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In today’s world where we are still having trouble foreseeing events such as earthquakes and disease outbreaks, our team decided to focus on finding a way to predict one of these problems and, ~~therefore~~, prevent it from happening. As the center of our study, we chose arboviruses, mosquito-borne viruses which often cause severe diseases in humans. These viruses are spreading at an alarming rate on a global scale ~~thanks~~ to mosquitoes, their vectors. Currently, the most common method of fighting against the dissemination of the vectors and the viruses are insecticides, which ~~proved~~ to be extremely damaging to the environment. In addition to that, mosquitoes tend to develop resistance against these insecticides, which diminishes their efficiency even more.

+

In today’s world where we are still having trouble foreseeing events such as earthquakes and disease outbreaks, our team decided to focus on finding a way to predict one of these problems and, thereby, prevent it from happening. As the center of our study, we chose arboviruses, mosquito-borne viruses which often cause severe diseases in humans. These viruses are spreading at an alarming rate on a global scale due to mosquitoes, their vectors. Currently, the most common method of fighting against the dissemination of the vectors and the viruses are insecticides, which haven proven to be extremely damaging to the environment. In addition to that, mosquitoes tend to develop resistance against these insecticides, which diminishes their efficiency even more.

Our project consists out of a kit named MOS(KIT)O, containing:

<SPACER>• A mosquito trap</SPACER>

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The diagnostic patch is biosilica-based and allows a quick detection of viruses in mosquitoes, by first depositing a mosquito lysate, produced by the trap, onto the patch. This system is quick and easy to use by local administrations and allows them to create a detailed real-time mapping of the territories populated with infected mosquitoes.

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So our project consists in the development of a better mapping tool of vector-borne diseases to specifically target insecticide spreading in infected areas only, to facilitate rapid diagnosis, and significantly improve the prevention ~~against~~ these diseases before outbreak appearance. To do that, we engineered a dual system capable of ensuring both the capture of mosquitoes and also the detection of the presence or absence of virus in these vectors.

+

So our project consists in the development of a better mapping tool of vector-borne diseases to specifically target insecticide spreading in infected areas only, to facilitate rapid diagnosis, and significantly improve the prevention of these diseases before outbreak appearance. To do that, we engineered a dual system capable of ensuring both the capture of mosquitoes and also the detection of the presence or absence of virus in these vectors.

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With the assistance of synthetic biology, we successfully modified E. coli, within a contained fully functioning biosafety laboratory. With it, we produce a novel fusion protein needed to create biosilica, and bind antibodies onto a cellulose support. We selected biosilica to increase rigidity of our patch and because it is completely biodegradable. The innovative design of the patch creates a multilayered matrix coated with antibodies capable of detecting a wide panel of vector-borne pathogens (like Zika, Chikunguya, Dengue, Yellow Fever…) and insecticide resistant proteins from captured mosquitoes.

+

With the assistance of synthetic biology, we successfully modified E. coli, within a contained fully functioning biosafety laboratory. With it, we produce a novel fusion protein needed to create biosilica, and bind antibodies onto a cellulose support. We selected biosilica to increase rigidity of our patch and because it is completely biodegradable. The innovative design of the patch creates a multilayered matrix coated with antibodies capable of detecting a wide panel of vector-borne pathogens (like Zika, Chikunguya, Dengue, Yellow Fever…) and insecticide-resistant proteins from captured mosquitoes.

−

As a result of these three functions, the protein is able to specifically catch viral proteins. And with a simple marking solution, it reveals the presence of the virus. Our novel protein is integrated into a cellulose patch giving a user friendly detection device. It is rigid, easy to ~~be manipulated~~, and made from a new composite biomaterial. In addition, by choosing the antibody that we fix on the protein BpA, we choose the virus that we want to detect (Zika, Chikunguya, Dengue, Yellow Fever…).

+

As a result of these three functions, the protein is able to specifically catch viral proteins. And with a simple marking solution, it reveals the presence of the virus. Our novel protein is integrated into a cellulose patch giving a user friendly detection device. It is rigid, easy to manipulate, and made from a new composite biomaterial. In addition, by choosing the antibody that we fix on the protein BpA, we choose the virus that we want to detect (Zika, Chikunguya, Dengue, Yellow Fever…).

To learn more about the design of our patch with the production of this fusion protein, you can go to the <a href="https://2016.igem.org/Team:Pasteur_Paris/Science">SCIENCE</a> section.

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To learn more about the design of the trap and the diagnostic KIT, you can go to the <a href="https://2016.igem.org/Team:Pasteur_Paris/Moskit_devices">DEVICE</a> section.

−

The Mos(kit)o device is easy to use and it does not require scientific expertise so it is possible to train people locally. From the ~~set~~ up of the trap to the analysis of the patch, the steps are simple and designed to reduce user error. For example, the quick read function has a color change component to ensure quick and accurate interpretation of results; changing from no color to color for positive results.

+

The Mos(kit)o device is easy to use and it does not require scientific expertise so it is possible to train people locally. From the setting up of the trap to the analysis of the patch, the steps are simple and designed to reduce user error. For example, the quick read function has a color change component to ensure quick and accurate interpretation of results; changing from no color to color for positive results.

We also reflected on the different stages of using our kit by establishing several scenarios on our project.

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 <div class="text1">
 	<p>
-			In today’s world where we are still having trouble foreseeing events such as earthquakes and disease outbreaks, our team decided to focus on finding a way to predict one of these problems and, therefore, prevent it from happening. As the center of our study, we chose <B>arboviruses</B>, mosquito-borne viruses which often cause severe diseases in humans. These viruses are spreading at an alarming rate on a global scale thanks to mosquitoes, their <B>vectors</B>. Currently, the most common method of fighting against the dissemination of the vectors and the viruses are <B>insecticides</B>, which proved to be extremely damaging to the <B>environment</B>. In addition to that, mosquitoes tend to develop resistance against these insecticides, which diminishes their efficiency even more.</br></br>
+			In today’s world where we are still having trouble foreseeing events such as earthquakes and disease outbreaks, our team decided to focus on finding a way to predict one of these problems and, thereby, prevent it from happening. As the center of our study, we chose <B>arboviruses</B>, mosquito-borne viruses which often cause severe diseases in humans. These viruses are spreading at an alarming rate on a global scale due to mosquitoes, their <B>vectors</B>. Currently, the most common method of fighting against the dissemination of the vectors and the viruses are <B>insecticides</B>, which haven proven to be extremely damaging to the <B>environment</B>. In addition to that, mosquitoes tend to develop resistance against these insecticides, which diminishes their efficiency even more.</br></br>
 			Our project consists out of a kit named <B>MOS(KIT)O</B>, containing:</br>
 			<SPACER>• A mosquito trap</br></SPACER>
@@ Line 64: / Line 64: @@
 			The diagnostic patch is biosilica-based and allows a quick detection of viruses in mosquitoes, by first depositing  a mosquito lysate, produced by the trap, onto the patch. This system is quick and easy to use by local administrations and allows them to create a detailed real-time mapping of the territories populated with infected mosquitoes.</br></br>
-			So our project consists in the development of a <B>better mapping tool of vector-borne diseases</B> to specifically target insecticide spreading in infected areas only, to facilitate rapid diagnosis, and significantly improve the prevention against these diseases before outbreak appearance. To do that, we engineered a dual system capable of ensuring both the <B>capture of mosquitoes</B> and also the <B>detection</B> of the presence or absence of virus in these vectors.
+			So our project consists in the development of a <B>better mapping tool of vector-borne diseases</B> to specifically target insecticide spreading in infected areas only, to facilitate rapid diagnosis, and significantly improve the prevention of these diseases before outbreak appearance. To do that, we engineered a dual system capable of ensuring both the <B>capture of mosquitoes</B> and also the <B>detection</B> of the presence or absence of virus in these vectors.
 			 </br></br>
@@ Line 71: / Line 71: @@
-			With the assistance of synthetic biology, we successfully modified <i>E. coli</i>, within a contained fully functioning biosafety laboratory. With it, we produce a novel fusion protein needed to create <FONT color="#DF5939"><B>biosilica</B></FONT>, and bind <FONT color="#D58490"><B>antibodies</B></FONT> onto a <FONT color="#1560BD"><B>cellulose</B></FONT> support. We selected <B>biosilica</B> to increase rigidity of our patch and because it is completely <B>biodegradable</B>. The innovative design of the patch creates a multilayered matrix coated with <B>antibodies</B> capable of detecting a wide panel of vector-borne pathogens (like Zika, Chikunguya, Dengue, Yellow Fever…) and insecticide resistant proteins from captured mosquitoes. </br></br>
+			With the assistance of synthetic biology, we successfully modified <i>E. coli</i>, within a contained fully functioning biosafety laboratory. With it, we produce a novel fusion protein needed to create <FONT color="#DF5939"><B>biosilica</B></FONT>, and bind <FONT color="#D58490"><B>antibodies</B></FONT> onto a <FONT color="#1560BD"><B>cellulose</B></FONT> support. We selected <B>biosilica</B> to increase rigidity of our patch and because it is completely <B>biodegradable</B>. The innovative design of the patch creates a multilayered matrix coated with <B>antibodies</B> capable of detecting a wide panel of vector-borne pathogens (like Zika, Chikunguya, Dengue, Yellow Fever…) and insecticide-resistant proteins from captured mosquitoes. </br></br>
-			As a result of these three functions, the protein is able to specifically catch viral proteins. And with a simple marking solution, it reveals the presence of the virus. Our novel protein is integrated into a cellulose patch giving a <B>user friendly detection device</B>. It is rigid, easy to be manipulated, and made from a <B>new composite biomaterial</B>. In addition, by choosing the antibody that we fix on the protein BpA, we choose the virus that we want to detect (Zika, Chikunguya, Dengue, Yellow Fever…).</br></br>
+			As a result of these three functions, the protein is able to specifically catch viral proteins. And with a simple marking solution, it reveals the presence of the virus. Our novel protein is integrated into a cellulose patch giving a <B>user friendly detection device</B>. It is rigid, easy to manipulate, and made from a <B>new composite biomaterial</B>. In addition, by choosing the antibody that we fix on the protein BpA, we choose the virus that we want to detect (Zika, Chikunguya, Dengue, Yellow Fever…).</br></br>
 			To learn more about the <B>design of our patch</B> with the production of this fusion protein, you can go to the <a href="https://2016.igem.org/Team:Pasteur_Paris/Science">SCIENCE</a> section.</br></br>
@@ Line 96: / Line 96: @@
 			To learn more about the design of the trap and the diagnostic KIT, you can go to the <a href="https://2016.igem.org/Team:Pasteur_Paris/Moskit_devices">DEVICE</a> section.</br></br>
-			The Mos(kit)o device is <B>easy to use</B> and it does not require scientific expertise so it is possible to train people locally. From the set up of the trap to the analysis of the patch, the steps are simple and designed to reduce user error. For example, the <B>quick read function</B> has a <B>color change</B> component to ensure quick and accurate interpretation of results; changing from no color to color for positive results. </br></br>
+			The Mos(kit)o device is <B>easy to use</B> and it does not require scientific expertise so it is possible to train people locally. From the setting up of the trap to the analysis of the patch, the steps are simple and designed to reduce user error. For example, the <B>quick read function</B> has a <B>color change</B> component to ensure quick and accurate interpretation of results; changing from no color to color for positive results. </br></br>
 			We also reflected on the different stages of using our kit by establishing several <B>scenarios</B> on our project.