Difference between revisions of "Team:Pasteur Paris/Results"

 
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Based on the input of specifications by <B>experts in the field</B> (entomologists, mosquito control officers, virologists..), and the impact of the <B>economy</B> and <B>sociology</B> of the places where we will apply our project, namely mostly tropical and poor countries, on the scientific process of detection (ecosystem of the mosquitoes, state of the samples containing pathogen antigens, safety,…) we were able to generate a trapping device with the help of ideation, prototyping and <B>3D modeling software</B>. The device is easy to use, safe and efficient in the detection of mosquito borne <B>pathogen antigens</B>. The trap was subsequently materialized through the <B>3D printing process</B>. The prototype model tested for egress of sample of mosquitoes (n=200) showed a 2% rate of escape (98% retention rate). However, capture using the Biogent® pheromone bag was not efficient as no mosquitoes were captured after 24h of exposure. This second aspect needs to be improved, by changing attraction systems including CO<sub>2</sub> generation.  
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Based on the input of specifications by <B>experts in the field</B> (entomologists, mosquito control officers, virologists..), and the impact of the <B>economy</B> and <B>sociology</B> of the places where we will apply our project, namely mostly tropical and developing countries, on the scientific process of detection (ecosystem of the mosquitoes, state of the samples containing pathogen antigens, safety,…) we were able to generate a <a href="https://2016.igem.org/Team:Pasteur_Paris/Moskit_devices">trapping device</a> with the help of <B>ideation</B>, <B>prototyping</B> and <B>3D modeling software</B>. The device is easy to use, safe and efficient in the detection of mosquito borne <B>pathogen antigens</B>. The trap was subsequently materialized through the <B>3D printing process</B>. The prototype model tested for egress of sample of mosquitoes (n=200) showed a 2% rate of escape (98% retention rate). However, capture using the Biogent® pheromone bag was not efficient as no mosquitoes were captured after 24h of exposure. This second aspect needs to be improved, by changing attraction systems including CO<sub>2</sub> generation.  
 
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<B>Composite patches</B> were obtained with a mix of cellulose and silica gel, either by mechanical mixing or produced in the <B>one pot experiment</B> . The resulting composite patches are <B>easier to handle</B> than those with cellulose alone or a mix of cellulose and water. The former resist to manipulation whereas the latter break when they are manipulated.
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<B>Composite patches</B> were obtained with a mix of cellulose and silica gel, either by mechanical mixing or produced in the <B>one pot experiment</B>. The resulting composite patches are <B>easier to handle</B> than those with cellulose alone or a mix of cellulose and water. The former resist to manipulation whereas the latter break when they are manipulated.
 
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Using similar approaches as in the trap design, a <B>prototype</B> for an <B>analysis station</B> has been <B>3D printed</B>. It allows us to visualize the analysis process and ergonomy. Sample throughput in the system remains to be tested. </br>
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Using similar approaches as in the <a href="https://2016.igem.org/Team:Pasteur_Paris/Moskit_devices">trap design</a>, a <B>prototype</B> for an <B>analysis station</B> has been <B>3D printed</B>. It allows us to visualize the analysis process and ergonomy. Sample throughput in the system remains to be tested. </br>
 
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With collaborations, public <B>education</B>, public <B>opinion</B>, <B>polling</B>, we were able to generate a <B>scenario</B> that encompasses the use of our Mos(kit)o device in the real world. </br>
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With collaborations, public <B>education</B>, public <B>opinion</B>, <B>polling</B>, we were able to generate a <a href="https://2016.igem.org/Team:Pasteur_Paris/Human_Practices"><B>scenario</B></a> that encompasses the use of our Mos(kit)o device in the real world. </br>
 
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From our <B>meet-ups</B>, discussion with other teams, and our own concern for the transition from <B>Open Science</B> to a possible start-up, we were able to generate <a href="https://2016.igem.org/Team:Pasteur_Paris/Law"><B>two document tools</B></a> that summarize and inform about these issues. </br>
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From our <a href="https://2016.igem.org/Team:Pasteur_Paris/Meet-up"><B>meet-ups</B></a>, discussion with other teams, and our own concern for the transition from <B>Open Science</B> to a possible start-up, we were able to generate <a href="https://2016.igem.org/Team:Pasteur_Paris/Law"><B>two document tools</B></a> that summarize and inform about these issues. </br>
 
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<h2>References: </h2>
 
<h2>References: </h2>
[1] Characterization of the cellulose-binding domain of the Clostridium cellulovorans cellulose-binding protein A, Golstein MA et al, J. Bacteriol., 1993. </br>
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[1] Characterization of the cellulose-binding domain of the <i>Clostridium cellulovorans</i> cellulose-binding protein A, Golstein MA et al, J. Bacteriol., 1993. </br>
  
 
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Latest revision as of 15:27, 19 November 2016