77 
 

 

                             
RESEARCH ARTICLE 

 

Development of Web-Based GIS Alert System for Informing 

Environmental Risk of Dengue Infections in Major Cities of 

Pakistan 
Naureen Zainab 1, Aqil Tariq 2,* , Saima Siddiqui 3  

1Department of Computer Software Engineering, Military College of Signals, National 

University of Science and Technology (NUST), Islamabad, 44000, Pakistan 
2State Key Laboratory of Information Engineering in Surveying Mapping and Remote 

Sensing (LIESMARS), Wuhan University, Wuhan, 430079, China 
3Department of Geography, University of Punjab, Lahore, 54590, Pakistan 

 

Received 23 November 2020/Revised 10 March 2021/Accepted 19 March 2021/Published 25 April 2021 

 

Abstract 

Dengue is one of the emerging major public health problems, and its incidence varies with 

climate conditions. It affects millions of people's lives owing to unusual socioeconomic 

conditions and epidemiological factors. This study was designed to build a web-based GIS 

alert system for dengue data management and analysis which would centralize information 

and make it accessible to all relevant stakeholders before, during, and after crises. Three 

geographical regions were selected in this study. The user interface of the dengue alert 

system was developed based upon MapGuide. Results indicate that risk level was mainly 

associated with Breteau Index. Karachi and Lahore were at their highest risk, i.e., level 4. 

Islamabad and Chakwal were also at the highest risk, i.e., level 4. Attock had high risk, i.e., 

level 3 followed by Haripur with minimal level 1. The high Breteau Index showed a direct 

relationship to high potential transmission of dengue outbreaks, a more significant peak of 

dengue was the result of monsoons, while smaller peaks were observed due to domestic water 

storage. Hence, it was concluded that monsoon is the best suitable season for the 

development of dengue. Web-Based GIS Alert System for dengue data management and 

analysis was developed, centralizing information and making it accessible to all relevant 

stakeholders before, during & after a crisis. This program creation will provide a more 

analytical forum for advising multiple levels of risk and an experimental method for 

measuring the effect of different factors on risk level distribution by adjusting the 

component's weighting. 

 

Keywords : Dengue; GIS analysis; GUI; Alert system; Breteau index; Weighted overlay 

 

1. Introduction 

Dengue is a mosquito-borne virus whose prevalence differs with temperature and 

weather (Chang et al., 2009; Gubler, 2006). Dengue is rising as one of Pakistan's most 

significant public health problems (Asif et al., 2013). In October 2005, after ten years, dengue 

affected Karachi again, and 21 deaths were reported out of 103 confirmed cases (Mukhtar et 

al., 2011).  

 

                Geosfera Indonesia                              

*Corresponding author. 

 Email address : aqiltariq@whu.edu.cn (Aqil Tariq) 

 

 

Vol. 6 No. 1, April 2021, 77-95 

p-ISSN 2598-9723, e-ISSN 2614-8528                                                                                                                                         

https://jurnal.unej.ac.id/index.php/GEOSI          

DOI : 10.19184/geosi.v6i1.20792 

 

https://orcid.org/0000-0003-1196-1248
https://orcid.org/0000-0003-3020-0233
mailto:aqiltariq@whu.edu.cn


 

78 
 

Naureen Zainab et al. / Geosfera Indonesia 6 (1), 2021, 77-95  

 

The year 2011 was Pakistan's worst year for dengue. In 2013 the most affected area 

was the dengue fever (DF) outbreak in Pakistan. Aedes-aegypti and Aedes-albopictus is 

considered to be the main dengue vectors in South Asia, including Pakistan. The 

identification of disease outbreaks is very significant (Sirisena et al., 2017). Epidemics are 

silent in contrast to explosions. Outbreaks kill or cause sickness before detection (Kahn et al., 

1975). Disease outbreaks can easily cause such hurt, and they can spsread rapidly, too. In the 

worst scenario, the window of opportunity to minimize this harm could be limited to a few 

days (Thompson et al., 2016). The United States of America spends billions of dollars a year 

on different forms of safety surveillance. The essential expenses include patient infection 

control, public health surveillance (PHS), air and water inspection, preparation, improved 

public health, and science services in information technology (Kahn et al., 1975). Proper and 

prompt treatment of incidents of sickness can save many meaningful humans lives. 

The Breteau Index calculates the number of positive containers per hundred surveyed 

homes, which in turn represents the distribution of Aedine mosquitoes, the dengue vector ( 

Udayanga et al., 2018). An alert system was established in Pakistan from a synthesis of 

geospatial data on the Breteau Map. The interrelationship was rendered between the Breteau 

Index and the temperature. It forms the basis for creating weighted overlays to determine risk 

levels (Attaway et al., 2016). Dengue Alert System generally predicts four different risk 

levels for the risk of dengue infections, i.e., highest, high, medium, and minimal ( 

Olubadewo-Joshua & Ugom, 2019; Tran et al., 2020). Hence, a Web-based application was 

created from a synthesis of geospatial data related to Breteau Index and temperature effect in 

Pakistan's major cities. Using various weighting factors on the previous history, appropriate 

weighting factor was evaluated and used to generate the alert for informing environmental 

risk of dengue infection in major cities of Pakistan. It forms the basis for creating weighted 

overlays to determine levels of risk. The weighting can be adjusted to adjust alarm device 

sensitivity (Bowman et al., 2014).  

Every year Pakistan experiences a lot of rain during the mild summer (monsoon) 

season. The daytime temperature is greater than the night temperature. Its good climatic 

conditions for the growth of dengue mosquitos. In this study, we target six major cities of 

Pakistan because Pakistan faces a lot of problems in these regions every year. In this study, 

we clearly describe the Spatio-temporal distributions of dengue cases. The study is novel 

because its first time correlates the local predominant conditions with dengue prevalence and 

builds a web-based GIS alert system. Therefore, this study was designed to build a web-based 

GIS alert system for dengue data management and analysis which would centralize 



 

79 
 

Naureen Zainab et al. / Geosfera Indonesia 6 (1), 2021, 77-95  

 

information and make it accessible to all relevant stakeholders before, during, and after 

crises. 

 

2. Methods 

2.1. Study Area 

The study area includes Rawalpindi, Haripur, Attock, Chakwal, Lahore, and Karachi 

(figure 1). All metropolitan regions are located in different latitudes and longitude in 

Pakistan. These cities' climate is characterized by four seasons: dry, wet, hot, and cold 

(Abbas, 2013). Rawalpindi and Lahore experience a monsoonal environment with rainy, hot 

summers and cool dry winters (wet and dry season); rainfall is typical of Pakistan's semi-arid 

region. Karachi also receives Monsoon rainfall, but the landscape is different compared to 

Rawalpindi and Pakistan (Burney et al., 2018). Karachi Harbor is a secure and majestic 

natural harbor on the shores of which the town is located. A low-lying coastal area stretches 

along the harbor's edge. The Malir River, a seasonal current, flows through the eastern part of 

the city, and the seasonal Layari River runs through the northern section that is most densely 

populated. Several ridges and small hills occur; the maximum elevation, Mango Pir, is 585 

feet high. 

 

Figure 1. Study area of dengue epidemic-prone districts in Pakistan 



 

80 
 

Naureen Zainab et al. / Geosfera Indonesia 6 (1), 2021, 77-95  

 

2.2. System Design, Development, and Assumption 

The alert system had been developed to forecast the risk of infection with dengue. It 

was presumed that the two variables that were used in the method, namely temperature and 

Breteau Scale, were strongly associated with dengue fever infection sensitivity and are of 

significant geographical significance (Kaya et al., 2019). 

 

2.3 Data Source 

Data on Breteau Index and affected people from 2006 to 2013 were collected from the 

National Institute of Health and Governments Health Departments. The monthly temperature 

data from 2006 to 2013 was acquired from the Pakistan Meteorological Department of 

Islamabad.   

 

2.4 Weighted Overlay 

A web-based application was developed from a synthesis of geospatial data related to 

the Breteau Index and temperature (Cetin et al., 2019).Using various weighting factors on the 

previous history, appropriate weighting factor was evaluated and was used to generate the 

alert for informing environmental risk of dengue infection in major cities of Pakistan. The 

Breteau Index was calculated according to Eq. (1) as described by  Gubler et al. ( 2014), 

while the risk level was calculated based on the formula generated as Eq. (2). 

 

Breteau index (BI) =
Number of positive containers

 houses inspected
× 100                                                  (1) 

Risk level = BI
(60 + temperature)

40
                                                                                              (2) 

When the Breteau Index value is zero, the risk level will be zero too, even in the case 

of high temperature. For instance, in similar temperatures in two different cities, two different 

risk levels can be observed due to different Breteau indexes. 

2.5 Risk Levels 

Dengue risk levels were classified (Table 1) into four different groups based on the 

developed formula of the risk level. The Breteau Index against these four risk levels is also 

analyzed. It was assumed that if Breteau Index is high, then the risk level is also high as 

Breteau Index and risk levels are directly proportional to each other (Table 2). 

 

 



 

81 
 

Naureen Zainab et al. / Geosfera Indonesia 6 (1), 2021, 77-95  

 

Table 1. Risk levels (Gubler et al.,  2014) 

Classification Risk level 

Level 1 0<Risk level<=300 

Level 2 301<=Risk level<=600 

Level 3 600<=Risk level<=1200 

Level 4 Risk level>1200 

 

Table 2. Breteau index according to risk levels (Gubler et al.,  2014) 

Classification Risk level Breteau Index 

Level 1 0<Risk level<=300 0< BI<=4 

Level 2 301<=Risk level<=600 5<= BI <=9 

Level 3 600<=Risk level<=1200 10<= BI <=19 

Level 4 Risk level>1200 BI >=20 

 

2.6 Prevention or Management of Dengue Borne Vector for Confined Risk Level 

The adoption of integrated pest management did the management of dengue vectors at 

confined four risk levels. Integrated pest management is the pest population's level to check 

the pest below the economic injury level using all possible control measures (Novotny et al., 

2007). Recommendations regarding each risk level were given on the basis of IPsM 

strategies. There are specific preventive and control measures recommended for each alert 

level shown in Table 3. 

Table 3. Preventive measures against each risk level (Novotny et al., 2007) 

Classification Breteau Index Risk Level Actions 

Level 1 0< BI<=4 
0<Risk 

level<=300 

Intimately monitor the sanitary condition to prevent 

and manage the various breeding places. 

Weekly inspection of breeding places and likely to 

eradicate immediately. 

Try to eliminate the fresh and stagnant water pounds. 

 

Level 2 5<= BI <=9 
301<=Risk 

level<=600 

The public is advised to monitor the breeding places 

efficiently within 3-4 days and eliminate their 

possible infesting or breeding heaven within their 

premises. 

 

Level 3 10<= BI <=19 
600<=Risk 

level<=1200 

Along with regular monitoring, eliminate all possible 

breeding potential through conducting special 

operations on a regular basis. 

Launch task-oriented forces to create awareness 

among people regarding dengue elimination 

programmed.  

 

Level 4 BI >=20 
Risk 

level>1200 

Launch a task-oriented force to create awareness 

among people regarding dengue elimination 

programmed and give them responsibilities to restrain 

the potential breeding places by allotting them 

specific territories. Private competitive pest control 

and management contractor must be employed to 

control and eradicate the arising potential mosquito 

problem. 

 



 

82 
 

Naureen Zainab et al. / Geosfera Indonesia 6 (1), 2021, 77-95  

 

2.7 Conceptual Design 

The present study's concept was to build a Web-Based GIS Alert System both online 

and offline for dengue data management and analysis, centralizing the information and 

making it accessible to all relevant stakeholders before, during, and after a crisis. The system 

aimed to ensure timely availability of information on health care services. The project data 

were mapped accurately and with geographic features displayed. Maps were drawn according 

to pre-set parameters in the present framework, and then the web browser showed the map in 

a .jpeg format. The users can create and display a new map by adjusting the parameters. On 

the server-side, this sort creates a heavy load. The server-side had regional info, GIS tools, 

and a system with hundreds of complex reports on the interface (Cetin, 2015). The systematic 

conceptual diagram of the Web-Based GIS Alert System is shown in Figure 2. 

 

 

 

Figure 2. Conceptual Design of Web-Based GIS Alert System. 

 

2.8 User Interface (UI) 

MapGuide Maestro is a MapGuide open-source map authoring tool. MapGuide Maestro 

strives to support the capabilities of the open-source application MapGuide. Both spatial and 

non-spatial details have been contained in SQL Server Express, which is a free database 

service that fits well with any web application platform (Zavlavsky, 2000). The Graphical 

User Interphase (MapGuide) was systematically developed, as shown in figure 3. 

 

  



 

83 
 

Naureen Zainab et al. / Geosfera Indonesia 6 (1), 2021, 77-95  

 

 

 

 

 

 

 

 

 

 

Figure 3. Graphical User Interphase (MapGuide) 

 

2.9 Component of Web-Based GIS Alert System 

Three components of the Web-Based GIS Alert System (figure 4) were used as: 

(1) Dengue Information Databases 

(2) GIS Layers and Maps 

(3) Queries and Reports 

 

 

 

 

 

 

 

 

 

 Figure 4. Components of Web-Based GIS alert system 

Overall, the system describes the risk levels of dengue infection in major cities of 

Pakistan, classifying them into three geographical regions. A web-based application was 

created from a synthesis of geospatial data related to the Breteau index and temperature effect 

in Pakistan's major cities. Currently, statistics on the Breteau Index and temperature are 



 

84 
 

Naureen Zainab et al. / Geosfera Indonesia 6 (1), 2021, 77-95  

 

displayed in a table format that is difficult for interpretation by general users. This project 

allows the visualization of the Breteau Index and temperature information in a spatial pattern 

and association with four risk levels, which enhances public awareness. Dengue Alert System 

describes the risk level of dengue infections from 2006 to 2013 in major cities of Pakistan. It 

can also predict the current risk level of dengue in any district of Pakistan. It can predict four 

different risk levels for the risk of dengue infections, i.e., highest, high, medium, and 

minimal. 

3. Results and Discussion  

3.1 Temporal Changes in Temperature and Breteaux Index 

A good association between the two variables has been identified from the temporal 

change in temperature and the Breteau Scale (Bozdogan et al., 2021). Higher Breteau Index 

focused primarily in the summer and autumn when higher temperatures prevailed. Results 

shown in Figure 5a indicate the temporal changes in Breteau Index in September 2010 in 

selected study sites. The Breteau Index of Lahore and Islamabad represented by Green color 

was high. The Breteau Index of Karachi denoted by Blue color was medium. The Breteau 

Index of Chakwal and Haripur represented by Yellow color was minimal, and the Breteau 

Index of Attock represented by Gray showed no risk. Similarly, the temporal changes in 

temperature in major cities of Pakistan Figure 5b indicate that Karachi had high temperature 

while the remaining cities showed low temperature.  

The high temperature was represented by Dark Gray color, and Low temperature was 

represented by Light Gray. The effect of temperature on the weighted overlay product can be 

calculated when the temperature and the Breteaux index are overlaid. The temperature was 

not considered to be the main factor deciding the level of risk according to the given 

weighting, and when the Breteau Scale equals zero, the risk level was also zero, irrespective 

of the temperature increase. The cities with a high Breteau Index are at a higher risk level. 

Lahore and Islamabad's temperature was low compared to Karachi, but they had a high-risk 

level due to the high Breteau Index. Breteau Index of Attock was zero, so there was no risk; 

however, the Attock temperature was 28oC, similar to Chakwal 27.6oC.  



 

85 
 

Naureen Zainab et al. / Geosfera Indonesia 6 (1), 2021, 77-95  

 

 

Figure 5a. Breteau Index of September 2010 in major cities of Pakistan, Figure 4b. 

Temperature of September 2010 in major cities of Pakistan, Figure 4c. Breteau Index of 

September 2011 in major cities of Pakistan, Figure 4d. Temperature of September 2011 in 

major cities of Pakistan. 

 

Figure 5c and Figure 5d show the Breteau Index and temperature of September 2011 

in selected study sites. Attock and Haripur very high followed the Breteau Index of Karachi, 

Lahore, Islamabad, Rawalpindi, and Chakwal. The temperature of Karachi and Lahore was 

high as compared to other cities. Figure 5d represents that Karachi and Lahore were at their 

highest risk and the temperature of these two cities was also high. Rawalpindi, Islamabad, 

and Chakwal were also at the highest risk, but they had a low temperature as compared to 

Karachi and Lahore. Attock had high risk, and the temperature was low. Haripur showed 

minimal risk and had a low temperature. Rawalpindi and Attock's temperature showed a 

similar trend but had different risk levels due to different Breteau Index. 

Web-based generated map of the Risk Levels of Dengueshows that risk level was 

high in those cities which had high Breteau Index. Results indicate that Karachi and Lahore 

were at their highest risk, i.e., level 4. Islamabad and Chakwal were also at the highest risk, 



 

86 
 

Naureen Zainab et al. / Geosfera Indonesia 6 (1), 2021, 77-95  

 

i.e., level 4. Attock had high risk, i.e., level 3 followed by Haripur with minimal level 1. 

Hence, it is concluded that risk level was mainly associated with Breteau Index, if Breteau 

Index was high, then the risk level was also high, so this is the main reason for which the 

highest weightage is assigned to the Breteau Index (Gungor et al., 2020). Temperature also 

plays a significant role because the risk level was high in mostly the summer months, which 

had a high temperature. If the temperature was high, mosquito's growth rates were also high 

because high temperature helps in breeding Aedes aegypti and Aedes albopictus mosquitoes. 

  

3.2 Peaks of Dengue Based on the Analysis of Risk Levels from 2006- 2013 in Major Cities 

of Pakistan 

Results from the analysis of dengue risk levels from 2006 to 2013 in major cities of 

Pakistan indicated that the high risk of dengue from 2006 to 2013 was mostly observed in the 

month of September, October, and November (Table 4). The dengue-related deaths were 

reported between the months from September to November. Dengue case-load registered 

during these months, and the reports declined rapidly during and after December. The high 

Breteau Index showed a major direct relationship to the high potential transmission of dengue 

outbreaks in the study sites. Two peaks of dengue were shown in the form of risk levels. The 

formation of a more significant peak of dengue resulted from monsoon rains in which water 

was filled at the low-lying places. Smaller peaks of dengue were formed in the dry season 

due to domestic storage of water. It was seen that transmission of dengue during the monsoon 

and after monsoon was maximum than that of the dry season. Finally, it was concluded that 

monsoon is the best suitable season for the reproduction, fecundity, survival, growth, and 

development of dengue. 

Dengue fever is estimated to affect 50 to 100 million people with 1/2 million life-

threatening infections globally in a year as of 2010. It has risen 30-fold significantly in 

frequency between 1960 and 2010. In Pakistan in the year 2010, there were more than 7000 

positive confirmed cases of dengue.With rising epidemics, dengue fever has become a 

significant disease in Pakistan. Given Pakistan's government's efforts, especially in Punjab, 

the high treatment cost has hindered Pakistan's ability to control epidemics. Dengue-fever 

mortality in Pakistan in the summer of 2011 was over 300 people, and epidemic incidence 

was over 14,000 infections. The outbreaks mainly occurred in the region of Lahore, Punjab, 

Pakistan. 

 

 

 



 

87 
 

Naureen Zainab et al. / Geosfera Indonesia 6 (1), 2021, 77-95  

 

 

 

Table 4. Results from the analysis of dengue risk levels from 2006 to 2013 in major cities of 

Pakistan 

 

City Dengue Risk 2006 2007 2008 2009 2010 2011 2012 2013 

K
a

r
a
c
h

i 

Duration 

Jan 

Apr 

Jul 

Aug 

- 

Jan, 

Sep 

to 

Dec 

Aug 

to 

Dec 

Jan 

Apr 

Aug 

to 

Dec 

Jan 

Apr 

to 

Dec 

Jan 

to 

Dec 

All 

over 

the year 

Minimum 

Jan 

Apr 

Jul 

Aug 

Jul 

Dec 
Jan 

Jan 

Aug 

Sep 

Dec 

Jan 

Apr 

Aug 

Dec 

Jan 

Apr 

to 

Jul 

Jan 

to 

Sep 

Jan 

to 

Aug 

Dec 

Moderate 
Sep 

 
Sep 

Sep 

Dec 
- Sep 

Aug 

Nov 

Dec 

Dec Sep 

Highest 
Oct 

Nov 

Oct 

Nov 

Oct 

Nov 

Oct 

Nov 

Oct 

Nov 

Sep 

Oct 

Oct 

Nov 

 

Oct 

Nov 

          

L
a
h

o
r
e
 

Duration - - 

Jan 

Aug 

to 

Dec 

Sep 

Dec 

Jul 

Dec 

Apr 

Dec 

Apr 

Aug 

to 

Dec 

Mar 

to 

Dec 

Minimum 

Jul 

Aug 

Sep 

Dec 

Dec 

Jan, 

Aug 

Dec 

Dec 

Jul 

Aug 

Dec 

Apr 

Jul 

Apr 

Aug 

Dec 

Mar 

to 

July 

Sep 

Moderate Oct 
Sep 

Oct 
Sep 

Sep 

Oct 
Sep 

Aug 

Nov 

Dec 

Sep 
Aug 

Dec 

Highest Nov Nov 
Oct 

Nov 
Nov 

Oct 

Nov 

Sep 

Oct 

Oct 

Nov 

Oct 

Nov 

  
        

A
tt

o
c
k

 

Duration - - 

Oct 

to 

Dec 

Oct 

to 

Dec 

Oct 

Nov 

July  

Sep 

to 

Dec 

- - 

Minimum Sep Sep Dec Dec  
Jul 

Dec 
- Nov 

Moderate 

Oct 

Nov 

 

Oct 

Nov 
Oct Oct Oct 

Sep 

Nov 
- - 

Highest - - Nov Nov Nov Oct - - 

 Continued         

           

           

           

          
          



 

88 
 

Naureen Zainab et al. / Geosfera Indonesia 6 (1), 2021, 77-95  

 

          

City Dengue Risk 2006 2007 2008 2009 2010 2011 2012 2013 
R

a
w

a
lp

in
d

i 

Duration - - 

Sep 

To 

Dec 

Sep 

to 

Dec 

Sep  

Dec 

Jun 

to 

Dec 

- 

Jun 

to 

Dec 

Minimum 
Jul 

Aug 
Aug Dec Dec 

Sep 

Dec 

Jun 

Jul 

Aug 

- 

Jul 

Aug 

Dec 

Moderate Oct 
Sep 

Oct 
Sep 

Sep 

Oct 
 

Nov 

Dec 
- Sep 

Highest Nov Nov 
Oct 

Nov 
Nov 

Oct 

Nov 

Sep 

Oct 
- 

Oct 

Nov 

          

Is
la

m
a

b
a

d
 

Duration 

Aug 

to 

Dec 

- 

Sep 

to 

Dec 

Sep 

to 

Nov 

Sep 

to 

Dec 

Jun 

to 

Dec 

- 

Aug 

to 

Dec 

Minimum - - Dec Sep Dec 

Jun 

Jul 

Aug 

Dec 

Aug 

to 

Nov 

Aug 

Sep 

Dec 

Moderate 
Sep 

Oct 
Oct Sep  

Sep 

Oct 
Nov - Oct 

Highest Nov Nov 
Oct 

Nov 

Oct 

Nov 
Nov 

Sep 

Oct 
- Nov 

          

H
a
r
ip

u
r
 

Duration 

Sep 

to 

Nov 

 

 
Oct 

Nov 

Sep 

to 

Nov 

Apr 

Jul 

to 

Dec 

- - - 

Minimum Dec Dec Dec Sep 

Apr 

Jul 

Aug 

Sep  

Dec 

Sep 

Oct 

Sep 

Oct 

Nov 

- 

Moderate Oct Sep Oct - Oct - - - 

Highest Nov 
Oct, 

Nov 
Nov 

Oct 

Nov 
Nov - - - 

  
        

C
h

a
k

w
a

l 

Duration - - 
No 

Case 

Jan 

Nov 

Sep 

to 

Nov 

Sep 

to 

Nov 

- - 

Minimum 
Oct, 

Nov 
Sep - - 

Sep  

Nov 
- - - 

Moderate - 
Oct, 

Nov 
- Jan Oct 

Oct 

Nov 
- - 

Highest Nov - - Nov - Sep - - 

Note : - = No case 

 



 

89 
 

Naureen Zainab et al. / Geosfera Indonesia 6 (1), 2021, 77-95  

 

 

3.3 Application - Web-Based GIS Alert System 

For Web-Based GIS Alert System application, a user can select URL 

localhost/dengue. The Dengue Support System will display. For login purposes, the user can 

click on the Login option. Before getting detailed information, the customer will be asked to 

enter the ID and password. If the user identification and password are wrongly entered, an 

error message will pop up, "Your attempt to login is not successful. Please try again," and the 

user will be asked to register until the correct information is typed in. This system would help 

to protect data security under study. The existing database had included eight years' data. The 

application was developed monthly, so a first select year and then the month, and then 

click/check the risk levels. Database contents and collections could be expanded in the future. 

After selecting the month and the year, the selected year's risk level will be displayed. Users 

can also zoom the areas concerned by clicking on the option Zoom Rectangle. This feature 

provides the consumer a general understanding of the environment impacted and theoretically 

affected. 

One of the most important functions of this system was to find the current risk level of 

any district based upon the Breteau Index and temperature. By entering the Breteau Index and 

temperature, the system can find the current risk level of dengue of any Pakistan district by 

selecting the district in the drop-down list. Results shows that the user selected district 

Faisalabad entered Breteau Index 7.53 and temperature 21.4 and then clicked on Select, the 

risk level of Faisalabad was displayed. The blue color represents that it was at level 2.  

 The Dengue Alert System was capable of generating the reports of Risk levels of each 

month. The reports of the Risk level of dengue in September 2011 along with "Actions to be 

taken" at each level. The system was also capable of generating the Graphical representation 

of the Risk Level of each month (figure 6). 

 
 

Figure 6. Graphical representation of risk level of September 2011 

1741.9

254.15

2044.5

1456.18 1457.7
1342.7

0

500

1000

1500

2000

2500

Chakwal Haripur Islamabad Karachi Lahore Rawalpindi

Series1Risk level



 

90 
 

Naureen Zainab et al. / Geosfera Indonesia 6 (1), 2021, 77-95  

 

It has been seen from the data and observed that high dengue indicators are in August, 

September, October, and November, i.e., after July, which have a high temperature in 

Pakistan. If the Breteau Scale is 0, the risk level will also be zero, regardless of how high the 

temperature is. It is concluded that risk level is mainly associated with breteau index, if 

breteau index is high, then risk level is also high, so this is the main reason due to which 

highest weightage is assigned to breteau index, but temperature also plays a significant role 

because risk level is high in mostly the months which have a high temperature. If the 

temperature is high, mosquito growth chances are also high because high temperature helps 

in the breeding of Aedine mosquitoes. There is no chance even if the temperature is very high 

without the existence of Aedine mosquitoes. For instance, if the temperature is similar for 

two cities, they have very different risk levels. 

The device may be combined with other potential factors. Human population growth 

is a significant dengue consideration because the desert region containing many mosquitoes is 

not dangerous. If the weather around the house is suitable for dengue, then dengue infections 

will be high. The moisture and containers may be important influences. Eventually, mosquito 

species often play a part. The system is not without limitations. It is a web-based application, 

and for this application, internet connectivity must require. If the internet speed is slow, this 

application will not work properly because it requires high bandwidth. 

According to dengue outbreaks, the likelihood of dengue is caused by many variables 

in real life including the virus and the climate. The application of temperature and breteau 

index offers one element of risk assessment, concentrating on exposure impact calculation 

alone. Certain considerations might be applied to the system's robustness. 

Similar results/an online alert system (GIS) were developed. The interrelationship 

between various indices and temperature was measured by Wong et al., (2007), who observed 

that the inference forms the rationale for the generation of weighted overlays to define risk 

levels. Weighting can be adjusted to set the sensitivity of the alert system. They concluded 

that the alert system offers one objective means to defining the risk of dengue in a society, 

which would not be affected by the incidence of the infection itself 

Similarly, Shen et al. (2015) conducted a study to explore the associations between 

the monthly number of dengue fever (DF) cases and possible risk factors in Guangzhou, a 

subtropical city of China. In their study, a total of 39,697 DF cases were detected in 

Guangzhou. Dengue fever incidence showed an obvious seasonal pattern, with most cases 

occurring from June to November. They observed that the current month's Breteau Index, 

average temperature, previous month's minimum temperature, and Tave were positively 



 

91 
 

Naureen Zainab et al. / Geosfera Indonesia 6 (1), 2021, 77-95  

 

associated with Dengue fever incidence. They also concluded that the mosquito density, 

Tave, and Tmin play a critical role in dengue fever transmission in Guangzhou.  

In another study, Liyanage et al., (2019) used an interrupted time-series design with a 

non-linear extension, and evaluated the impact of vector control interventions from June 22, 

2014, to Dec 29, 2016, in Panadura, a high-risk MOH division in Western Province, Sri 

Lanka. They used dengue notification and larval survey data to estimate the reduction in 

Breteau index and dengue incidence before and after the intervention using two separate 

models, adjusting for time-varying confounding variables (i.e., rainfall, temperature, and the 

Oceanic Niño Index). They found that Breteau index is an essential index for controlling and 

measuring the extent of vector control in dengue transmission. 

Bajwala et al (2020) conducted a study using mean temperature (°C), relative 

humidity (%), and precipitation (rainfall in mm) as climatic parameters affecting vector 

ecology. They recorded the peak number of cases was recorded in the post-monsoon period. 

They proposed that presence of some serologically positive cases even during dry months in 

this study could probably be reflective of the year-round activity of the dengue vector. 

Moreover, some advanced techniques, i.e., artificial intelligence-based mathematical 

model and fuzzy logic, could be a suitable option to implement control measures in dengue-

prone areas. Adak & Jana (2021) developed an artificial intelligence-based mathematical 

model taking the three stegomyia indices, namely house index, Breteau index, and container 

index. 

The project's concept was to build a Web-Based GIS Alert System for dengue data 

management and analysis, centralizing information and making it accessible to all relevant 

stakeholders before, during & after a crisis situation. The system aims to ensure timely 

availability of information on health care services and project data, mapped accurately and 

with geographic features displayed, designed an alert system for users to visualize the spatial 

distribution of the risk of exposure to Aedine mosquito in the local setting. The system 

complements information on the incidence of infection and is a more objective way of 

defining risk levels. Overall, the system describes the risk levels of dengue infection in major 

cities of Pakistan, classifying them into three geographical regions, and can predict all 

Districts of Pakistan's risk levels. A web-based application was created from a synthesis of 

geospatial data related to Breteau index and temperature effect in Pakistan's major cities. 

Future alignment of this program with practices of prevention and control of dengue 

fever will be important. This pilot project may be associated with the various government 

departments involved. Similar systems could be built and adapted to estimate exposure to 

other diseases, such as bird flu, for which environmental factors are critical for propagation. 



 

92 
 

Naureen Zainab et al. / Geosfera Indonesia 6 (1), 2021, 77-95  

 

The program could become a tool for local, regional, and even national health authorities and 

other stakeholders in the long run. 

 

4. Conclusion 

The user interface of the dengue alert system was developed based upon MapGuide. 

The inter-relationship between Breteau Index and the temperature was developed using a 

web-based GIS application. Four different patterns mapping were developed for the risk of 

dengue, i.e., highest, high, medium, and minimal. Maps were created using pre-set criteria, 

and the map was shown as an image by the web browser.A high risk of dengue was found in 

August, September, October, and November, i.e., after July, in which had high temperature 

was noted. Risk level was found mainly associated with Breteau Index; if Breteau Index was 

high, then risk level was also high. When the Breteau Index equals zero, the risk level was 

zero, irrespective of the temperature rise. Temperature also played a significant role because 

the risk level was high, mainly in the months with high temperatures. There was no risk 

without Aedine mosquitoes' presence even if the temperature was very high. For instance, if 

the temperature was similar for two cities, they depicted very different risk levels. This 

study's significance is introducing a new method for expressing the alert system on a spatial 

scale. The web-based Alert system should no longer be expressed in statistical and textual 

formats, but that spatial graphics could be incorporated. In addition, the weighted overlay 

allows the users to weigh the contribution of factors affecting the exposure risk to dengue. 

Conflict of Interest  

The authors declare that there is no conflict of interest.  

Acknowledgments 

Authors gratefully acknowledge the support received from Dr. Mukhtar Senior 

Scientific Officer (Entomology), Ex. Head of Department of Zoonotic and Vector-Borne 

Diseases and thanks to Dr Jan Muhammad Director Pakistan Meteorological Department for 

monthly mean temperature data. We are thankful to Dr. M. Farrukh Sultan, DPC, EDOH, 

Lahore. The authors would also like to express their appreciation to Rana Naveed Mustafa 

(NARC), Naveed Yaqoob, Department of Mathematics, QAU Islamabad and Azmat Ali Sr. 

Project Manager ERP (IT/MIS) at Agribusiness Support Fund for their kind cooperation. This 

research was supported by the National Natural Science Foundation of China (No. 

41871345). 

 



 

93 
 

Naureen Zainab et al. / Geosfera Indonesia 6 (1), 2021, 77-95  

 

References 

Abbas, F. (2013). Analysis of a historical (1981-2010) temperature record of the Punjab 

Province of Pakistan. Earth Interactions, 17(15), 1–23. 

https://doi.org/10.1175/2013EI000528.1. 

 

Adak, S., & Jana, S. (2021). A study on stegomyia indices in dengue control: a fuzzy 

approach. Soft Computing - A Fusion of Foundations, Methodologies and 

Applications, 25(1), 699–709. https://doi.org/10.1007/s00500-020-05179-x. 

 

Asif, M., Tripathi, N. K., & Ahmed, S. (2013). Towards Near Real Time Public Health 

Surveillance  (A Decision Support System for  Public Health Surveillance). 

International Journal of Computer Applications, 61(21), 45–50. 

 

Attaway, D. F., Jacobsen, K. H., Falconer, A., Manca, G., & Waters, N. M. (2016). Risk 

analysis for dengue suitability in Africa using the ArcGIS predictive analysis tools (PA 

tools). Acta tropica, 158, 248-257. https://doi.org/10.1016/j.actatropica.2016.02.018. 

 

Bajwala, V. R., John, D., Rajasekar, D., Eapen, A., & Murhekar, M. V. (2020). Burden of 

Dengue with Related Entomological and Climatic Characteristics in Surat City, Gujarat, 

India, 2011–2016: An Analysis of Surveillance Data. The American journal of tropical 

medicine and hygiene, 103(1), 142-148. https://doi.org/10.4269/ajtmh.19-0967. 

 

Bowman, L. R., Runge-Ranzinger, S., & McCall, P. J. (2014). Assessing the Relationship 

between Vector Indices and Dengue Transmission: A Systematic Review of the 

Evidence. PLoS Neglected Tropical Diseases, 8(5). 

https://doi.org/10.1371/journal.pntd.0002848. 

 

Bozdogan Sert, E., Kaya, E., Adiguzel, F., Cetin, M., Gungor, S., Zeren Cetin, I., & Dinc, Y. 

(2021). Effect of the surface temperature of surface materials on thermal comfort: a case 

study of Iskenderun (Hatay, Turkey). Theoretical and Applied Climatology, 1–11. 

https://doi.org/10.1007/s00704-021-03524-0. 

 

Cetin, M. (2019). The effect of urban planning on urban formations determining bioclimatic 

comfort area’s effect using satellitia imagines on air quality: a case study of Bursa 

city. Air Quality, Atmosphere & Health, 12(10), 1237-1249. 

https://doi.org/10.1007/s11869-019-00742-4. 

 

Cetin, M., Adiguzel, F., Gungor, S., Kaya, E., & Sancar, M. C. (2019). Evaluation of thermal 

climatic region areas in terms of building density in urban management and planning for 

Burdur, Turkey. Air Quality, Atmosphere & Health, 12(9), 1103-1112. 

https://doi.org/10.1007/s11869-019-00727-3. 

 

Cetin, M. (2015). Using GIS analysis to assess urban green space in terms of accessibility: 

case study in Kutahya. International Journal of Sustainable Development & World 

Ecology, 22(5), 420-424. https://doi.org/10.1080/13504509.2015.1061066. 

 

Chang, A. Y., Parrales, M. E., Jimenez, J., Sobieszczyk, M. E., Hammer, S. M., Copenhaver, 

D. J., & Kulkarni, R. P. (2009). Combining google earth and GIS mapping technologies 

in a dengue surveillance system for developing countries. International Journal of 

https://www.ijcaonline.org/archives/volume61/number21/10216-5083


 

94 
 

Naureen Zainab et al. / Geosfera Indonesia 6 (1), 2021, 77-95  

 

Health Geographics, 8(1), 1–11. https://doi.org/10.1186/1476-072X-8-49. 

 

Gubler, D. J. (2006). Dengue/dengue haemorrhagic fever: history and current status. 

In Novartis foundation symposium (Vol. 277, p. 3). Chichester; New York; John Wiley.  

 

Gubler, D. J., Ooi, E. E., Vasudevan, S., & Farrar, J. (2014). Dengue and dengue 

hemorrhagic fever. Oxfordshire : CABI. 

 

Gungor, S., Cetin, M., & Adiguzel, F. (2020). Calculation of comfortable thermal conditions 

for Mersin urban city planning in Turkey. Air Quality, Atmosphere and Health, 1–8. 

https://doi.org/10.1007/s11869-020-00955-y. 

 

Kahn, T. C., Cameron, J. T., & Giffen, M. B. (1975). Methods and evaluation in clinical and 

counseling psychology. Elmsford, NY: Pergamon Press. 

 

Kaya, E., Agca, M., Adiguzel, F., & Cetin, M. (2019). Spatial data analysis with R 

programming for environment. Human and Ecological Risk Assessment, 25(6), 1521–

1530. https://doi.org/10.1080/10807039.2018.1470896. 

 

Liyanage, P., Rocklöv, J., Tissera, H., Palihawadana, P., Wilder-Smith, A., & Tozan, Y. 

(2019). Evaluation of intensified dengue control measures with interrupted time series 

analysis in the Panadura Medical Officer of Health division in Sri Lanka: a case study 

and cost-effectiveness analysis. The Lancet. Planetary Health, 3(5), e211–e218. 

https://doi.org/10.1016/S2542-5196(19)30057-9. 

 

Mukhtar, M., Tahir, Z., Baloch, T., Mansoor, F., & Kamran, J. (2011). Entomological 

investigations of dengue vectors in epidemic-prone districts of Pakistan during 2006–

2010. World Health Organization Regional Publications. South East Asia Series. 

 

Novotny, V., Miller, S. E., Hulcr, J., Drew, R. A. I., Basset, Y., Janda, M., … Weiblen, G. D. 

(2007). Low beta diversity of herbivorous insects in tropical forests. Nature, 448(7154), 

692–695. https://doi.org/10.1038/nature06021. 

 

Olubadewo-Joshua, O., & Ugom, K. M. (2019). Application of Geospatial Techniques in the 

Locational Planning of Health Care Centers in Minna, Nigeria. Geosfera Indonesia, 

3(3), 59-72. https://doi.org/10.19184/geosi.v3i3.8754. 

 

Shen, J. C., Luo, L., Li, L., Jing, Q. L., Ou, C. Q., Yang, Z. C., & Chen, X. G. (2015). The 

impacts of mosquito density and meteorological factors on dengue fever epidemics in 

Guangzhou, China, 2006-2014: A time-series analysis. Biomedical and Environmental 

Sciences, 28(5), 321–329. https://doi.org/10.3967/bes2015.046. 

  

Sirisena, P., Noordeen, F., Kurukulasuriya, H., Romesh, T. A., & Fernando, L. K. (2017). 

Effect of climatic factors and population density on the distribution of dengue in Sri 

Lanka: A GIS based evaluation for prediction of outbreaks. PloS One, 12(1), e0166806. 

https://doi.org/10.1371/journal.pone.0166806. 

Burney, S. A., Barakzai, M. A. K., & James, S. E. (2020). Forecasting Monthly Maximum 

Temperature of Karachi City using Time Series Analysis. Pakistan Journal of 

Engineering, Technology & Science, 7(2). https://doi.org/10.22555/pjets.v7i2.2439. 

 

https://onlinelibrary.wiley.com/doi/book/10.1002/0470058005#page=13
https://books.google.co.id/books?hl=id&lr=&id=Tl_YBAAAQBAJ&oi=fnd&pg=PR5&dq=gubler+dengue+2014&ots=CTlAVgEMxI&sig=PoApGUM45GPXtfHkXsJe09KnNJE&redir_esc=y#v=onepage&q=gubler%20dengue%202014&f=false
https://books.google.co.id/books?hl=id&lr=&id=Tl_YBAAAQBAJ&oi=fnd&pg=PR5&dq=gubler+dengue+2014&ots=CTlAVgEMxI&sig=PoApGUM45GPXtfHkXsJe09KnNJE&redir_esc=y#v=onepage&q=gubler%20dengue%202014&f=false
https://www.sciencedirect.com/book/9780080178622/methods-and-evaluation-in-clinical-and-counseling-psychology
https://www.sciencedirect.com/book/9780080178622/methods-and-evaluation-in-clinical-and-counseling-psychology
https://apps.who.int/iris/bitstream/handle/10665/171002/db2011v35p99.pdf;jsessionid=455D9654C6994338D775C931E795E6EF?sequence=1
https://apps.who.int/iris/bitstream/handle/10665/171002/db2011v35p99.pdf;jsessionid=455D9654C6994338D775C931E795E6EF?sequence=1
https://apps.who.int/iris/bitstream/handle/10665/171002/db2011v35p99.pdf;jsessionid=455D9654C6994338D775C931E795E6EF?sequence=1


 

95 
 

Naureen Zainab et al. / Geosfera Indonesia 6 (1), 2021, 77-95  

 

 

Thompson, R. N., Gilligan, C. A., & Cunniffe, N. J. (2016). Detecting Presymptomatic 

Infection Is Necessary to Forecast Major Epidemics in the Earliest Stages of Infectious 

Disease Outbreaks. PLoS Computational Biology, 12(4). 

https://doi.org/10.1371/journal.pcbi.1004836. 

 

Tran, B. L., Tseng, W. C., Chen, C. C., & Liao, S. Y. (2020). Estimating the threshold effects 

of climate on dengue: A case study of Taiwan. International Journal of Environmental 

Research and Public Health, 17(4), 1–17. https://doi.org/10.3390/ijerph17041392. 

 

Udayanga, L., Gunathilaka, N., Iqbal, M. C. M., Najim, M. M. M., Pahalagedara, K., & 

Abeyewickreme, W. (2018). Empirical optimization of risk thresholds for dengue: An 

approach towards entomological management of Aedes mosquitoes based on larval 

indices in the Kandy District of Sri Lanka. Parasites and Vectors, 11(1), 368. 

https://doi.org/10.1186/s13071-018-2961-y. 

 

Wong, N. S., Law, C. Y., Lee, M. K., Lee, S. S., & Lin, H. (2007). An Alert System for 

Informing Environmental Risk of Dengue Infections. In P. C. Lai & A. S. H. Mak 

(Eds.), GIS for Health and the Environment: Development in the Asia-Pacific Region 

With 110 Figures (pp. 171–183). Springer Berlin Heidelberg. 

https://doi.org/10.1007/978-3-540-71318-0_12. 

 

Zavlavsky, I. (2000). A New Technology for Interactive Online Mapping with Vector 

Markup and XML. Cartographic Perspectives, 0(37), 65-77–77. 

https://doi.org/10.14714/CP37.810.