Archives of Academic Emergency Medicine. 2022; 10(1): e15

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

Clinical Features and Outcomes of Acute Chlorine Gas In-
halation; a Brief Report
Taymmia Ejaz1∗, Sheema Saadia1, Safia Akhlaq1, Adil Aziz1, Muhammad Arslan Ahmed1, Aisha Fareed
Siddiqui1

1. Department of Medicine, The Aga Khan University Hospital, Karachi, Pakistan.

Received: January 2022; Accepted: January 2022; Published online: 14 February 2022

Abstract: Introduction: On March 6th,2020, chlorine gas leak was reported at Engro Polymer & Chemicals Plant in Karachi
City, Pakistan. This study aimed to evaluate the clinical features and outcomes of patients who presented to
emergency department (ED) following this event. Methods: This retrospective cross-sectional study, evaluated
the clinical features and outcomes (length of hospital stay, complications, and mechanical ventilation require-
ment) of patients presenting to ED of Aga Khan University Hospital, Karachi, Pakistan, with history of chlorine
gas exposure at the Engro Plant from 6th March to 14th March 2020. Results: 38 patients with mean age of 33.1
± 8.1 years presented to ED with history of chlorine gas exposure (100% male). 4 (10.5%) cases had comorbid
diseases. Most common presenting symptom was dyspnea, observed in 33 (86.8%) cases, followed by cough,
seen in 27 (71.1%) subjects. 13.2% (5/38) patients had infiltration on chest x-ray and 33 (86.8 %) required hos-
pitalization. 6 (15.8%) patients had repeat presentation requiring hospitalization or ED visit. 18 (47.4%) were
managed with high flow oxygen therapy, 9 (23.7%) required non-invasive ventilation and one patient was intu-
bated due to development of pneumo-mediastinum. Mean length of stay was 1.55 ± 1.58 days and no patients
died. Presence of tachycardia was the only finding significantly associated with need for oxygen (p = 0.033) and
non-invasive ventilation (p = 0.012). Conclusion: The majority of patients presenting with acute chlorine gas
exposure showed good clinical outcomes and rapid recovery, however, a high index of suspicion and vigilance
should be maintained for complications such as pneumomediastinum and acute respiratory distress syndrome
in these patients.

Keywords: Inhalation exposure; poisoning; accidents, occupational; chlorine; gas poisoning; outcome assessment, health
care

Cite this article as: Ejaz T, Saadia S, Akhlaq S, Aziz A, Ahmed MA, Siddiqui AF. Clinical Features and Outcomes of Acute Chlorine Gas Inhala-

tion; a Brief Report. Arch Acad Emerg Med. 2022; 10(1): e15. https://doi.org/10.22037/aaem.v10i1.1448.

1. Introduction

Chlorine gas, a simple halogen irritant, is available world-

wide as a household and industrial chemical. Through oxi-

dation and free radical formation (1) halogen pulmonary ir-

ritants (HPIs) cause respiratory mucosal damages, and con-

comitant ophthalmological and dermatological manifesta-

tions(2). Manifestations are dose-dependent, with mucosal

membrane irritation occurring at concentrations less than 15

ppm, milder respiratory clinical features at concentrations

more than 30 ppm, and pneumonitis and pulmonary edema

∗Corresponding Author: Taymmia Ejaz; Department of Medicine, The Aga
Khan University Hospital, Stadium Road, Karachi, 78600, Pakistan. Email:
taymmia.ejaz@gmail.com/ taymmia.ejaz@aku.edu, Tel: +923225830686, OR-
CID: http://orcid.org/0000-0001-8748-8763.

at concentrations greater than 50 ppm. Death results within

few to 30 minutes in exposures with 400 ppm and over 1000

ppm concentrations, respectively(2). Exposure can result

from multiple sources, which include industrial accidents,

inappropriate use of household cleaning agents, swimming

pool chlorination accidents, burning of solid chlorine prod-

ucts, and deliberate release as a chemical weapon such as in

World War One and Syrian Conflict(3). Health effects of chlo-

rine gas inhalation vary based on age, comorbid conditions,

exposure duration, and various other factors(3, 4). Inhala-

tional injury results in acute short-term clinical features and

long-term changes in lung function, which manifest as reac-

tive airway dysfunction(5, 6). Industrial accidents resulting

in large scale chlorine exposure incidents have occurred both

in the developed and developing world(7-12). On March

6th, 2020, chlorine gas leak was reported at Engro Polymer &

Chemicals Plant in Karachi City, Pakistan(13). Over one hun-

This open-access article distributed under the terms of the Creative Commons Attribution NonCommercial 3.0 License (CC BY-NC 3.0).
Downloaded from: http://journals.sbmu.ac.ir/aaem



T. Ejaz et al. 2

dred workers were reported to have been exposed and were

taken to different health care facilities in Karachi; some were

brought to Aga Khan University Hospital for further manage-

ment. This study aimed to evaluate clinical features and out-

comes of patients who were accidentally exposed to chlorine

gas in the industrial accident.

2. Methods

2.1. Study design and setting

This study is a retrospective cross-sectional study conducted

in Aga Khan University Hospital, Karachi, Pakistan, from

March - April 2020. Ethical approval was taken from Insti-

tutional Ethics Review Committee Aga Khan University Hos-

pital (ERC:2020-4918-10961).

2.2. Participants

All patients with history of chlorine gas exposure at the Engro

Plant from 6th March to 14th March 2020 presenting to Emer-

gency department and those hospitalized in Aga Khan Uni-

versity Hospital, Karachi, Pakistan were included in the study.

Patients were enrolled based on consecutive non-probability

sampling. Patients with incomplete records were excluded.

Diagnosis of chlorine poisoning was made based on expo-

sure history, clinical presentation, and laboratory and radio-

logical findings.

2.3. Data collection

Data collection was done using a pre-designed proforma.

Data was collected on demographic profile, co-morbid con-

ditions, presenting clinical features and other symptoms, ex-

amination findings, oxygen requirement, laboratory finding,

imaging findings, and management. Retrospective review

of files and electronic health records was done. Patients

who had not undergone chest x-rays or arterial blood gas

tests were categorized in missing data. Length of hospital

stay, complications, and mechanical ventilation requirement

were considered as outcomes.

2.4. Statistical analysis

Data analysis was done in SPSS Version 23. Categorical data

were reported with frequencies and percentages. Continu-

ous data were reported as mean and standard deviation. Nor-

mality tests were done to assess normality and parametric or

nonparametric tests were used accordingly. Fischer’s exact

and chi-square tests were done to compare categorical data,

and student t-test was done to compare quantitative data. A

p-value < 0.05 was considered significant.

Table 1: Clinical and laboratory findings of studied cases

Variables Values
Symptoms
Dyspnea 33 (86.8)
Cough 27 (71.0)
Cough and dyspnea 25 (65.7)
Chest pain 17 (44.7)
Headache 5 (13.2)
Sore throat 4 (10.5)
Nausea 4 (10.5)
Vomiting 2 (5.3)
Physical examination
Tachycardia 19 (50.0)
Tachypnea 29 (76.3)
Expiratory wheeze 4 (10.5)
Bilateral lung crepitation 7 (18.4)
Arterial Blood gas (n = 13)
Mean pH 7.35 ± 0.14
Median Po2 mmHg (IQR) 64 (55.5 – 94.0)
Median PCo2 mmHg (IQR) 41.5 (38.9 - 46.75)
Laboratory parameters (n=32)
Hemoglobin(g/dl) 14.65± 0.99

White cell count(x109 ) 13.89± 4.64
Neutrophils (%) 79.43 ±12.01
Neutrophilia 17 (44.7)
Lactate(n=13) 2.18± 1.27
Sodium(mmol/l) 139.28 ± 2.27
Potassium(mmol/l) 4.00 ± 0.38
Bicarbonate(mmol/l) 25.15 ± 2.74
Chloride(mmol/l) 104.56 ± 1.74
Troponin(ng/ml) 0.0072 ± 0.0036
Data are presented as mean ± standard deviation or
frequency (%). Complete baseline laboratory data were
available for 32 patients who were shifted to emergency room
long stay area; whereas this was missing in other patients as
they were observed clinically and discharged from short stay
area.

3. Results

38 patients with the mean age of 33.1 ± 8.1 (range: 21 - 55)

years presented to emergency department with history of

chlorine gas exposure during the defined study period (100%

male). 4 (10.5%) patients had comorbid conditions (3 hyper-

tensions, 2 diabetes mellitus, and 1 ischemic heart disease).

Table 1 summarizes the clinical and laboratory findings of

studied cases. Most common presenting symptom was dys-

pnea, observed in 33 (86.8%) cases, followed by cough, seen

in 27 (71.1%). Among the unusual presenting features, pre-

syncope/syncope was reported by three patients and loose

stools were reported by one patient.

Chest x-rays were done in 32 (84.2%) patients; among

these patients 5/32 patients (15.6%) had abnormalities (pul-

monary edema in 2 patients, pneumomediastinum and sub-

cutaneous emphysema in one patient, bilateral inhomoge-

neous consolidations in one patient and infiltrates in right

This open-access article distributed under the terms of the Creative Commons Attribution NonCommercial 3.0 License (CC BY-NC 3.0).
Downloaded from: http://journals.sbmu.ac.ir/aaem



3 Archives of Academic Emergency Medicine. 2022; 10(1): e15

Table 2: Management and outcomes of studied patients

Variables Values
Length of stay (days)
Mean ± SD 1.55 ± 1.58
≤ 1* 29 (76.3)
2 6 (15.8)
≥ 4 3 (7.9)
Disposition
Ward 24 (63.2)
Emergency department 7 (18.4)
Special care unit 6 (15.8)
Intensive care unit 1 (2.6)
Management
Salbutamol nebulization 32 (84.2)
Ipratropium nebulization 34 (89.5)
Systemic steroids 13 (34.2)
Sodium bicarbonate nebulization 2 (5.3)
Beclomethasone nebulization 5 (13.2)
Supplemental oxygen 18 (47.4)
Non-invasive ventilation 9 (23.7)
Mechanical ventilation 1 (2.6)
Data are presented as mean ± standard deviation (SD) or
frequency (%). *: 10 (26.3%) were hospitalized for < 6 hours.

infra-hilar region in one patient).

Table 2 shows the management and outcomes of the cases.

33(86%) patients required hospitalization and 6 (15.8%) pa-

tients had repeat presentations requiring hospitalization or

emergency department visit. 18 (47.4%) were managed with

high flow oxygen therapy, 9 (23.7%) required non-invasive

ventilation, and one patient was intubated due to devel-

opment of pneumomediastinum on repeat presentation to

emergency department. Mean length of stay was 1.55 ± 1.58

days and no patients died. Tachycardia was the only finding

significantly associated with need for oxygen supplement (p

= 0.033) and non-invasive ventilation (NIV ) requirement (p =

0.012; table 3).

4. Discussion

This study describes the presenting features, outcomes,

management, and complications observed in patients af-

ter an industrial disaster resulting in accidental exposure to

chlorine. The proportion of presenting affected population

was significantly lower than that observed in other larger-

scale disasters due to smaller scale and nature of the inci-

dent. However, the findings of this study can predict what

challenges and patient outcomes can occur in case of any

event causing exposure on a larger scale in a metropolitan

city such as Karachi in a lower-middle income country. Al-

though many case studies have been published on acciden-

tal chlorine exposure due to swimming pool accidents and

household exposure, there are few studies on large scale in-

dustrial exposure.

All patients in our study were males and adults. This ac-

counts for the relatively better outcomes in our study since

children are reported to be more severely affected by chlo-

rine exposure(14). This was observed in various studies as

children had a higher hospitalization rate and longer hospi-

tal stay(14).

The presenting features and symptoms of the patients were

similar to those observed in other observational studies.

Cough and dyspnea were the most common symptoms ob-

served in our study. Sever et al.(11) in Turkey reported sim-

ilar outcomes and clinical features in 39 patients presenting

to emergency department after accidental chlorine gas expo-

sure. Cough and dyspnea were seen in 64.1% and 30.8% of

the patients, respectively. Sever et al.(11) also reported these

as the most common symptoms. In a systematic review of

over 37 incidents of accidental chlorine exposure in civilians

(n=1566), cough and dyspnea were also the most common

presenting features, observed in 29% and 22% patients, re-

spectively(2). In contrast, Kim et al. reported headache as the

most common symptom observed in patients exposed(14)

and eye irritation with sneezing was common in patients in a

study by Ammoura et al. in Jordan(7). Physical signs showed

significant correlation with outcomes in a study by Khilji et

al. from Oman(9). However, tachycardia was the only find-

ing significantly associated with oxygen or NIV requirement

in our study.

30.8% were asymptomatic and physical examination was un-

remarkable in the majority (64.1%) of patients and the most

common physical examination finding was tachypnea in a

study on evaluation of 39 cases of chlorine exposure by Sever

et al. in Turkey(11). However, the majority of patients had

an abnormal physical examination in our study; tachypnea

was the most common physical sign, found in 29 (76.3%) pa-

tients. All 71 patients (100%) had presented with respiratory

complains after the train derailment incident in Graniteville,

California(12). On physical exam wheeze (46%) and crackles

(29%) were the most common findings; tachypnea was ob-

served in 46%(12). Gülolu et al. (8)from Turkey also reported

10.4% asymptomatic subjects and normal physical examina-

tion in the majority (71.6%) of patients.

Only one patient (2.6%) had abnormal x-ray in the study by

Sever et al.(11); in contrast to 15.6% patients having abnor-

mal chest x-ray findings in our study. Non-invasive ventila-

tion was required in 9 (27.3%) patients in our study, in com-

parison, no patient in their study required non-invasive or

invasive mechanical ventilation. Chest x-rays were done in

71.7% (76/106) and x-rays were pathological in only 6 (5.7%).

In contrast, 40/71 (57%) of the hospitalized patients devel-

oped abnormal findings after the Graniteville train derail-

ment incident(12), most of these x-ray changes occurred on

the first day of exposure and infiltrates were frequent find-

ings. The role of chest-x-ray in management after chlo-

This open-access article distributed under the terms of the Creative Commons Attribution NonCommercial 3.0 License (CC BY-NC 3.0).
Downloaded from: http://journals.sbmu.ac.ir/aaem



T. Ejaz et al. 4

Table 3: Association between some clinical features and need for oxygen supplementation and non-invasive ventilation (NIV )

Variable Total (n) Oxygen P NIV P
Age (years)
≥ 40 6 4 (66.7)

0.33
3 (50.0)

0.13
< 40 32 15 (46.9) 6 (18.0)
Chest x-ray abnormality
Yes 5 5 (100.0)

0.049
4 (80.0)

0.013
No 27 14 (51.9) 5 (18.5)
Tachypnea
Yes 29 16 (55.2)

0.22
9 (31.0)

0.061
No 9 3 (33.3) 0
Tachycardia
Yes 19 13 (68.4)

0.033
8 (42.1)

0.019
No 19 6 (31.6) 1 (5.3)
Data presented as mean ± standard deviation (SD) or number (%). WBC: White blood cell; CT: computed tomography scan;
ESR: Erythrocyte sedimentation rate; CRP: C-reactive protein; CPK: Creatine Phosphokinase; LDH: Lactate dehydrogenase;
BUN: Blood urea nitrogen; COPD: Chronic obstructive pulmonary disease.

rine exposure is controversial; most recommend it in cases

of pulmonary edema or acute respiratory distress syndrome

(ARDS), however, others recommend a baseline chest x-ray

in all patients with exposure to assess radiological progres-

sion(3).

Kim et al.(14) did not report any laboratory abnormalities

among the 209 non-hospitalized patients after chlorine ex-

posure. Arterial Blood Gas (ABG) assessments were done

in only 55 (77%) cases in a study by Van Sickle (12). Mean

pH was 7.32, which was similar to7.35 reported in our study.

25 (45%) patients had respiratory acidosis in their study as

compared to 30% in our study and 18 (10%) had hypox-

emia in their study as compared to 69.2% of our patients in

whom ABGs were assessed. Similarly, ABG assessments were

not done in 85/106 (80.2%) patients in a study by Gülolu et

al.(8) Among those with ABG assessments,results were within

normal ranges in 13/21 (61.9%), 4/21 (19.04%) had hypoxia,

3/21 (14.2%) patients had hypercarbia and one patient had

hypocarbia and respiratory alkalosis.

In a systematic review of 36 studies(2), overall death rate in

1566 individuals was 0.6%, all of the 9 patients who had died

in that systematic review belonged to the study on Gran-

iteville train derailment incident(12).There were four cases of

spontaneous pneumomediastinum (0.3%)(2). Our study had

one case of pneumomediastinum, and no patient died. Al-

though this study did not assess lung function tests, chlorine

gas exposure can result in long-term sequela due to reduc-

tion in lung function and this was reported in various stud-

ies(10, 15, 16).

Masoumi et al. from neighboring Iran reported significant

problems, which were encountered after chlorine gas leakage

in Dezful, Iran(10). Prevention of these events requires envi-

ronmental regulations, chlorine safety-related guidelines im-

plementation and pilot safety studies in industrial installa-

tions. Emergency response systems in hospitals for rapid

implementation during these disasters can ensure effective

management.

5. Limitation

Limitations of our study include being single-centered and

retrospective study design. Exact number of exposed peo-

ple is not known and patients presented to various tertiary

care hospitals in Karachi after the incident; therefore, out-

comes of those patients are not known. Distance from leak-

age site; exposure duration, and concentration of chlorine

was not documented properly. Long-term follow up of pa-

tients was not done to assess for persistence of symptoms.

Moreover, lung functions test during admission and post-

admission were not done to assess bronchial hyperactivity.

Our center is a large tertiary care private hospital; therefore,

the results of the study cannot be generalized to other centers

in the country.

6. Conclusion

The majority of patients presenting with acute chlorine gas

exposure showed good clinical outcomes and rapid recovery;

however, a high index of suspicion and vigilance should be

maintained for complications such as pneumomediastinum

and acute respiratory distress syndrome in these patients.

Prevention of these events requires environmental regu-

lations, chlorine safety-related guidelines implementation,

and pilot safety studies in industrial installations. Moreover,

in case of these incidents the duration of exposure, proximity,

and concentration of the toxin should be documented.

This open-access article distributed under the terms of the Creative Commons Attribution NonCommercial 3.0 License (CC BY-NC 3.0).
Downloaded from: http://journals.sbmu.ac.ir/aaem



5 Archives of Academic Emergency Medicine. 2022; 10(1): e15

7. Declarations

7.1. Acknowledgments

None.

7.2. Authors’ contributions

Taymmia Ejaz, Safia Akhlaq and Adil Aziz designed the study.

Taymmia Ejaz and Safia Akhlaq participated in acquisition of

data. Sheema Saadia and Arslan Ahmed analyzed the data.

Adil Aziz and Arslan Ahmed reviewed results and carried out

interpretation of data. Taymmia Ejaz and Sheema Saadia

wrote the initial draft and others revised the manuscript crit-

ically. All authors approved final version of the manuscript to

be published and are accountable for all aspects of the work.

7.3. Funding and supports

None.

7.4. Conflict of Interest

Authors declare that there is no conflict of interest.

References

1. Carlisle M, Lam A, Svendsen ER, Aggarwal S, Matalon S.

Chlorine-induced cardiopulmonary injury. Annals of the

New York Academy of Sciences. 2016;1374:159-67.

2. Govier P, Coulson JM. Civilian exposure to chlorine gas: A

systematic review. Toxicol Lett. 2018;293:249-52.

3. Zellner T, Eyer F. Choking agents and chlorine gas -

History, pathophysiology, clinical effects and treatment.

Toxicol Lett. 2020;320:73-9.

4. Huynh Tuong A, Despreaux T, Loeb T, Salomon J, Megar-

bane B, Descatha A. Emergency management of chlorine

gas exposure - a systematic review. Clin Toxicol (Phila).

2019;57(2):77-98.

5. Balte PP, Clark KA, Mohr LC, Karmaus WJ, Van Sickle D,

Svendsen ER. The Immediate Pulmonary Disease Pattern

following Exposure to High Concentrations of Chlorine

Gas. Pulm Med. 2013;2013:325869.

6. Hoyle GW, Svendsen ER. Persistent effects of chlorine in-

halation on respiratory health. Annals of the New York

Academy of Sciences. 2016;1378:33-40.

7. Ammoura AM, S.Aqqad A, T.Hamdan MA. Chlorine Gas

Poisoning. Journal of The Royal Medical Services2004.

8. Güloğlu C, Kara İH, Erten PG. Acute Accidental Exposure

to Chlorine Gas in the Southeast of Turkey: A study of 106

Cases. Environmental Research. 2002;88:89-93.

9. Khilji MF. Clinical Presentations and Outcomes of Indus-

trial Chlorine Gas Exposure Incidence in Oman. Prehos-

pital and Disaster Medicine. 2021;36:18-24.

10. Masoumi G, Maniey M, Aghababaeian H, Ostad-

taghizadeh A, Araghi Ahvazi L. Lessons Learned From

a Chlorine Gas Leakage in Dezful City, Iran. Disaster

Medicine and Public Health Preparedness. 2020:1-7.

11. Sever M, Mordeniz C, Sever F, Dokur M. Accidental Chlo-

rine Gas Intoxication: Evaluation of 39 Patients. Journal

of Clinical Medicine Research. 2009.

12. Van Sickle D, Wenck MA, Belflower A, Drociuk D, Ferdi-

nands J, Holguin F, et al. Acute health effects after expo-

sure to chlorine gas released after a train derailment. Am

J Emerg Med. 2009;27(1):1-7.

13. Bhatti MW. 137 faint in Port Qasim industrial gas leakage.

The News. 7th March 2020.

14. Kim J-A, Yoon S-Y, Cho S-Y, Yu J-H, Kim H-S, Lim G-I, et

al. Acute health effects of accidental chlorine gas expo-

sure. Ann Occup Environ Med. 2014;26.

15. Christensen BE, Duncan MA, King SC, Hunter C, Ruckart

P, Orr MF. Challenges During a Chlorine Gas Emer-

gency Response. Disaster Med Public Health Prep.

2016;10(4):553-6.

16. Clark KA, Karmaus WJ, Mohr LC, Cai B, Balte P, Gibson JJ,

et al. Lung Function before and after a Large Chlorine Gas

Release in Graniteville, South Carolina. Ann Am Thorac

Soc. 2016;13(3):356-63.

This open-access article distributed under the terms of the Creative Commons Attribution NonCommercial 3.0 License (CC BY-NC 3.0).
Downloaded from: http://journals.sbmu.ac.ir/aaem


	Introduction
	Methods
	Results
	Discussion
	Limitation 
	Conclusion 
	Declarations
	References