DARM DA study exercise group 3: Difference between revisions

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[[Category:DARM exercise]]
[[Category:DARM exercise]]
{{assessment|moderator=Carmen Gil|stub=Yes}}
{{assessment|moderator=Carmen Gil|stub=}}


For some guidance see the discussion page: {{disclink|General step-wise guidelines for making a DA study plan}}
For some guidance see the discussion page: {{disclink|General step-wise guidelines for making a DA study plan}}
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Since travel restriction for an indetermined period of time is an unrealistic measure, more feasible tools to control the spreading of the swine flu to Finland are needed. We propose the use of thermal-image scanners combined with a PCR flu test.  
Since travel restriction for an indetermined period of time is an unrealistic measure, more feasible tools to control the spreading of the swine flu to Finland are needed. We propose the use of thermal-image scanners combined with a PCR flu test.  


The symptoms of swine flu are similar to regular flu symptoms. The most common symptoms include a sudden fever, a sore throat, cough and a runny nose. The incubation period for influenza (the time between infection and appearance of symptoms) is usually 2–3 days, but symptoms may start 1–7 days from contamination. Because the fever is one of the most common symtoms of swine flu, the idea is using the thermal-image scanners to prevent swine spreding with passangers incoming to Finland. The scanners could be set up at airports and other border control points for checking all incoming travellers. Thermal scanning is a quick and non-intrusive system for mass screening of people from a distance of more than one metre. The scanners use thermal imaging to assess the skin temperatures of people as they pass through a checkpoint, and transform that data into a coloured image on a screen. The scanners will be set up so that when someone with raised body temperature or the set threshold temperature of scanner (normally above 38(?)C), passes through the testing area, his/hers features will be highlighted in a particular colour. Those who are monitoring the screen of scenner would then pull over the persons with higer body temperature for further investigation and checking whether the observed higher body temperature is really because of a fever.
The symptoms of swine flu are similar to regular flu symptoms. The most common symptoms include a sudden fever, a sore throat, cough and a runny nose. The incubation period for influenza (the time between infection and appearance of symptoms) is usually 2 days. Infected individuals are infectious for up to 10 days. Because fever is one of the most common symtoms of swine flu, the idea is using the thermal-image scanners to prevent swine flu spreading with passengers arriving from abroad in Finland. The scanners could be set up at airports and other border control points for checking all incoming passengers. Thermal scanning is a quick and non-intrusive system for mass screening of people from a distance of more than one metre. The scanners use thermal imaging to assess the skin temperatures of people as they pass through a checkpoint, and transform that data into a coloured image on a screen. The scanners will be set up so that when someone with raised body temperature, passes through the testing area, his/hers features will be highlighted in a particular colour. The threshold temperature of scanner will be above normal body temperature (37 C). Those who are monitoring the passengers passing by the scanner would then pull over the persons who are suspected to have a fever for further investigation. Whether the observed higher body temperature is really the result of fever, is needed to check and confirm by a thermometer before further tests.


After the checking and confirming of the fever, person will be quarantined, because the laboratory tests are required to confirm whether a person has been infected with influenza A(H1N1)virus. There are several methods for testing swine flue, but use of PCR-test (real-time reverse transcriptase-polymerase chain reaction, rRT-PCR) is recommended for confirmation of novel cases, because PCR-test is recognized to be one of the most effective and sensitive tests (http://www.cdc.gov/h1n1flu/specimencollection.htm). PCR-test uses a device to amplify copies of genes so researchers can easily compare a sample taken from a sick person to the genetic material of the potentially pandemic infection. Running of PCR-test in laboratory takes few days (48-96 hours: http://www.cdc.gov/h1n1flu/guidance/diagnostic_tests.htm) and during that time person who is tested will be quarantied. Although the accuracy of PCR-test is quite good: high sensitivity 86-100% (http://www.cdc.gov/h1n1flu/guidance/diagnostic_tests.htm) and specificity 99 %, the test can also provide "false negative" and "false positive" results. "False negative" is in cases where the person actually has the virus and the a negative result does not, by itself, exclude the possibility of swine flu virus infection. Another problem is that a positive result only indicates that the patient is presumptively infected with swine flu virus, but not the stage of infection.
If the fever is confirmed, the person will be quarantined/hospitalized for the time of laboratory tests that are required to confirm whether the person has really been infected with influenza A(H1N1)virus. There are several methods for testing swine flu, but use of PCR-test (real-time reverse transcriptase-polymerase chain reaction, rRT-PCR) is recommended for confirmation of novel cases, because PCR-test is recognized to be one of the most effective and sensitive tests [http://www.cdc.gov/h1n1flu/specimencollection.htm]. PCR-test uses a device to amplify copies of genes so researchers can easily compare a sample taken from a sick person to the genetic material of the potentially pandemic infection. Running of PCR-test in laboratory takes few days (48-96 hours [http://www.cdc.gov/h1n1flu/guidance/diagnostic_tests.htm]) and during that time person who is tested will be quarantied. Although the accuracy of PCR-test is quite good: high sensitivity 86-100% [http://www.cdc.gov/h1n1flu/guidance/diagnostic_tests.htm] and specificity 99 %, the test can also provide "false negative" and "false positive" results. "False negative" is in cases where the person actually has the virus and the a negative result does not, by itself, exclude the possibility of swine flu virus infection. Another problem is that a positive result only indicates that the patient is presumptively infected with swine flu virus, but not the stage of infection.


When the positive swine flu case is detected, the patient will be hospitalized and the treatment with drugs will be started. The antiviral drugs can make the illness milder and make the patient feel better faster. They may also prevent serious flu complications. Beside antivirals, supportive care in hospital, focuses on controlling fevers, relieving pain and maintaining fluid balance, as well as identifying and treating any secondary infections or other medical problems.
When the positive swine flu case is detected, the patient will be kept in quarantine at the hospital where the treatment with drugs will be started. By keeping the swine flu patients in quarantine will be prevented the swine flu speading to the Finnish population.


===Purpose===
===Purpose===


The question to be answered by this assessment is: can the use of thermal scanners combined with PCR tests prevent the spreading of swine flu to Finland if all passagers arriving to Finland will be scanner at the border control points?
The question to be answered by this assessment is: can the use of thermal scanners combined with PCR tests provide enough time before the spreading of swine flu to Finland so that the vaccine could be properly tested before starting a campaign?


===Scope===
===Scope===
This assessment is carried out to find out whether the installation of thermal scanners (and performance of PCR flu tests if fever is detected) to the Finnish airports, harbours and other border controls is a relevant system to prevent the swine flu spreading to Finland.
This assessment is carried out to find out whether the installation and use of thermal scanners (and performance of PCR swine flu tests if fever is detected) in the Finnish airports, harbours and other border controls is an useful system to considerably delay the swine flu spreading to Finland.
:The purpose of this assessment is to find out if the thermal scanners could be used for preventing the spreding of swine flu to Finland.


===Boundaries===
===Boundaries===


:Our assessment takes place in the moment (end of April 2009) when swine flu was starting to spread from Mexico, but no cases had yet been detected in Finland. At that time, The Finnish Ministry of Foreign Affairs was not issued any travel restrictions to the affected areas. The scanners would be placed in the Finnish airports, harbours and other border control points and all the passengers arriving to Finland abroad would be scanned. The scanning would be continued untill the decision about swine flu vaccination campaign in Finland will be made.
Our assessment takes place at the moment when swine flu was starting to spread from Mexico, but no cases had yet been detected in Finland (29th April 2009). At that time, The Finnish Ministry of Foreign Affairs had not issued any travel restrictions to the affected areas. The scanners would be placed in the Finnish airports, harbours and other border control points and all the passengers arriving to Finland from abroad would be scanned. The scanning of passangers would continue until the vaccine is properly tested and the decision on the swine flu vaccination campaign in Finland will be made.


===Scenarios===
===Scenarios===


1. Scanners are used and the passangers with a raised body temperature (temp. above normal temperature 37±0.5 C) are tested for swine flu infection through the PCR test and quarantined/hospitalized if test is positive.
1. Scanners are used and the passangers with a raised body temperature (above 37 C) are tested for swine flu infection through the PCR test and quarantined/hospitalized if test is positive.


2. No scanners are used and the passangers can arrive to Finland freely without monitoring and controlling possible swine flu infection.
2. No scanners are used and the passangers can arrive to Finland freely without monitoring and controlling possible swine flu infection.
Line 36: Line 35:
:The Finnish Ministry of Foreign Affairs  
:The Finnish Ministry of Foreign Affairs  
:The Finnish Ministry of Transport and Communications
:The Finnish Ministry of Transport and Communications
: The Finnish Customs
:The Finnish Ministry of Employment and Economy
:The Finnish Customs


===Participants===
===Participants===
The participants doing this assessments are: Bate Shadrak, Carmen Gil, and Minna Ruokolainen from the group 3 of Darm-course 2011
The participants doing this assessments are: Bate Shadrack, Carmen Gil, and Minna Ruokolainen from the group 3 of Darm-course 2011


==Definition==
==Definition==
:Causal diagram


[[image:Causal diagram.PNG|thumb|Add a legend for you diagram.]]
[[image:Decision tree.PNG|thumb|Decision tree.]]
[[image:Causal diagram.PNG|thumb|Causal diagram.]]


===Decision variables===
===Decision variables===


Decision variable are  
Decision variable are  
:Use of thermal scanners combined with PCR test
:Using thermal scanners combined with PCR test
:No use of thermal scanners
:Not using thermal scanners


===Indicators===
===Indicators===


Passengers infected with influenza virus H1N1 get through the passenger control points on their arrival to Finland
Fraction of passengers infected with influenza virus H1N1 that get through the control points on their arrival to Finland
 
 


===Other variables===
===Other variables===


*Swine flu incubation takes 5 days on average (from 2 to 7 days)
*Swine flu incubation: 48 hours on average
*Symptoms last for ?? days on average
*Infected individuals are infectious for up to 10 days
*Sensitivity and specificity of thermal scanner for fever
*Sensitivity of thermal scanner: 70%
*Normal body temperature (37±0.5 C) of the population that follows a normal distribution
*Specificity of thermal scanner: 92%
*Sensitivity of the PCR swine flu test: 80-100%
*Sensitivity of the PCR swine flu test: 86-100%
*Specificity of the PCR swine flu test: 99 %
*Specificity of the PCR swine flu test: 99 %
*Number and origin of passengers travelling to Finland
*Number of passengers traveling to Finland per day: 150 000 [http://www.findikaattori.fi/105/]
*Prevalence of swine flu in different countries
*Worldwide prevalence of swine flu (29th April 2009): 2.14 x 10^8
*Intake of antipyretic drugs (e.g. painkillers)
*Body temperature distribution in the population <i>(not included)</i>
*Intake of antipyretic drugs (e.g. painkillers) <i>(not included)</i>
*Spreading of the virus in Finland [http://www.ktl.fi/ttr/gen/rpt/h1n1.pdf]


=== Calculation ===
=== Calculation ===


# To estimate the fraction of arriving passengers that could be infected, we need to know the number of passengers per day, the origin and prevalence of swine flu in each country
# To estimate the accuracy of thermal scanners determining if a passenger has fever or not, we need to know the sensitivity and specificity of the scanners. The detectability of the fever would also dependent on other variables, such as the likelihood that the passenger is using antipyretic drugs and the body temperature distribution in the population; however, these are not included in our calculations. We also need to take into account the incubation time for swine flu, because during this period infected people do not yet have fever.
# To estimate the accuracy of thermal scanner determining if the passenger has fever or not, we need to know the sensitivity and specificity of the thermal scanners. The detectability of the fever is also dependent on the likelihood that passenger is using antipyretic drugs. We also need to take into account the incubation time for swine flu, because during this period infected people do not have fever. In this step we also need to know the prevalence of swine flu. It is needed to know the body temperature of population, which has a normal distribution. 
# To estimate the accuracy of the PCR-test in determining whether the fever is caused by swine flu or not, we need to know the sensitivity and specificity of this test.
# To estimate accuracy of PCR-test in determining whether the fever is caused by swine flu or not, we need to know the sensitivity and specificity of the PCR-test.
# The outcome will be expressed as the fraction of infected passengers successfully detected at the checkpoints.
# The outcomes will be expressed as expected utilities. We will assign the utility 0 for swine flu and utility 1 for healthy.
# Additionally, to estimate the fraction of arriving passengers that could be infected, we would ideally know the departure country of passengers, the numbers of passengers per day, and the prevalence of swine flu in each departure country (and how this changes through time). In this assessment we considered as examples the world prevalence of swine flu, calculated from the oficial number of cases reported [http://pib.nic.in/newsite/erelease.aspx?relid=48583] and the world population [http://www.ibiblio.org/lunarbin/worldpop] on 29th April 2009 and after the pandemic.
 
===Analyses===


EXTRA
The calculations will be done in a [[:heande:Model for DARM DA study exercise group 3|simple model]].
* Analyses: statistical and other analyses that contain two or more variables, e.g. optimizing.


==Result==
==Result==
To make a final decision we should calculate the expected utilities of using thermal scanners combined with PCR-tests or not. To make the decision of using scanners we would need the expected utility to be very close to 1. Otherwise there would be too high probability of swine flu spreading to Finland and the scanners would be useless.
To make a final decision we should calculate the expected fraction of infected travelers detected by thermal scanners combined with PCR tests. According to our model, 53.6% of infected individuals would be detected. This means that the use of scanners and PCR tests would provide about twice as much time until the epidemic arrives in Finland than if no thermal scanners and PCR tests are done at the checkpoints.  


==References==
==References==
 
:1. http://www.cdc.gov/h1n1flu/specimencollection.htm
:2,3. http://www.cdc.gov/h1n1flu/guidance/diagnostic_tests.htm
:4. http://www.findikaattori.fi/105/
:5. http://www.ktl.fi/ttr/gen/rpt/h1n1.pdf
:6. http://pib.nic.in/newsite/erelease.aspx?relid=48583
:7. http://www.ibiblio.org/lunarbin/worldpop
<references/>
<references/>

Latest revision as of 12:18, 12 April 2011



For some guidance see the discussion page: D↷

Introduction

Since travel restriction for an indetermined period of time is an unrealistic measure, more feasible tools to control the spreading of the swine flu to Finland are needed. We propose the use of thermal-image scanners combined with a PCR flu test.

The symptoms of swine flu are similar to regular flu symptoms. The most common symptoms include a sudden fever, a sore throat, cough and a runny nose. The incubation period for influenza (the time between infection and appearance of symptoms) is usually 2 days. Infected individuals are infectious for up to 10 days. Because fever is one of the most common symtoms of swine flu, the idea is using the thermal-image scanners to prevent swine flu spreading with passengers arriving from abroad in Finland. The scanners could be set up at airports and other border control points for checking all incoming passengers. Thermal scanning is a quick and non-intrusive system for mass screening of people from a distance of more than one metre. The scanners use thermal imaging to assess the skin temperatures of people as they pass through a checkpoint, and transform that data into a coloured image on a screen. The scanners will be set up so that when someone with raised body temperature, passes through the testing area, his/hers features will be highlighted in a particular colour. The threshold temperature of scanner will be above normal body temperature (37 C). Those who are monitoring the passengers passing by the scanner would then pull over the persons who are suspected to have a fever for further investigation. Whether the observed higher body temperature is really the result of fever, is needed to check and confirm by a thermometer before further tests.

If the fever is confirmed, the person will be quarantined/hospitalized for the time of laboratory tests that are required to confirm whether the person has really been infected with influenza A(H1N1)virus. There are several methods for testing swine flu, but use of PCR-test (real-time reverse transcriptase-polymerase chain reaction, rRT-PCR) is recommended for confirmation of novel cases, because PCR-test is recognized to be one of the most effective and sensitive tests [1]. PCR-test uses a device to amplify copies of genes so researchers can easily compare a sample taken from a sick person to the genetic material of the potentially pandemic infection. Running of PCR-test in laboratory takes few days (48-96 hours [2]) and during that time person who is tested will be quarantied. Although the accuracy of PCR-test is quite good: high sensitivity 86-100% [3] and specificity 99 %, the test can also provide "false negative" and "false positive" results. "False negative" is in cases where the person actually has the virus and the a negative result does not, by itself, exclude the possibility of swine flu virus infection. Another problem is that a positive result only indicates that the patient is presumptively infected with swine flu virus, but not the stage of infection.

When the positive swine flu case is detected, the patient will be kept in quarantine at the hospital where the treatment with drugs will be started. By keeping the swine flu patients in quarantine will be prevented the swine flu speading to the Finnish population.

Purpose

The question to be answered by this assessment is: can the use of thermal scanners combined with PCR tests provide enough time before the spreading of swine flu to Finland so that the vaccine could be properly tested before starting a campaign?

Scope

This assessment is carried out to find out whether the installation and use of thermal scanners (and performance of PCR swine flu tests if fever is detected) in the Finnish airports, harbours and other border controls is an useful system to considerably delay the swine flu spreading to Finland.

Boundaries

Our assessment takes place at the moment when swine flu was starting to spread from Mexico, but no cases had yet been detected in Finland (29th April 2009). At that time, The Finnish Ministry of Foreign Affairs had not issued any travel restrictions to the affected areas. The scanners would be placed in the Finnish airports, harbours and other border control points and all the passengers arriving to Finland from abroad would be scanned. The scanning of passangers would continue until the vaccine is properly tested and the decision on the swine flu vaccination campaign in Finland will be made.

Scenarios

1. Scanners are used and the passangers with a raised body temperature (above 37 C) are tested for swine flu infection through the PCR test and quarantined/hospitalized if test is positive.

2. No scanners are used and the passangers can arrive to Finland freely without monitoring and controlling possible swine flu infection.

Intended users

The intended users of assessment will be:

The Finnish Ministry of Social Affairs and Health
The Finnish Ministry of Foreign Affairs
The Finnish Ministry of Transport and Communications
The Finnish Ministry of Employment and Economy
The Finnish Customs

Participants

The participants doing this assessments are: Bate Shadrack, Carmen Gil, and Minna Ruokolainen from the group 3 of Darm-course 2011

Definition

Decision tree.
Causal diagram.

Decision variables

Decision variable are

Using thermal scanners combined with PCR test
Not using thermal scanners

Indicators

Fraction of passengers infected with influenza virus H1N1 that get through the control points on their arrival to Finland

Other variables

  • Swine flu incubation: 48 hours on average
  • Infected individuals are infectious for up to 10 days
  • Sensitivity of thermal scanner: 70%
  • Specificity of thermal scanner: 92%
  • Sensitivity of the PCR swine flu test: 86-100%
  • Specificity of the PCR swine flu test: 99 %
  • Number of passengers traveling to Finland per day: 150 000 [4]
  • Worldwide prevalence of swine flu (29th April 2009): 2.14 x 10^8
  • Body temperature distribution in the population (not included)
  • Intake of antipyretic drugs (e.g. painkillers) (not included)
  • Spreading of the virus in Finland [5]

Calculation

  1. To estimate the accuracy of thermal scanners determining if a passenger has fever or not, we need to know the sensitivity and specificity of the scanners. The detectability of the fever would also dependent on other variables, such as the likelihood that the passenger is using antipyretic drugs and the body temperature distribution in the population; however, these are not included in our calculations. We also need to take into account the incubation time for swine flu, because during this period infected people do not yet have fever.
  2. To estimate the accuracy of the PCR-test in determining whether the fever is caused by swine flu or not, we need to know the sensitivity and specificity of this test.
  3. The outcome will be expressed as the fraction of infected passengers successfully detected at the checkpoints.
  4. Additionally, to estimate the fraction of arriving passengers that could be infected, we would ideally know the departure country of passengers, the numbers of passengers per day, and the prevalence of swine flu in each departure country (and how this changes through time). In this assessment we considered as examples the world prevalence of swine flu, calculated from the oficial number of cases reported [6] and the world population [7] on 29th April 2009 and after the pandemic.

The calculations will be done in a simple model.

Result

To make a final decision we should calculate the expected fraction of infected travelers detected by thermal scanners combined with PCR tests. According to our model, 53.6% of infected individuals would be detected. This means that the use of scanners and PCR tests would provide about twice as much time until the epidemic arrives in Finland than if no thermal scanners and PCR tests are done at the checkpoints.

References

1. http://www.cdc.gov/h1n1flu/specimencollection.htm
2,3. http://www.cdc.gov/h1n1flu/guidance/diagnostic_tests.htm
4. http://www.findikaattori.fi/105/
5. http://www.ktl.fi/ttr/gen/rpt/h1n1.pdf
6. http://pib.nic.in/newsite/erelease.aspx?relid=48583
7. http://www.ibiblio.org/lunarbin/worldpop