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<h3>Integration in our project </h3>
 
  
<p id="integration-scroll" class="scrollspy">There were several interactions with stakeholders that heavily impacted the direction of our design. Integrated Human Practices was extremely valuable in shaping our project. In response to dialogues with the public, risk assessors, and potential users, we changed our design from a GMO-based lab tool to a <i>safe</i> and <i>reliable</i> end product. Key points that we took from discussions with stakeholders were that the method needs to combine a <i>simplified sample preparation</i>, a <i>fast, easy readout</i> and the possibility for <i>on-site use</i>. We integrated all these in our project, by designing a cell-free method that can be stored for up to two weeks and produces a visible readout.
 
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<p>We started by finding a relevant case in which our device could make a contribution. Through a conversation with a veterinarian, we were advised to narrow our scope to mastitis, an udder infection affecting dairy cows.
 
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<blockquote>Every milk farmer faces mastitis, a challenging udder disease affecting dairy cows.<cite>Bouwe Gall Frank (veterinarian)</cite></blockquote>
 
 
<p>This infection is not easy to get rid of; udders are exposed to the open environment, making the infection a common re-occurrence. All dairy farmers we spoke to in the Netherlands have had to deal with mastitis. Farmers want to have fast administration of antibiotics when treating this disease, as time is of the essence. Our tool makes sure that fast treatment of mastitis can be done in a responsible way, without misusing antibiotics, thereby helping to prevent the evolution of antibiotic resistant bacteria. Looking to mastitis, we adapted our tool to detect relevant resistance genes in the common pathogen, Staphylococcus Aureus (SAU), causing this disease.
 
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<blockquote>It is relevant to be able to detect SAU pathogens. As there is a huge difference in sensitivity for antibiotics considering MRSA, it would be added value to have a conclusive result on the sensitivity.<cite>Maaike van den Berg (veterinarian)</cite></blockquote>
 
 
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After talking to experts with expertise in mastitis from the Wageningen Bioveterinary Research Center in Lelystad, we found that detecting the mecA and blaZ genes was the way to go.
 
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<blockquote>MecA can be used to detect resistance against all β-lactam antibiotics.<cite>Fimme van der Wal (agricultural researcher)</cite></blockquote>
 
 
<blockquote>Detection of blaZ is a conclusive result to exclude commonly used penicillin treatment.<cite>Dik Mevius (agricultural researcher)</cite></blockquote>
 
 
<p>For further information about these genes check out our <a href="https://2017.igem.org/Team:TUDelft/Applied_Design" target="_blank">applied design</a> and <a href="https://2017.igem.org/Team:TUDelft/Demonstrate" target="_blank">demonstrate page</a>.
 
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<p>After defining our end-users and detection goal, we looked at how we could make our device as user-friendly as possible. From the start of our project, we wanted to integrate the use of tardigrade intrinsically disordered proteins (TDPs) which are able to maintain the functionality of other proteins upon desiccation. This fitted perfectly in our design with respect to our end-users, as our TDPs enable the transportation and storage of our detection tool at room temperature. Normally, protein function can be maintained when stored at -80 degrees celsius, something that is not always available at your local dairy farm! We also envisioned that this improved storage method will be advantageous for shipping our versatile RNA-detection tool for broader applications. For further information on our TDPs, check out our <a href="https://2017.igem.org/Team:TUDelft/Design#TDP" target="_blank">TDP design page</a>.
 
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<p>Adding to the storability, we realised that our tool needed to give a readout visible to the naked eye. At a farm, there are no fancy lasers or microscopes, so we had to get creative! We started by designing a microfluidics paper chip with GMOs with a kill switch to detect resistance genes, but gained crucial feedback on this.</p>
 
 
<blockquote>Even <b>if</b> GMO kill switches were reliable, there is no public acceptance to use GMOs in the environment. <b>If</b> it will be accepted in the future, it will take years from now to legislate this principle. Innovation based on this gets stuck.<cite>Cecile van der Vlugt (Risk Assessor GMO)</cite></blockquote>
 
 
<p>This led us to come up with a <b>new application: CINDY-Seq</b>. This method allows for a simple yes or no answer to the question: is the pathogen causing mastitis in my cow resistant to penicillins, or even all β-lactamases depending on the design of Cas13a, in a matter of hours, without the use of GMOs in the environment. For more information on how CINDY-Seq works, please visit our <a href="https://2017.igem.org/Team:TUDelft/Design#coacervation" target="_blank">coacervation design page</a>.</p>
 
 
<p>Now that we completed the design of our detection tool, we needed to look at how we could make the sample preparation as simple as possible for a farmer, as farmers like to do most things themselves.</p>
 
 
<blockquote>We try to do most things by ourselves to prevent high bills from the veterinarian.<cite>Tjerkje Poppinga (dairy farmer)</cite></blockquote>
 
 
<p>In the case of mastitis, the pathogen is present in the milk of the infected cow. By hitting the books and optimising existing protocols, we came up with an easy method to prepare a fresh milk sample for the detection tool. To know more about which methods we came up with, look at our <a href="https://2017.igem.org/Team:TUDelft/Design#sampleprep" target="_blank">sample prep design page</a> where we describe this extensively.</p>
 
 
<p>Finally, our integrated human practices strategy helped us to think a step further about our design, regarding, for example, the costs involved in our device and what it should actually look like; what kind of ‘kit’ will it be and what will it contain? We also looked at the feasibility of our device in the context of whether or not farmers would actually be allowed to <i>use</i> such a device and what needs to be done considering legislation to make this possible.</p>
 
 
<blockquote>Only veterinarians can prescribe or change antibiotic treatments.<cite>Engeline van Duijkeren (veterinarian)</cite></blockquote>
 
<p>Stakeholder interactions shaped our final design and made it feasible to transform our detection method into an application, resulting in a toolbox with which the farmers can perform the resistance test themselves on-site, instead of being dependent on slow lab processes. Simple, cheap and safe methods - for example the hand-powered centrifuge and boiling method during sample preparation, together with an optimized readout - make our device applicable for rapid frontline diagnostics. We developed our toolbox to detect the most relevant multiple antibiotic resistance genes, expanding the impact of our product to achieve better animal and human treatment strategies, see our <a href="https://2017.igem.org/Team:TUDelft/Applied_Design" target="_blank">applied design page</a> for more info!</p>
 
 
 
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Revision as of 09:34, 6 October 2018

Integrated Human
Practices:

Work in Progress

Integrated Human
Practices:

Human Practices