coughing up blood, shortness of 
breath, wheezing, and chest pain in 



 

Ahmed P, Eaty M, Alam N, Anthony L, Yasmin N. Respiratory symptoms among urban traffic 
policemen in Bangladesh: A cross-sectional study (Original research). SEEJPH 2022, posted: 19 
June 2022. DOI: 10.11576/seejph-5534 

 

P a g e  8 | 13 

comparison to the inspectors. Similar to the 
present study, an epidemiological study 
conducted before in Italy also reported that 
traffic police personnel assigned for traffic 
control and management by the roadside are 
at high risk of adverse respiratory symptoms 
including coughing, wheezing, shortness of 
breathing in comparison to traffic police 
personnel assigned for administrative duties 
at the office (18). 
The elevated risk of studied respiratory 
symptoms in constables could be explained 
by direct and continuous roadside exposure 
to roadside pollution which has been shown 
to be a direct correlate in studies conducted 
before (19,20). A recently conducted 
comparative study in Malaysia explored that 
traffic police personnel who work by the 
roadside are at high risk of adverse 
respiratory outcomes in comparison to 
unexposed occupational groups due to 
continuous and direct exposure (21). 
Continuous and direct exposure to toxic 
chemicals and gases of vehicular emission 
cause irritation and allergy in the lungs and 
airways, airway obstruction, and increased 
mucus production leading to obstructive lung 
diseases (22,23). Although the human 
bronchopulmonary tract has multiple 
protective mechanisms, such as the air-blood 
barrier and mucosal cilia, air pollutants can 
accumulate in or pass through lung tissues 
depending on the size and chemical nature of 
pollutants (24). The vapor of air pollutants is 
prone to be absorbed by human tissues or 
dissolved in body fluids, relying mostly on 
hydrophilicity and hydrophobicity. The 
ultrafine particles are capable of translocation 
through blood circulation to distal organs and 
tissues, such as liver tissue for detoxification 
(25). Particles deposited in the respiratory 
tract in sufficient amounts can induce 
pulmonary inflammation. Controlled human 
and animal exposure studies have 
demonstrated increased markers for 
pulmonary inflammation following exposure 

to a variety of different particles (26). Airway 
inflammation increases airway 
responsiveness to irritants such as particle 
pollution, allergens, and gases reducing lung 
function by causing bronchoconstriction. At 
the cellular level, inflammation may damage 
or kill cells and compromise the integrity of 
the alveolar-capillary barrier. Repeated 
exposure to particle pollution aggravates the 
initial injury and promotes chronic 
inflammation with cellular proliferation and 
extracellular matrix reorganization (27). 
As regards to subjective symptoms of the 
current study, investigated by means of the 
questionnaire, positive results were more 
prevalent among the constables than 
inspectors, this difference being a statistically 
significant agreement with what was 
observed by a study conducted before in 
China which showed an increase in 
respiratory symptoms in road traffic workers 
(28). Regarding the research approach of the 
study, the identification of the type of 
industries and occupations where there is an 
excess risk of adverse respiratory health 
outcomes is in agreement with a study done 
before in Italy (29). 
This study, to the best knowledge of the 
authors, is the first of its kind that measures 
the risk of adverse respiratory health 
outcomes among traffic police personnel in 
Bangladesh. However, there are some 
limitations in the present study. Given the 
cross-sectional design of the study, it has 
limited capability to infer causality, and the 
relatively small number in the reference 
group can affect the validity of the outcome. 
Further epidemiological studies, on larger 
samples and environmental air quality data 
provided, are required to better understand 
and define the pollution-related respiratory 
outcomes in traffic police personnel. The 
finding of this study suggests a valuable need 
for targeted occupational health interventions 
such as the use of protective masks at the 
workplace and periodic medical surveillance 



 

Ahmed P, Eaty M, Alam N, Anthony L, Yasmin N. Respiratory symptoms among urban traffic 
policemen in Bangladesh: A cross-sectional study (Original research). SEEJPH 2022, posted: 19 
June 2022. DOI: 10.11576/seejph-5534 

 

P a g e  9 | 13 

to prevent respiratory morbidity and 
mortality in traffic police personnel working 
in polluted environments. 
 
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Ahmed P, Eaty M, Alam N, Anthony L, Yasmin N. Respiratory symptoms among urban traffic 
policemen in Bangladesh: A cross-sectional study (Original research). SEEJPH 2022, posted: 19 
June 2022. DOI: 10.11576/seejph-5534 

 

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Medical Evaluation questionnaire. 
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Ahmed P, Eaty M, Alam N, Anthony L, Yasmin N. Respiratory symptoms among urban traffic 
policemen in Bangladesh: A cross-sectional study (Original research). SEEJPH 2022, posted: 19 
June 2022. DOI: 10.11576/seejph-5534 

 

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_____________________________________________________________________________________________ 
 
© 2022 Ahmed et al; This is an Open Access article distributed under the terms of the Creative Commons Attribution 
License (http://creativecommons.org/licenses/by/3.0), which permits unrestricted use, distribution, and reproduction 
in any medium, provided the original work is properly cited. 

 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

 
 



 

Ahmed P, Eaty M, Alam N, Anthony L, Yasmin N. Respiratory symptoms among urban traffic 
policemen in Bangladesh: A cross-sectional study (Original research). SEEJPH 2022, posted: 19 
June 2022. DOI: 10.11576/seejph-5534 

 

P a g e  12 | 13 

ANNEX. QUESTIONNAIRE 
 
Respiratory health outcomes among Traffic police in Bangladesh: A Cross-sectional Study                                       
  

FACE SHEET 
 

Serial Number :  
Site :   
Date of Interview :  
Interviewed by :  
 

Sl. 
No 

Questions Coding category Direction Code 

SECTION A: Socio-demographic characteristics  
1 Name  ………………………   

2 Age (to the nearest 
year) 

…………….   

3 Sex  Male/ Female    

3 Your height   
…………Ft………. inch = ….. m…cm  

  

4 Your weight   
…………….kg  

  

5 Religion Muslim....................................................1                    
Hindu......................................................2 
Buddhist.................................................3                
Christian.................................................4 
Others (Specify).....................................5 

  

6 What is your job title inspector………………………………1 
sergeant……………………………….2 
constable………………………………3 

  
 
 
 

7 What is your 
relationship status: 

Single…………………………………1 
Married……………………………….2 
Divorced/ Separated………………….3 

  
 
 
 
 

SECTION B: respiratory heath status  



 

Ahmed P, Eaty M, Alam N, Anthony L, Yasmin N. Respiratory symptoms among urban traffic 
policemen in Bangladesh: A cross-sectional study (Original research). SEEJPH 2022, posted: 19 
June 2022. DOI: 10.11576/seejph-5534 

 

P a g e  13 | 13 

Sl. 
No 

Questions Coding category Direction Code 

8 Do you currently have 
any of the following 
respiratory heath 
condition?   
 
 

a. Shortness of breath: Yes/No 
b. Shortness of breath when walking fast on level ground or 
walking up a slight hill or incline: Yes/No 
c. Shortness of breath when walking with other people at an 
ordinary pace on level ground: Yes/No 
d. Have to stop for breath when walking at your own pace on 
level ground: Yes/No 
e. Shortness of breath when washing or dressing yourself: 
Yes/No 
f. Shortness of breath that interferes with your job: Yes/No 
g. Coughing that produces phlegm (thick sputum): Yes/No 
h. Coughing that wakes you early in the morning: Yes/No 
i. Coughing that occurs mostly when you are lying down: 
Yes/No 
j. Coughing up blood in the last month: Yes/No 
k. Wheezing: Yes/No 
l. Wheezing that interferes with your job: Yes/No 
m. Chest pain when you breathe deeply: Yes/No 
n. Any other symptoms that you think may be related to lung 
problems: Yes/No 

Multiple 
response 
possible 

 
 
 
 
 

 
SECTION C: History of previous respiratory illness 
 

9 Have you ever had the 
following lung disease 
diagnosed by a doctor?  
 

Asthma ……………………………..1  
Chronic bronchitis  …………………2 
Tuberculosis………………………...3  
Pneumonia………………………….4 
Pneumothorax………………………5 
Lung cancer………………………..6 
Chest injury or surgery.……………7 
Broken ribs…………………………8 

 
Multiple 
response 
possible  

 
 
 
 
 

10 Have you ever had any 
allergic  conditions? 

Allergic reactions that interfere with your breathing: Yes/No   

SECTION D:  Behavioural information 
 

11 
 

What is your smoking 
status? 

Yes …………………1 
No ………………….2 

 
 
 

 
 

12 Do you regularly do 
exercise (workout)? 

Yes……………………………………1 
No…………………………………….2 
Sometimes ……………………………3 

  

13 Do you use mask at 
workplace duty time? 

Yes (Always)………………………...1 
No…………………………………… 2 
Sometimes……………………………3