https://ojs.wpro.who.int/ 1WPSAR Vol 12, No 2, 2021  | doi: 10.5365/wpsar.2020.11.3.008

COVID-19: Outbreak Investigation Report

S
evere acute respiratory syndrome coronavirus 2 
(SARS-CoV-2) was first identified in Malaysia on 
25 January 2020; three cases were notified, all 

of which were imported from Wuhan, China. On 30 
January 2020, WHO declared coronavirus disease 2019 
(COVID-19) a public health emergency of international 
concern. On 6 February, the first local transmission was 
reported in Malaysia in a close contact of a confirmed 
COVID-19 case who had returned from Singapore. The 
first case in Malaysia with neither a history of contact 
with a confirmed case nor travel to an affected area 
was reported on 12 March 2020. By 28 April 2020, 
Malaysia had reported 5851 confirmed cases and 100 
fatalities.

Selangor is the most densely populated state 
in Malaysia, with a population of 5.8 million and a 
population density of 780.3 people/km2. It is situated 
in Peninsular Malaysia, bordering the capital, Kuala 

Lumpur, and the Federal Government Administrative 
Centre, Putrajaya. By mid-March 2020, there were more 
than 200 COVID-19 cases in Selangor, and the number 
increased to more than 1300 by mid-April 2020, largely 
due to two main clusters. The Malaysian Government 
instituted movement restrictions through a mandatory 
movement control order (MCO) under the Prevention 
and Control of Infectious Diseases Act 1988 and the 
Police Act 1967 to limit human movement from 18 
March in an effort to prevent further COVID-19 cases.

A variety of containment strategies, used either 
in isolation or in combination, have been used for 
COVID-19, which can be broadly categorized as 
physical distancing measures, movement restrictions, 
public health measures and socioeconomic measures.1 
This paper describes the epidemiology and control 
measures used to control the outbreak of COVID-19 in 
Selangor, Malaysia, up to April 2020.

a Ministry of Health Malaysia.
b Selangor State Health Department, Malaysia.
c Institute for Medical Research, Malaysia.
d Petaling District Health Office, Malaysia.
Published: 22 June 2021
doi: 10.5365/wpsar.2020.11.3.008

Objective: Various public health and social measures have been used during the COVID-19 outbreak, including lockdowns, 
contact-tracing, isolation and quarantine. The objective of this manuscript is to describe outbreaks of COVID-19 in 
Selangor, Malaysia, the public health strategies used and the observed impact of the measures on the epidemic curve.

Methods: Information on all confirmed COVID-19 cases in Selangor between 25 January and 28 April 2020 was obtained. 
Clusters were identified, and cases were disaggregated into linked, unlinked and imported cases. Epidemic curves were 
constructed, and the timing of movement control orders was compared with the numbers of cases reported.

Results: During the study period, 1395 confirmed COVID-19 cases were reported to the Selangor Health Department, 
of which 15.8% were imported, 79.5% were linked and 4.7% were unlinked cases. For two main clusters, the number 
of cases decreased after control measures were instituted, by contact-tracing followed by isolation and home quarantine 
for the first cluster (n = 126), and with the addition of the movement control order for the second, much larger cluster 
(n = 559).

Discussion: The findings suggest that appropriate, timely public health interventions and movement control measures 
have a synergistic effect on controlling COVID-19 outbreaks.

Use of movement restrictions during an 
outbreak of COVID-19 in Selangor, Malaysia
Anita Suleiman,a Shaari Ngadiman,b Mazliza Ramly,a Ahmad Faudzi Yusoffc and Mohamed Paid Yusofd

Correspondence to Mazliza Ramly (drmazliza@moh.gov.my).



WPSAR Vol 12, No 2, 2021  | doi: 10.5365/wpsar.2020.11.3.008 https://ojs.wpro.who.int/2

Suleiman et alStrategies in stemming COVID-19 in Selangor, Malaysia

1 month to 92 years (median, 35 years); 10.4% were 
aged <19 years, 46.5% 19–39 years, 27.2% 40–59 
years and 14.5% ≥60 years. Of the 1395 cases, 15.8% 
were imported, 79.5% were linked cases and 4.7% were 
unlinked cases.

The epidemic curve (Fig. 1) shows an exponential 
increase in the number of cases in Selangor from early 
March 2020, which peaked on 19 March, followed by a 
steady decline by 28 April.

Initial case detection and control measures included 
contact-tracing, isolation of cases and home quarantining 
of contacts of cases. Travellers and returning Malaysians 
with either symptoms or fever detected with thermal 
scanners at points of entry were tested for SARS-CoV-2. 
Those found to be positive were isolated in a designated 
COVID-19 hospital, while those found to be negative and/
or asymptomatic were quarantined in designated hotels 
for 14 days from the date of arrival.

The increase in the number of linked cases after  
22 February was due to a workplace cluster. Extensive 
case investigations revealed 126 confirmed cases among 
1715 contacts, for an attack rate of 7.3%. This attack 
rate was higher among work-related contacts (18.7%, 
56 of 300) than among family and social contacts 
(4.9%). The case with the earliest onset of illness, on 
18 February, was identified as the primary case for this 
cluster and was imported from a neighbouring country. 
The largest potential exposure event was on 27 February, 
at a meeting with approximately 300 people. The number 
of cases in this cluster peaked on 29 February and then 
declined, in line with public health measures initiated on 
29 February (Fig. 2A).

At the time of the workplace cluster, mass gather-
ings were not banned. A second cluster was subsequently 
detected after a religious mass gathering in Kuala Lumpur 
of more than 10 000 people between 28 February and 
2 March 2020, resulting in 559 COVID-19 cases in 
Selangor among attendees, their families and social con-
tacts (Fig. 2B). Further links were made to a wedding on 
6 March and the transfer of students from a school near 
the mass gathering location to another school in Selangor 
on 12 March. The earliest onset of disease after the latter 
event was on 26 February in a cook at the school in 
Selangor, who also attended the mass gathering.

METHODS

This observational study included all COVID-19 cases 
reported in Selangor between 25 January and 28 April 
2020. By that time, Selangor had reported 25% of all 
COVID-19 cases in Malaysia.

A confirmed case was defined as an individual with 
a positive test for SARS-CoV-2 by reverse transcriptase-
polymerase chain reaction from nasopharyngeal swabs. 
We obtained demographic, clinical and exposure 
information from an online data collection form used by 
district health authorities in case investigation. Clusters 
were identified from detailed movement histories of 
confirmed cases and their contacts.

An epidemic curve was plotted, with the date of 
onset of illness used for symptomatic cases and the 
date of last exposure plus 5 days as the estimated “on-
set date” for asymptomatic cases. We defined cases as 
“imported” if they had travelled overseas in the 14 days 
before onset, as “linked” if the disease was acquired 
locally after a history of contact with a COVID-19 case 
and as “unlinked” for those with no history of contact 
with a confirmed COVID-19 case. Data were analysed in 
Microsoft Excel with SPSS version 26.

The control measures used during the period of 
measuring the epidemic curve are described.

Ethics approval

The study protocol was reviewed and approved by the 
Medical Research and Ethics Committee, Ministry of 
Health Malaysia (NMRR-20–1043–54912 [IIR]).

RESULTS

As of 28 April 2020, 1395 confirmed COVID-19 cases 
had been reported to Selangor Health Department. Most 
(80%) were detected by contact-tracing, 13% were 
imported, 5% were detected by sampling of people with 
influenza-like illness or severe acute respiratory illness 
at sentinel surveillance sites, and 2% were found during 
routine passive case detection.

Most of the COVID-19 cases were in Malaysian 
citizens (85%) and males (59%). The age range was 



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Strategies in stemming COVID-19 in Selangor, MalaysiaSuleiman et al

During the first 14 days of the first MCO, the number 
of COVID-19 cases decreased by 12.8%, with a further 
decline of 71% after the second and 72% after the third 
MCO. The number of imported cases fell after implemen-
tation of international travel restrictions during the first 
MCO and had almost disappeared by the third. Most 
unlinked cases were reported before and throughout the 
first MCO and had also fallen to almost 0 during the third.

DISCUSSION

Lack of pharmacological treatment and vaccines against 
COVID-19 meant that public health and social measures 
were the mainstay of the initial COVID-19 response. Sel-
angor initially adopted contact-tracing, isolation of cases 
and quarantine of contacts to manage the outbreak but 
added MCOs with closure of schools, universities and 
non-essential businesses and services. The MCOs ap-
pear to have flattened the epidemic curve. A modelling 
study conducted in the United Kingdom that included 

On 18 March, the first 14-day MCO was initiated, 
which prohibited public movement, including interstate 
and international travel and mass gatherings for religious, 
sports, social and cultural activities throughout the 
country. Businesses and services deemed non-essential, 
schools, universities and government offices were closed, 
and people were urged to work from home. Only essen-
tial services such as food and health care could operate, 
with strict operating procedures that ensured physical 
distancing and screening for fever. A second MCO was 
implemented from 1 April to 14 April. In addition, an 
enhanced MCO was enforced in certain locations with 
established large clusters, where all movement was 
restricted. Comprehensive testing of all residents for 
SARS-CoV-2 was conducted; residents and visitors in the 
area were forbidden to leave their homes, and all roads 
into the enhanced MCO area were blocked. Residents 
were provided with adequate food and medical supplies 
by authorities, with special arrangements to address any 
additional needs.

Fig. 1. Epidemic curve of COVID-19 cases by importation and linkage between 5 January and 28 April 2020, 
Selangor, Malaysia (n = 1395)

MCO 1 MCO 2 MCO 3

0

10

20

30

40

50

60

70

1/5/20 1/19/20 2/2/20 2/16/20 3/1/20 3/15/20 3/29/20 4/12/20 4/26/20

N
um

be
r 

of
 c

as
es

Date of onset

Unlinked

Linked

Imported



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Suleiman et alStrategies in stemming COVID-19 in Selangor, Malaysia

Fig. 2A. Distribution of cases by date of illness onset and date of exposure in a workplace cluster, Selangor, 
Malaysia (n = 126)

0

5

10

15

20

25

2/
3/

20

2/1
0/

20

2/1
7/2

0

2/
24

/2
0

3/
2/

20
3/

9/
20

3/1
6/

20

3/
23

/2
0

3/
30

/2
0

4/
6/

20

4/1
3/

20

4/
20

/2
0

4/
27

/2
0

5/4
/2

0

MCO 

Date of onset Date of exposure

Fig. 2B. Distribution of cases by date of illness onset and date of exposure in a cluster in Selangor after attendance 
at a mass religious gathering in Kuala Lumpur (n = 559)

0

10

20

30

40

50

60

70

80

90

2/1
1/2

02
0

2/1
8/2

02
0

2/2
5/2

02
0

3/3
/20

20

3/1
0/2

02
0

3/1
7/2

02
0

3/2
4/2

02
0

3/3
1/2

02
0

4/7
/20

20

4/1
4/2

02
0

4/2
1/2

02
0

4/2
8/2

02
0

Date of onset Date of exposure

MCO 1 MCO 2 MCO 3

N
u
m

b
er

 o
f 
ca

se
s

N
u
m

b
er

 o
f 
ca

se
s



WPSAR Vol 12, No 2, 2021  | doi: 10.5365/wpsar.2020.11.3.008https://ojs.wpro.who.int/ 5

Strategies in stemming COVID-19 in Selangor, MalaysiaSuleiman et al

The objective of the MCO was to reduce contact 
of potential cases with others, thereby averting wide-
spread community transmission and preventing the 
health care system from being overwhelmed by an 
influx of new patients. Extension of the MCO was made 
possible by government support through an economic 
stimulus package to ease the burden on businesses and 
individuals of the economic downturn.8 Although costly, 
MCOs were seen to slow the epidemic. An interrupted 
time-series study in Hubei and Guangdong provinces in 
China before and after lockdown showed a significant 
reduction in the incidence of cases, indicating the ef-
fectiveness of lockdown in containing the outbreak.9 A 
local modelling study with various contact rates during 
the phases of MCO found that MCO implementation 
flattened the epidemic curve,10 and the effectiveness 
of lockdown in reducing transmission rates has been 
shown by modelling elsewhere.2 It should be noted, 
however, that the decrease in the number of COVID-19 
cases in Selangor might have also been the effect of 
the combined prevention strategies, such as isolation, 
quarantine, travel bans and closure of schools and 
universities, and not the MCO alone.

The study has several limitations. As Selangor 
implemented several public health measures concur-
rently, the relative impact of each intervention could not 
be evaluated. Nevertheless, our data show a temporal 
association between trends in the epidemic curve and 
MCO implementation. Additionally, we did not directly 
assess changes in human contact behaviour before and 
during the MCO.

Our study results support the conclusion that 
MCOs, in conjunction with other public health and social 
measures, played a key role in controlling the spread of 
SARS-CoV-2 in Malaysia.

Acknowledgements

We thank the Director-General of Health Malaysia for 
his permission to publish this article. We also extend our 
gratitude to all personnel at the Selangor State Health 
Department, district health offices and Sungai Buloh 
Hospital and the Kuala Lumpur International Airport 
Health Officer for their cooperation and work in collecting 
the data for this study.

various transmission routes and mitigation measures 
suggested that lockdowns alone, particularly if short, 
will not eliminate transmission and that a combination 
of stricter measures is required.2

One of the main public health measures used to 
reduce importation of cases of COVID-19 was thermal 
body scanning and health declarations at points of 
entry. However, asymptomatic and presymptomatic 
cases can effectively shed the virus3 and are unlikely to 
be detected by screening at points of entry. One study 
showed that half of infected travellers are not detected 
during airport screening.4 In the initial workplace cluster 
in Selangor, the index case was an imported case that 
had not been detected at the point of entry. With a 
substantial proportion of asymptomatic cases (30%), 
additional control methods are required.

The initial workplace cluster in Selangor was suc-
cessfully interrupted through the public health measures 
of contact-tracing, isolation of all confirmed cases and 
home quarantine of all contacts. Contact-tracing has 
been a key public health response during previous pan-
demics of influenza and other communicable disease 
outbreaks, as it identifies potentially infected individu-
als before symptoms emerge.5 If conducted promptly, 
contact-tracing can prevent onward transmission from 
secondary cases.6 Although contact-tracing can be 
highly effective for the control of COVID-19, it places 
substantial demands on the public health authorities, as 
reported in other studies.7

The second cluster, arising from the mass gathering 
in Kuala Lumpur, involved cases all around the country 
as attendees dispersed to their respective states. In 
Selangor, contacting and then testing the large number 
of potential contacts from this event stretched the 
state’s capacity, and the response to the first cluster of 
126 cases could not be replicated for the second cluster 
of 559 cases. Therefore, the first MCO was enforced, 
resulting in a reduction in the number of new cases, 
which continued during the second and third MCOs. 
Had mass gatherings been prohibited during the ear-
lier phase of COVID-19, this outbreak could have been 
prevented. However, as a result of this cluster, MCOs 
were identified as a useful, practicable control measure, 
which can be implemented intermittently as required.



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Suleiman et alStrategies in stemming COVID-19 in Selangor, Malaysia

5. Peak CM, Childs LM, Grad YH, Buckee CO. Comparing non-
pharmaceutical interventions for containing emerging epidemics. 
Proc Natl Acad Sci USA. 2017;114(15):4023–8. doi:10.1073/
pnas.1616438114

6. Keeling MJ, Hollingsworth TD, Read JM. Efficacy of contact trac-
ing for the containment of the 2019 novel coronavirus (COV-
ID-19). J Epidemiol Community Health. 2020;74(10):861–6. 
doi:10.1136/jech-2020-214051

7. Girum T, Lentiro K, Geremew M, Migora B, Shewamare S. Global 
strategies and effectiveness for COVID-19 prevention through 
contact tracing, screening, quarantine, and isolation: a system-
atic review. Trop Med Health. 2020;48(1):91. doi:10.1186/
s41182-020-00285-w 

8. Flanders S, Nungsari M, Chuah HY. The COVID-19 hardship 
survey: An evaluation of the Prihatin Rakyat economic stimulus 
package 2020. Kuala Lumpur: Asia School of Business; 2020. 
Available from: https://asb.edu.my/research-papers/the-covid-
19-hardship-survey.

9. Figueiredo A, Codina A, Marculino de Figueiredo DC, Saez M, 
León A. Impact of lockdown on COVID-19 incidence and mortal-
ity in China: An interrupted time series study. Bull World Health 
Organ. 2020. Available from: https://www.who.int/bulletin/on-
line_first/20-256701.pdf.

10. Salim N, Chan WH, Mansor S, Bazin NEN, Amaran S, 
Mohd Faudzi AA et al. COVID-19 epidemic in Malay-
sia: Impact of lock-down on infection dynamics. medRx-
iv 2020.04.08.20057463.

Conflicts of interest

We know of no conflict of interest associated with this 
publication, and there has been no significant financial 
support for this work that could have influenced its 
outcome.

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