Difference between revisions of "Team:Wageningen UR/Design"

 
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<h1>Helping honeybees and beekeepers with BeeT </h1>
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<h1>Helping honey bees and beekeepers with BeeT </h1>
<p>How would BeeT work in the real world? Who would use it and how would they use it? More importantly, would they even use BeeT? To explore these questions, we sought out experts, beekeepers and designers. They helped us prepare BeeT for real life and societal conditions. On this page, we use BeeT's illustrated story to show you how our design chanced in response to feedback, practical problems and new information. </p>
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<p>How would BeeT work in the real world? Who would use it and how would they use it? More importantly, how can we ensure BeeT is embraced? To explore these questions, we sought out experts, beekeepers and designers. They helped us prepare BeeT for real life conditions. Scroll down to learn more about how our design changed in response to feedback, practical problems and new information.</p>
  
 
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<p>We started our project by talking to bee specialist Tjeerd Blacquiere from Wageningen UR and Frank Moens, spokesperson for the Dutch association for Beekeepers. They assured us that the parasitic mite <i>Varroa destructor</i> is indeed the main cause for the poor state of honeybees. With both we discussed current methods to treat the mites. They explained that, in the Netherlands, beehives are treated year-round with combinations of formic acid, oxalic acid and thymol. Each of these compounds has its own disadvantages: formic acid has a very small margin between concentrations that get rid of Varroa and concentrations that are harmful to bees. Oxalic acid treatment is only effective in the fall and winter. Lastly, thymol has a narrow temperature range and contaminates the honey with an unpleasant taste. Moreover, we have to conclude that the range of treatments available now is not effective enough. After all, current methods have failed to protect honeybees<sup><a href="#fn1" id="ref1">1</a></sup>. It is clear that our approach has to be more effective than current methods and should not contaminate the honey, an important product for beekeepers.</p>
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<p>Additionally we have spoken to Bob Mulders, an expert in strategic communication at Wageningen UR. He alerted us to the ‘don’t change the consumer, change the technology’ principle. This principle dictates that for a technology to be adopted, it should require little or no adaptation from the consumers. He also agreed to become official advisor of our team.</p>
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<h1>Initial Considerations </h1>
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<p>We started our project by talking to bee specialist Tjeerd Blacquière from Wageningen UR and Frank Moens, spokesperson for the Dutch association for Beekeepers. They assured us that the parasitic mite <i>Varroa destructor</i> is indeed the main cause for the high mortality of honey bees. With both, we discussed current methods to treat these mites. They explained that, in the Netherlands, beehives are treated year-round with combinations of formic acid, oxalic acid and thymol. Each of these compounds has its own disadvantages: formic acid has a very small margin between concentrations that get rid of <i>Varroa</i> and concentrations that are harmful to bees. Oxalic acid treatment is only effective in the fall and winter. Lastly, thymol has a narrow temperature range and contaminates the honey with an unpleasant taste. Moreover, apparently these methods have failed to protect honey bees<sup><a href="#fn1" id="reffn1">1</a></sup>. It can be concluded that our approach has to be more effective and easy to use  than current methods. Furthermore, it should not contaminate the honey, an important product for beekeepers.</p>
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<p>Additionally, we have spoken to Bob Mulder, an expert in strategic communication at Wageningen UR. He introduced us to the ‘don’t change the consumer, change the technology’ principle. This principle dictates that for a technology to be adopted, it should require little or no adaptation from the consumer. He also agreed to become official advisor of our team.</p>
  
 
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<img src="https://static.igem.org/mediawiki/2016/4/40/T--Wageningen_UR--triforce.jpg">
 
<img src="https://static.igem.org/mediawiki/2016/4/40/T--Wageningen_UR--triforce.jpg">
<figcaption>This is BeeT's triforce: it visualizes the three most important requirements. Firstly, we would need to have something that is better than current pesticides. Secondly, it needed to suit the beekeeper's schedule and methods, as beekeeping relies on highly conserved and reliable practices. Finally, it is vital to ensure it could not contaminate the honey. These requirements take into account both the theoretical effectiveness of the approach as well as the more practical aspect that beekeepers need to actually want to use our product, BeeT.  </figcaption>
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<figcaption>This is BeeT's triforce. It visualizes the three most important requirements for BeeT: more effective than current <i>Varroa</i> treatments, easy to use for beekeepers, and not contaminating the honey.</figcaption>
 
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<p>Based on these requirements, we decided to focus on three key aspects: <b>specificity</b>, <b>regulation</b> and <b>biocontainment</b>.</P>
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<h1>Specificity, Regulation and Biocontainment</h1>
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<p>Based on these requirements, we decided to focus on three key aspects: <b>specificity</b>, <b>regulation</b> and <b>biocontainment</b>. Below, we discuss how those topic were incorporated in the final design.</P>
 
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<p>The first point, <b>specificity</b> focusses on how we can make an effective treatment to <i>Varroa</i> that leaves bees and humans unharmed. There are many chemicals that can be used to kill mites, but most are also harmful to honeybees to some extent. Therefore, our approaches aimed for a toxin that would truly be a better alternative. During testing of the toxins, we encountered a major hurdle: <i>Varroa</i> are extremely vulnerable in laboratory settings and often die irrespectively of the treatment. To overcome this hurdle we developed a new <i>in vitro</i> assay for determining <i>Varroa</i> toxicity. </p>
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<h2>Specificity </h2>
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<p><b>Specificity</b> focuses on how we can make an effective treatment to <i>Varroa</i> that leaves bees and humans unharmed. There are many chemicals that can be used to kill mites, but most are also harmful to honey bees to some extent. Therefore, our approaches aimed for a toxin that would truly be a better alternative. When testing of the toxins, we encountered a major hurdle: <i>Varroa</i> mites are extremely vulnerable in laboratory settings and often die irrespectively of the treatment. To overcome this, we developed an <i>in vitro</i> assay for determining <i>Varroa</i> toxicity.</p>
 
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<img src="https://static.igem.org/mediawiki/2016/1/16/T--Wageningen_UR--comicspecificity.jpg">
 
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<h2>Regulation</h2>
<p>Our regulation focused on two aspects: minimizing background toxin presence in the beehive and ensuring that misapplication of BeeT would not result in damage to beehives or beekeepers. Initially, we intended for our toxin to be present in the beehive at all times. If it was not harmful to bees or humans, what would it matter? It could be used as a preventative measure. However, beekeepers voiced their dislike of GMO's and especially the presence of the toxin, so we soon realized we would have to minimize the beehive's exposure to BeeT.</p>
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<p>Our regulation focused on two aspects: minimizing background toxin presence in the beehive and ensuring that misapplication of BeeT would not result in damage to beehives or beekeepers. Initially, we intended for our toxin to be present in the beehive at all times. If it is not harmful to bees or humans, what would it matter? We thought of it as a preventative measure. However, we were told by Tjeerd Blaquiere that resistance of <i>Varroa</i> is a recurring problem. Literature<sup><a href="#fn2" id="reffn2">2</a></sup> told  us that resistance can be slowed if treatment of <i>Varroa</i> is only applied when needed, so we realized toxin production should be strictly regulated.</p>
 
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<p>From the very start of our project, we were aware of the potential dangers of using synthetic biology in a system as volatile as a beehive. However, the RIVM (Dutch governmental institute for national well being and environment) primed u…….
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<h2>Biocontainment</h2>
Additionally, we realized that beekeepers would never use BeeT if they thought it could escape their control. With this in mind, we tried to implement two complementary biocontainment systems.</p>
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<p>From the very start of our project, we were aware of the potential dangers of using synthetic biology in a system as volatile as the beehive. However, the RIVM (Dutch governmental institute for national well being and environment) challenged us to investigate the 'safety-by-design' in our project. Additionally, beekeepers voiced their dislike of GMOs, and we realized that beekeepers would never use BeeT if they would not be entirely convinced of its safety. With this in mind, we tried to implement two complementary biocontainment systems.</p>
 
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<h1>Prototype Design</h1>
<figcaption>We explored the ethical and societal issues together with Synenergene, RIVM and students from the Design Academy Eindhoven.</figcaption>
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<p>To get beekeepers to use BeeT it should not just work well, it also has to fit well with their practicalities. We asked design student Thieu Custers, from the Design Academy Eindhoven, to develop a visual prototype. Below you can find his design and explanation.<br><br></p>
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<figcaption>BeeT design and product description by Thieu Custers, Design Academy Eindhoven. Thieu helped us put BeeT together in a way that is transparent to the user. To promote public debate on synthetic biology, it is essential that its usage is as visible as possible. </figcaption>
 
 
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<h1>The next step: does it work?</h1>
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During our project, we did not have time to finalize BeeT and test it in the field. However, using an open source model (beehave) as a basis, we determined how effective BeeT needs to be to have a significant impact on bee survival. We adapted beehave to our needs by adding a BeeT module, and to make our predictions as accurate as possible we used real life weather data as input. Apart from preparing this tool to measure effectiveness for future use, we got some interesting information from the model about the ideal time of application of BeeT. From Frank Moens we heard that <i>Varroa</i> mites are best combated in autumn. In that way, strong winter bees can be made that are more likely to survive the winter. Moreover, there is no risk of contaminating the honey, as it is not harvested in that time of the year. However, from the beehave model we could conclude that BeeT is more effective when applied in spring. We think this is important information to consider for further development of BeeT and in giving advice to beekeepers on how to use it. </p>
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<figcaption>Graphs from the Beehave model, showing population dynamics of mites and bees without BeeT treatment (A) and with BeeT treatment (B). The blue and red lines show how Bee and mite populations change over time, respectively. Parameters from Figure B can be used to give an estimation of how effective BeeT needs to be to save the bees. </figcaption>
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<h1><b>References</b></h1>
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<h1><b>References</b></h1><br>
 
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  <a id="fn1" href=http://www.tandfonline.com/doi/full/10.1080/00218839.2016.1153294>1.</a> Seitz, N., Traynor, K. S., Steinhauer, N., Rennich, K., Wilson, M. E., Ellis, J. D., ... & Delaplane, K. S. (2016). A national survey of managed honey bee 2014–2015 annual colony losses in the USA. Journal of Apicultural Research, 1-12. <a href="#ref1" title="Jump back to footnote 1 in the text.">↩</a>
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  <a id="fn1" href=http://www.tandfonline.com/doi/full/10.1080/00218839.2016.1153294>1.</a> Seitz, N., Traynor, K. S., Steinhauer, N., Rennich, K., Wilson, M. E., Ellis, J. D., ... & Delaplane, K. S. (2016). A national survey of managed honey bee 2014–2015 annual colony losses in the USA. Journal of Apicultural Research, 1-12. <a href="#reffn1" title="Jump back to footnote 1 in the text.">↩</a>
 
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<a id="fn2" href=http://www.biosecurity.govt.nz/files/pests/varroa/control-of-varroa-guide.pdf>2.</a> Goodwin, M., & Van Eaton, C. (2001). Control of Varroa. A guide for New Zealand Beekeepers. New Zealand Ministry of Agriculture and Forestry (MAF). Wellington, New Zealand. <a href="#reffn2" title="Jump back to footnote 2 in the text.">↩</a>
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Latest revision as of 02:23, 20 October 2016

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Wageningen UR iGEM 2016

 

 

 

Helping honey bees and beekeepers with BeeT

How would BeeT work in the real world? Who would use it and how would they use it? More importantly, how can we ensure BeeT is embraced? To explore these questions, we sought out experts, beekeepers and designers. They helped us prepare BeeT for real life conditions. Scroll down to learn more about how our design changed in response to feedback, practical problems and new information.




Initial Considerations

We started our project by talking to bee specialist Tjeerd Blacquière from Wageningen UR and Frank Moens, spokesperson for the Dutch association for Beekeepers. They assured us that the parasitic mite Varroa destructor is indeed the main cause for the high mortality of honey bees. With both, we discussed current methods to treat these mites. They explained that, in the Netherlands, beehives are treated year-round with combinations of formic acid, oxalic acid and thymol. Each of these compounds has its own disadvantages: formic acid has a very small margin between concentrations that get rid of Varroa and concentrations that are harmful to bees. Oxalic acid treatment is only effective in the fall and winter. Lastly, thymol has a narrow temperature range and contaminates the honey with an unpleasant taste. Moreover, apparently these methods have failed to protect honey bees1. It can be concluded that our approach has to be more effective and easy to use than current methods. Furthermore, it should not contaminate the honey, an important product for beekeepers.

Additionally, we have spoken to Bob Mulder, an expert in strategic communication at Wageningen UR. He introduced us to the ‘don’t change the consumer, change the technology’ principle. This principle dictates that for a technology to be adopted, it should require little or no adaptation from the consumer. He also agreed to become official advisor of our team.

This is BeeT's triforce. It visualizes the three most important requirements for BeeT: more effective than current Varroa treatments, easy to use for beekeepers, and not contaminating the honey.


Specificity, Regulation and Biocontainment

Based on these requirements, we decided to focus on three key aspects: specificity, regulation and biocontainment. Below, we discuss how those topic were incorporated in the final design.




Specificity

Specificity focuses on how we can make an effective treatment to Varroa that leaves bees and humans unharmed. There are many chemicals that can be used to kill mites, but most are also harmful to honey bees to some extent. Therefore, our approaches aimed for a toxin that would truly be a better alternative. When testing of the toxins, we encountered a major hurdle: Varroa mites are extremely vulnerable in laboratory settings and often die irrespectively of the treatment. To overcome this, we developed an in vitro assay for determining Varroa toxicity.




Regulation

Our regulation focused on two aspects: minimizing background toxin presence in the beehive and ensuring that misapplication of BeeT would not result in damage to beehives or beekeepers. Initially, we intended for our toxin to be present in the beehive at all times. If it is not harmful to bees or humans, what would it matter? We thought of it as a preventative measure. However, we were told by Tjeerd Blaquiere that resistance of Varroa is a recurring problem. Literature2 told us that resistance can be slowed if treatment of Varroa is only applied when needed, so we realized toxin production should be strictly regulated.




Biocontainment

From the very start of our project, we were aware of the potential dangers of using synthetic biology in a system as volatile as the beehive. However, the RIVM (Dutch governmental institute for national well being and environment) challenged us to investigate the 'safety-by-design' in our project. Additionally, beekeepers voiced their dislike of GMOs, and we realized that beekeepers would never use BeeT if they would not be entirely convinced of its safety. With this in mind, we tried to implement two complementary biocontainment systems.




Prototype Design

To get beekeepers to use BeeT it should not just work well, it also has to fit well with their practicalities. We asked design student Thieu Custers, from the Design Academy Eindhoven, to develop a visual prototype. Below you can find his design and explanation.


The next step: does it work?

During our project, we did not have time to finalize BeeT and test it in the field. However, using an open source model (beehave) as a basis, we determined how effective BeeT needs to be to have a significant impact on bee survival. We adapted beehave to our needs by adding a BeeT module, and to make our predictions as accurate as possible we used real life weather data as input. Apart from preparing this tool to measure effectiveness for future use, we got some interesting information from the model about the ideal time of application of BeeT. From Frank Moens we heard that Varroa mites are best combated in autumn. In that way, strong winter bees can be made that are more likely to survive the winter. Moreover, there is no risk of contaminating the honey, as it is not harvested in that time of the year. However, from the beehave model we could conclude that BeeT is more effective when applied in spring. We think this is important information to consider for further development of BeeT and in giving advice to beekeepers on how to use it.

Graphs from the Beehave model, showing population dynamics of mites and bees without BeeT treatment (A) and with BeeT treatment (B). The blue and red lines show how Bee and mite populations change over time, respectively. Parameters from Figure B can be used to give an estimation of how effective BeeT needs to be to save the bees.

References


    1. Seitz, N., Traynor, K. S., Steinhauer, N., Rennich, K., Wilson, M. E., Ellis, J. D., ... & Delaplane, K. S. (2016). A national survey of managed honey bee 2014–2015 annual colony losses in the USA. Journal of Apicultural Research, 1-12.

    2. Goodwin, M., & Van Eaton, C. (2001). Control of Varroa. A guide for New Zealand Beekeepers. New Zealand Ministry of Agriculture and Forestry (MAF). Wellington, New Zealand.