Difference between revisions of "Team:Paris Bettencourt/Design"

 
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<font color="red">Should I talk first about what the problem is (malnutrition in India), or will we talk about it somewhere else?</font>
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<br>
 
<br>
  
 
<div id="notebookMenu">
 
<div id="notebookMenu">
  <ul>
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    <ul>
    <li><a href="#introduction" class="stretch">Introduction</a></li>
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        <li><a href="#introduction">Introduction</a></li>
    <li><a href="#manufacturing">Manufacturing</a></li>
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        <li><a href="#distribution">Distribution & Availability</a></li>
    <li><a href="#distribution">Distribution & (or?) Availability</a></li>
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        <li><a href="#acceptance">Acceptance</a></li>
    <li><a href="#acceptance">Acceptance</a></li>
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        <li><a href="#safety">Safety & Regulations</a></li>
    <li><a href="#safety">Safety & Regulations</a></li>
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        <li><a href="#continuity">Continuity</a></li>
    <li><a href="#continuity">Final product / Continuity / Synbio??</a></li>
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    </ul>
  </ul>
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</div>
 
</div>
  
 
<div id="notebookContent">
 
<div id="notebookContent">
<a name="introduction" class="anchor"><h1></h1></a>
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    <a name="introduction" class="anchor"><h1></h1></a>
<h1 class="date one">Introduction</h1>
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<p>
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We decided to re-think the universal tradition of food fermentation, and extend it with new possibilities. With community acceptance in mind, we invented a product that can works sustainably in the hands of people with minimal equipment, and fits equally well into the existing infrastructure set up by the Indian government to fight malnutrition, by significantly reducing the production costs. This way we ensure that our product has the highest chances of reaching its target population. At the same time, we show that it will be trusted by people, because it does not stricly depend on any third party and because it is deeply rooted in their traditions.
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</p>
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<a name="manufacturing" class="anchor"><h1></h1></a>
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    <h1 class="date one">Introduction</h1><br>
<h1 class="date two">Manufacturing</h1>
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    <p>Despite many efforts from the indian government and NGO's to decrease the micronutrient deficiencies in India, there are two major limitations that prevent the vast majority of the population to access sufficient sources of vitamins and iron or phytic acid: <b>cost</b>, and <b>distribution</b>. Our project proposes an elegant solution to address both those issues, via a cost-effective biosynthesis of vitamins and phytic acid by micro-organisms, which can be cultivated in everyone’s home without any need of external infrastructure.
 +
<br><br>We decided to re-think the universal tradition of food fermentation to expand it with new possibilities. With
 +
        community acceptance in mind, we developed a product that can work sustainably in the hands of people with
 +
        minimal equipment, and fits equally well into the existing infrastructure set up by the Indian government to
 +
        fight malnutrition by significantly reducing the production costs. This way we ensure that our product has the
 +
        highest chances of reaching its target population. At the same time, we designed our product to engender people's
 +
        trust, as its use is sustained without strictly depending on any third party and it is deeply rooted in their traditions.
 +
    </p>
  
<br>The aim of the manufacturing project is to find a way to grow and distribute our strains, easily and cheaply, to be able to reach as many people as possible.<br> 
 
  
<h2>Growth of our strains</h2>
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                    <a name="distribution" class="anchor"><h1></h1></a>
<div class="column-left" align="justify">
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Our project is designed for poor region: the cheaper our product, the more people it can reach. Starting from this point, we don't want to build labs in India, buy media and grow our strains in expensive structures. Therefore, we had to think of a cheap solution to grow the strains in homemade media.<br>
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To avoid expensive and time-consuming treatment, an edible medium is sought. It could then be directly used to cook either our distribution product or the Idli directly. The process would hence be quite simple and accessible to the population.<br> 
+
After some research, we selected 4 different homemade media to test with the strains we were working on: Sc. mcherry, Lactococcus lactis???????, and propioni?????:
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<ul><li>Water from the cooking of potato</li>
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<li>Water from the cooking of potato+sugar(10%)</li>
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<li>Water from the cooking of rice</li>
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<li>Water from the cooking of rice+milk(10%)</li><br>
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</div>
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<div class="column-right" align="justify">
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For each strain, we made growth curves to compare the growth of the strain in the homemade media and in its "normal" media (respectively YPD, M17+Glucose 1% and YEL).
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</div>
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<div style="clear:both">
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<br><br>
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                    <h1 class="date three">Distribution & Availability</h1>
<h2>Packaging and distribution</h2><br>
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<div class="column-left" align="justify">  
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One stake of our project is to give the strains to the population.
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Either community labs or users grow the strains, strains needs to travel from us to the community lab and then to the final user.<br>
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To answer this problem, we tried several methods, premilinarily working on a yeast: Saccharomyces cerevisiae mcherry.<br>
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We could have just lyophilized the strains but our goal is to design something cheap and easy to do for the locals, using only ingredients they have access to and not time consuming.<br>
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We first tried to dry the yeast to obtain a yeast powder. Not satisfied with this method, we tried to cook a powder, using potato, flour, corn meal, sugar and ginger. For each test, we calculated the survival rate of the yeasts in the powder obtained.
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<table style="width:25%" align="center">
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                  <br> <div class="column-left" align="justify"><b>The Integrated Child Development Services (ICDS) programme</b>
<tr align="center">
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<br>An important problem we wanted to tackle with our product is the access Indian people have to sources of vitamins. Indeed, we researched what structures and programs already exist in India, and found that it was a major issue.  
    <th>Powder</th>
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    <td>1</td>
+
    <td>2</td>
+
    <td>3</td>
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    <td>4</td>
+
    <td>5</td>
+
  </tr>
+
  <tr align="center">
+
    <th>Survival rate</th>
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    <td>79%</td>
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    <td>14%</td>
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    <td>20%</td>
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    <td>12%</td>
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    <td>4%</td>
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  </tr>
+
</table>
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<i>Powder 1: yeast powder; powder 2: potato, wheat flour, corn meal, sugar and ginger; powder 3: potato, rice flour, corn meal, and sugar; powder 4: potato, rice flour and corn meal.</i><br>
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</div>
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<div class="column-right" align="justify">
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Finally, regardless of the survival rate, none of the previous methods were satisfying. We realised a powder wasn't the best way to distribute our strains. We wanted portions, easy to pack, with the possibility to pack several portions together. Portions must be easy to stock.<br>
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The most efficient and ergonomic shape appeared to be a cube. Moreover, the cube will mainly be added to Idli, made of rice, so rice flour seemed to be a logical ingredient, consonant with the dish, common in India and cheap.<br>
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Little by little, we succeeded to design an easy recipe, to cook small cubes made of rice flour and water. The idea was also to be flexible to every cube maker means, therefore the recipe is not very strict and can be adapted to what the people have available.<br></div><div style="clear:both"><br>
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<div class="column-left" align="justify">
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                        <br>One of the most important governmental programs for vitamin supplementation is the
<center style="line-height:1.7em"><h3 style="margin:0; font-size:1.65em">Recipe </h3></center>
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                        Integrated Child Development Services (ICDS) program, which has existed in India since 1975.
<h4 style="border-bottom: 1px solid black">Ingredients</h4>  
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                        This program monitors the growth and development of children, and provides supplementary
<ul style="margin:0"><li>2 cups of rice flour</li>
+
                        nutrition as well as education and primary health care for children under six and pregnant and
<li>1 cup of liquid solution containing the strains (water, potato juice or rice juice, )</li></ul>
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                        lactating mothers. The program is implemented through a network of community-level
<h4 style="border-bottom: 1px solid black">Method</h4>
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                        <i>anganwadi</i> centers (AWC), which provides daily supplements both in the center as well as
<ul style="margin:0"><li>Mix the 2 cups of flour with the cup of  liquid solution</li>
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                        through take-home rations. Those supplements include doses of vitamin A and tablets of iron and
<li>The dough obtained should not be too sticky, otherwise, add flour</li>
+
                        folic acid, in order to prevent xerophtalmia - which can lead to blindness - and anaemia.
<li>It should not be too crumbly neither, otherwise, add water</li>
+
                        <br>However, the National Family Health Survey (NFHS-3) held in 2005-2006 in India reports that
<li>Divide the dough in small portion </li>
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                        only 28% of children received those supplements and health care even though 4/5 of children
<li>Shape each portion to obtain a small cube, about half a centimeter in width</li>
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                        under six lived in a region covered by an <i>anganwadi</i> center. In the 6 months preceding the
<li>Let the cubes dry at least 2hours</li>
+
                        survey, only 1/4 of the children between 12-35 months were given vitamin A supplements - and in
<li>You should obtain a small solid cube ready to be used</li></ul>
+
                        9 Indian states, this number falls to less than 20%. The access to ICDS has been improved in
</div>
+
                        recent years, however, although access is still far from being universal (2). According to a
 +
                        national survey held in 2013-14, 46% of children aged 6-59 months had received doses vitamin A.
 +
                        <br>As for folic acid, the 2013-14 survey reports only 14% of children aged 6-59 months having
 +
                        received iron and folic acid supplements.
 +
                        <br><br>Though the program holds great promise and has implemented more than a million <i>anganwadi</i>
 +
                        centers, it is clear that people’s access to them is still very limited. People have to walk to
 +
                        the nearest center everyday if they want to receive the supplements, which is not convenient
 +
                        especially in rural areas.
 +
<br><br><b>Vitamins in everyone’s home</b>
 +
<br>This observation held a major role in our design of a product that can be grown at home, in every village or household. A culture of microorganisms doesn’t require an expensive infrastructure; in fact, most Indian families have already been growing microbial cultures that are several generations old by using a part of their daily yogurt as a starter for the fermentation of the next day’s yogurt. A great part of our project was dedicated to find a cheap and edible medium in which the microbes could be cultivated at home, and to manufacture a simple and practical way to distribute our engineered yeast and bacteria (See <a href="https://2015.igem.org/Team:Paris_Bettencourt/Project/Manufacturing">Manufacturing page</a>). We found that a microbial culture could be grown in a very simple medium like potato juice, and that the yeast could be lyophilized, mixed with rice flour and water, and distributed in the form of small cubes.
 +
                    </div>
  
<div class="column-right" align="justify">
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                    <div class="column-right" align="justify">
<img src="https://static.igem.org/mediawiki/2015/3/3e/ParisBettencourt_manufacturingInfo.png" style="width:100%">
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</div><div style="clear:both">
+
<br><br>
+
  
 +
                        <br><br>We believe that a culture of yeast and bacteria that can be grown at home and supplements
 +
                        fermented foods with vitamins could reach far more people than the <i>anganwadi</i> centers:
 +
                        those cultures would only need to be distributed once, which would not be very costly as the
 +
                        packages can be made to be very small and light and one culture would act as a starter culture
 +
                        for many more. In this way, the culture would be maintained in the home, without the need for
 +
                        people to travel long distances to have access to nutritional supplements.
  
<br><br>
+
<br><br><b>Amma Unavagam</b>
  
<a name="distribution" class="anchor"><h1></h1></a>
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<br>Another way to cheaply give people access to micronutrient-rich foods could be to implement our product in the popular canteens called Amma Unavagam (meaning “Mother Restaurants) which are being developed by the Government in the state of of Tamil Nadu, mostly in the city of Chennai. Those canteens offer people dishes like idli and dosa, both made of fermented rice, for the very cheap price of Rs. 1 for an idli ($0.01).
<h1 class="date three">Distribution & (or?) Availability</h1>
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<br>Those canteens are visited by thousands of people. If they were using our product during the fermentation of their rice, those people would benefit from the micronutrients produced by the engineered strains.
  
<h2>Cost and time to create the strain <font color="red">(how would you call that?? Also, I need help to assess the cost and/or DALY)</font></h2>
+
                        <br><br><b>An adaptable solution</b>
 +
<br>Our product is also more accessible in that it doesn't have the same geographic and
 +
                        climate constraints as cultures of rice or other crops. Contrary to Golden Rice, the rice
 +
                        developed by the Swiss Federal Institute of Technology and the University of Freiburg that
 +
                        biosynthesizes beta-carotene and can only be grown in environments with very high water
 +
                        availability, a microbial culture can be grown anywhere. Even though this summer we mostly
 +
                        focused on microbial cultures of fermented dishes composed of rice, microbes are used to ferment
 +
                        any kind of cereals as well as other foods. So our product can be adapted to a very wide range
 +
                        of fermented dishes, and could also be used by people who don’t eat rice.
 +
                    </div>
 +
                    <div style="clear:both"></div>
 +
                    <br> <img src="https://static.igem.org/mediawiki/2015/7/72/ParisBettencourt_implementationinfo.png"
 +
                              style="width:100%">
  
Lorem ipsum
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                    <br><br>
 +
                    <a name="acceptance" class="anchor"><h1></h1></a>
  
<br><br>
+
                    <h1 class="date one">Acceptance</h1>
<h2>Access</h2>
+
  
<div class="column-left" align="justify">An important problem we wanted to tackle with our product is the access Indian people have to sources of vitamins. Indeed, we researched what structures and programs already exist in India, and found that it was a major issue.
+
                    <h2>People's opinion</h2>
<br>One of the most important governmental programs for vitamin supplementation is the Integrated Child Development Services (ICDS) program, which has existed in India since 1975. This program monitors the growth and development of children, and provides supplementary nutrition as well as education and primary health care for children under six and pregnant and lactating mothers. The program is implemented through a network of community-level <i>anganwadi</i> centers (AWC), which provides daily supplements both in the center as well as through take-home rations. Those supplements include doses of vitamin A and tablets of iron and folic acid, in order to prevent xerophtalmia - which can lead to blindness - and anaemia.
+
<br>However, the National Family Health Survey (NFHS-3) held in 2005-2006 in India reports that only 28% of children received those supplements and health care even though 4/5 of children under six lived in a region covered by an  <i>anganwadi</i> center. In the 6 months preceding the survey, only 1/4 of the children between 12-35 months were given vitamin A supplements - and in 9 Indian states, this number falls to less than 20%. The access to ICDS has been improved in recent years, however, although access is still far from being universal (2). According to a national survey held in 2013-14, 46% of children aged 6-59 months had received doses vitamin A.
+
<br>As for folic acid, the 2013-14 survey reports only 14% of children aged 6-59 months having received iron and folic acid supplements.
+
<br><br>Though the program holds great promise and has implemented more than a million <i>anganwadi</i> centers, it is clear that people’s access to them is still very limited. People have to walk to the nearest center everyday if they want to receive the supplements, which is not convenient especially in rural areas.</div>
+
  
<div class="column-right" align="justify">This observation held a major role in our design of a product that can be grown at home, in every village or household. A culture of microorganisms doesn’t require an expensive infrastructure; in fact, most Indian families have already been growing microbial cultures that are several generations old by using a part of their daily yogurt as a starter for the fermentation of the next day’s yogurt. As we have shown <font color="red">(Célia’s part)</font>, a microbial culture can be grown on or in a very simple medium like potato juice.
+
                    <div class="column-left" align="justify">Since the very beginning of our project, we researched which solution would be convenient and acceptable to them, by asking them about their habits and opinions. For this we interviewed local indian citizens, and well as local authorities in India (find the details on the <a href="https://2015.igem.org/Team:Paris_Bettencourt/Acceptance">Acceptance page</a>).
+
<br>We believe that a culture of yeast and bacteria that can be grown at home and supplements fermented foods with vitamins could reach far more people than the <i>anganwadi</i>centers: those cultures would only need to be distributed once, which would not be very costly as the packages can be made to be very small and light and one culture would act as a starter culture for many more. In this way, the culture would be maintained in the home, without the need for people to travel long distances to have access to nutritional supplements.
+
  
<br><br>Our product is also more accessible in that it doesn't have the same geographic and climate constraints as cultures of rice or other crops. Contrary to Golden Rice, the rice developed by the Swiss Federal Institute of Technology and the University of Freiburg that biosynthesizes beta-carotene and can only be grown in environments with very high water availability, a microbial culture can be grown anywhere. Even though this summer we mostly focused on microbial cultures of fermented dishes composed of rice, microbes are used to ferment any kind of cereals as well as other foods. So our product can be adapted to a very wide range of fermented dishes, and could also be used by people who don’t eat rice.</div>
+
<br><br>We found out that people in India don’t want GMO to be associated with farmers, and they don’t want them to be dependent on one company that would have monopoly on the product. This fitted well with the idea of strains that can be grown at home by everyone. By focusing on yeast and bacteria that are kept in pots and that can be added in a dish at the user’s convenience, we are not targeting the farmers specifically, and we are not affecting the crops at all; and we are giving people an independence and way to chose at any time whether or not they want to eat the GMO.</div>
 +
 
 +
<div class="column-right" align="justify">Most of the indian people we interviewed also told us that they would try our idea of adding a vitamin-producing bacteria, as long as it is proven efficient and harmless for human health. They said that a slight change in the recipe of a dish (aka adding the yeast a bacteria so that they would ferment and produce the vitamins in the dish) would not bother them as long as the taste is not changed.
 +
<br>In order to not affect the taste, we chose to modify micro-organisms already present in the dish instead of adding new ones, in order to not disrupt the microbiome of the fermented dish. To check if high amounts of vitamins could change the taste, we also tasted <i>idlis</i> (fermented rice cakes) in which vitamin A, B2 and B12 bought in a supermarket had been added in quantities equivalent to the required daily amount, and did a blind test: people found no difference in taste at all with and without vitamins.</div>
 
<div style="clear:both"></div>
 
<div style="clear:both"></div>
  
<br><br>
+
                    <br><br>
<a name="acceptance" class="anchor"><h1></h1></a>
+
<h1 class="date one">Acceptance</h1>
+
  
<h2>People's opinion</h2>
+
                    <h2>Why idli?</h2>
  
Lorem ipsum
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                    <div class="column-left" align="justify"><i>Idli</i> (or <i>idly</i>) is a small steamed cake made
<br>[Abdou's data]
+
                        with fermented rice and black lentils (called <i> urad dal</i> or <i>dal</i>). It is a very
<br>[Review board data]
+
                        popular breakfast food across India, mostly in the south, and is often eaten with chutney.
 +
                        <br>We wanted our product to truly fit the traditions and tastes of the people we were
 +
                        targeting, and <i>idli</i> appeared to be the ideal dish. It is a very popular staple of the
 +
                        Indian diet, along with the crepe-like <i>dosa</i>, which is made of a similar but less coarse
 +
                        batter. Its two ingredients (rice and <i>dal</i>) are very cheap and widely available resources,
 +
                        and <i>idli</i> is commonly eaten by people who lack other types of food and who suffer from
 +
                        vitamin deficiencies. There is even a program that distributes free rice to the poorest
 +
                        populations in the country, the Public Distribution System (PDS); and in the city of Chennai and
 +
                        its suburbs, canteens called <i>Amma Unavagam</i> sell <i>idli</i> and other foods for very low
 +
                        prices (Rs1 for 1 <i>idli</i>).
  
<br><br>
+
                        <br><br>
<h2>Why idli?</h2>
+
                        Besides its popularity and easy accessibility, the most interesting property of <i>idli</i> is
 +
                        that it is fermented. To cook <i>idli</i>, people soak rice and <i>dal</i> separately, then
 +
                        grind and mix them together, then let the batter ferment overnight. In the hot Indian climate,
 +
                        the batter ferments quickly and its volume can triple overnight.
 +
                        <br>Many studies have been made on the microbiome of <i>idli</i> batter. Though the strains
 +
                        found in <i>idli</i> can be highly variable from one study to another, probably because the
 +
                        microbiome varies from different regions, we found that <i>Lactococcus lactis</i> and <i>Lactobacillus
 +
                            plantarum</i> are among the most common fermentative bacteria found in <i>idli</i> batter,
 +
                        while in the yeast population, <i>Saccharomyces cerevisiae</i> was always present.
 +
                        Since we wanted our product to disrupt as little as possible
 +
                        the <i>idli</i>'s taste, we chose these organisms for production of the different vitamins and
 +
                        to improve iron availability, instead of adding new micro-organisms that weren’t already present
 +
                        in the <i>idli</i> batter that may have influenced the microbiome in an unpredictable manner.
 +
                        Many people who reviewed our project said that taste was of high importance, and would prefer
 +
                        that we modified microbes already present in the idli rather than add new ones.</div>
 +
         
  
<div class="column-left" align="justify"><i>Idli</i> (or <i>idly</i>) is a small steamed cake made with fermented rice and black lentils (called <i> urad dal</i> or <i>dal</i>). It is a very popular breakfast food across India, mostly in the south, and is often eaten with chutney.
+
                    <div class="column-right" align="center">
<br>We wanted our product to truly fit the traditions and tastes of the people we were targeting, and <i>idli</i> appeared to be the ideal dish. It is a very popular staple of the Indian diet, along with the crepe-like <i>dosa</i>, which is made of a similar but less coarse batter. Its two ingredients (rice and <i>dal</i>) are very cheap and widely available resources, and <i>idli</i> is commonly eaten by people who lack other types of food and who suffer from vitamin deficiencies. There is even a program that distributes free rice to the poorest populations in the country, the Public Distribution System (PDS); and in the city of Chennai and its suburbs, canteens called <i>Amma Unavagam</i> sell <i>idli</i> and other foods for very low prices (Rs1 for 1 <i>idli</i>).
+
  
<br><br>
+
                        <b>Idli recipe</b>
Besides its popularity and easy accessibility, the most interesting property of <i>idli</i> is that it is fermented. To cook <i>idli</i>, people soak rice and <i>dal</i> separately, then grind and mix them together, then let the batter ferment overnight. In the hot Indian climate, the batter ferments quickly and its volume can triple overnight.  
+
                        <br><img src="https://static.igem.org/mediawiki/2015/c/ce/ParisBettencurt_idli_recipe.jpg"
<br>Many studies have been made on the microbiome of <i>idli</i> batter. Though the strains found in <i>idli</i> can be highly variable from one study to another, probably because the microbiome varies from different regions, we found that <i>Lactococcus lactis</i> and <i>Lactobacillus plantarum</i> are among the most common fermentative bacteria found in <i>idli</i> batter, while in the yeast population, <i>Saccharomyces cerevisiae</i> was always present. <font color="red">ADD SOURCES</font> Since we wanted our product to disrupt as little as possible the <i>idli</i>'s taste, we chose these organisms for production of the different vitamins and to improve iron availability, instead of adding new micro-organisms that weren’t already present in the <i>idli</i> batter that may have influenced the microbiome in an unpredictable manner. Many people who reviewed our project said that taste was of high importance, and would prefer that we modified microbes already present in the idli rather than add new ones.
+
                                style="width:450px">
<br><font color="red">+ should we talk about the advantages of fermented foods?</font></div>
+
                    </div>
 +
                    <div style="clear:both"></div>
  
<div class="column-right" align="center">
 
  
<b>Idli recipe</b>
+
                    <br><br>
<br><img src="https://static.igem.org/mediawiki/2015/c/ce/ParisBettencurt_idli_recipe.jpg" style="width:450px"></img>
+
                    <a name="safety" class="anchor"><h1></h1></a>
</div>
+
<div style="clear:both"></div>
+
  
<br><br>
+
                    <h1 class="date two" id="safety">Safety & Regulations</h1>
<h2>Taste & color</h2>
+
  
Lorem ipsum
 
  
<br><br>
+
                    <h2>Choice of Strains</h2>
<h2>An orthogonal GMO <font color="red">(is that even english??)</font></h2>
+
  
Lorem ipsum
+
                    <div class="column-left" align="justify">Since our product is meant to be used freely in households
 +
                        without containment, and to be eaten by people, safety is a major element we had to address. In
 +
                        this optic we chose to implement our pathways in Generally Considered As Safe (GRAS) organisms:
 +
                        <i>Saccharomyces cerevisiae</i>, <i>Lactobacillus plantarum</i>, <i>Lactococcus lactis</i> and
 +
                        <i>Propionibacterium freudenreichii</i> are all GRAS, commonly found in food.
 +
                        <br>We used <i>Escherichia Coli</i> to assemble our plasmids because this bacteria is easy to
 +
                        work with, but our goal is to have the vitamins produced by GRAS only.
 +
                        <br>A further step to our project would be to implement the pathways in wild type strains
 +
                        directly taken from fermented foods, instead of lab strains.
 +
                    </div>
  
 +
                    <div class="column-right" align="center">
 +
                        <img src="https://static.igem.org/mediawiki/2015/6/60/ParisBettencourt_cutebacteria.png"
 +
                            width="180px">
 +
                    </div>
 +
                    <div style="clear:both"></div>
  
<br><br>
+
                    <br><br>
<a name="safety" class="anchor"><h1></h1></a>
+
<h1 class="date two">Safety & Regulations</h1>
+
  
<h2>Choice of Strains</h2>
+
                    <h2>Toxicity</h2>
  
<div class="column-left" align="justify">Since our product is meant to be used freely in households without containment, and to be eaten by people, safety is a major element we had to address. In this optic we chose to implement our pathways in Generally Considered As Safe (GRAS) organisms: <i>Saccharomyces cerevisiae</i>, <i>Lactobacillus plantarum</i>, <i>Lactococcus lactis</i> and <i>Propionibacterium freudenreichii</i> are all GRAS, commonly found in food.
+
                    During the summer we worked on the synthesis of 3 vitamins: vitamin A, vitamin B2, and vitamin B12.
<br>We used <i>Escherichia Coli</i> to assemble our plasmids because this bacteria is easy to work with, but our goal is to have the vitamins produced by GRAS only.  
+
                    <br>No toxic or adverse effects have been associated with B12, even in very large intakes, so there
<br>A further step to our project would be to implement the pathways in wild type strains directly taken from fermented foods, instead of lab strains. <font color="red">or would it change anything if we did that, in regards to safety and regulations?? I don’t know</font></div>
+
                    is no tolerable upper intake level (UL) over which the B12 becomes toxic. And this is true for all
 +
                    the forms of B12 present in food and supplements.
 +
                    <br>The same is not true of vitamin A, though: most vitamin pills contain retinol, which is the form
 +
                    of vitamin A that is used by the human body, and which can be toxic at very high dose. The ß-carotene produced by our yeast though is not toxic, since the body only converts what it needs into retinol.
 +
                    <br>The vitamin B2 form that our micro-organism is producing is riboflavin, which can be toxic at very
 +
                    high dose. However it is very unlikely that the bacteria will produce a couple of orders of magnitude more than the daily requirement (about
 +
                    1.2mg/day), contrary to the vitamin pills that often contain a
 +
                    lot more, from 10 to 100 mg.
  
<div class="column-right" align="center">
+
                    <br><br>
<img src="https://static.igem.org/mediawiki/2015/6/60/ParisBettencourt_cutebacteria.png" width="180px"></img>
+
</div>
+
<div style="clear:both"></div>
+
  
<br><br>
+
                    <h2>European and Indian Regulations</h2>
<h2>Toxicity</h2>
+
  
During the summer we worked on the synthesis of 3 vitamins: vitamin A, vitamin B2, and vitamin B12.
+
In order to evaluate the feasibility of our product’s implementation, we researched the european and indian regulations concerning the production and distribution of genetically engineered micro-organisms.
<br>No toxic or adverse effects have been associated with B12, even in very large intakes, so there is no tolerable upper intake level (UL) over which the B12 becomes toxic. And this is true for all the forms of B12 present in food and supplements.
+
<br>The same is not true of vitamin A, though: most vitamin pills contain retinol, which is the form of vitamin A that is used by the human body. <font color="red">JB je te laisse écrire c'est quoi qui est toxique et pourquoi la ß-carotene l'est pas !! :)</font>
+
  
<br>The vitamin B2 that our micro-organism is producing is riboflavin, which can be toxic at very high dose. However it is very unlikely that we will produce more that the daily requirement (about 1.2mg/day), contrarily to the vitamin pills that we can buy on the market and that often contain a lot more, from 10 to 100 mg. <font color="red">Barth do you want to add/change anything? Please do! :)</font>
+
<br>We found that the <a href="http://ec.europa.eu/health/files/eudralex/vol-1/dir_1990_219/dir_1990_219_en.pdf">EU directive 90/219/EEC</a> of the European Economic Community relative to the contained use of GMO would allow production of this product within the european market. This directive is enforced in each of the EU member’s national regulations.
  
 
<br><br>
 
<br><br>
<h2>European Regulations</h2>
+
In India, the FSSAI (Food Safety and Standard Authority in India) told us that the safety is needed to be established in order for our product to be authorized. Both Dr. A. K. Sharma from the FSSAI and Dr. Sunita Grover the Dairy Microbiology Division at the National Dairy Research Institute <a href="https://2015.igem.org/Team:Paris_Bettencourt/Acceptance">advised us to chose micro-organisms that were already present in the fermented foods</a> we were targeting, which is what we did. These organisms are all in Risk Group 1 (Unlikely to cause human disease.), and have the GRAS status (Generally Considered As Safe).
 
+
<br>We also found out that the Indian law currently doesn’t allow GM microorganisms because of the use of antibiotic markers that makes them unsafe to eat.
Lorem ipsum
+
<br><br>But <a href="https://2015.igem.org/Team:Paris_Bettencourt/Acceptance">according to Samir K. Brahmachari</a>, former director of the Council of Scientific and Industrial Research in India, our product has a greater chance to be authorized if there is no more live bacteria in the final form of the dish, that is actually eaten. We checked this affirmation and found out this regulation:
 +
<br><br><div align="center"><i>‘...food stuffs...derived from Living Modified Organisms where the end product is NOT a Living Modified Organism are exempted from mandatory approval of the Genetic Engineering Approval Committee.’</i></div>
 +
<div align="right">Food Safety and Standards Authority of India (FSSAI)<br>
 +
Notification no. S. O. 1519(E) dated 23-8- 2007 in the Gazette of India</div>
  
 +
<br>Since the idli is steamed for 10 to 15 minutes before it is eaten, we made an experiment to assess the presence of yeasts and bacteria in the steamed idli, and found out that the steaming process effectively sterilizes the idli and eliminates the microbes present in the batter.
 
<br><br>
 
<br><br>
<h2>Indian Regulations</h2>
+
<div align="center"><b>Plates of different media, 36h after being inoculated with idli batter, before and after the batter was steamed for 10 minutes</b>
 
+
<br><img src="https://static.igem.org/mediawiki/2015/8/82/ParisBettencourt_plate_after_cooking.png" width="800px"></img></div>
Lorem ipsum
+
 
+
 
+
 
<br><br>
 
<br><br>
<a name="continuity" class="anchor"><h1></h1></a>
+
We can see than nothing grew in the plates inoculated with steamed idli batter, which indicates that all the micro-organisms present in the batter were killed during the steaming process.
<h1 class="date three">Final Product or Continuity</h1>
+
  
<h2><font color="red">Someone else (Antoine ? <3) needs to fill that...</font></h2>
+
<br>
 +
                    <a name="continuity" class="anchor"><h1></h1></a>
  
Lorem ipsum
+
                    <h1 class="date three">Continuity</h1>
  
 
+
As we wanted people to feel that our product really belong to them, we
 
+
designed it in the form of an open framework that can be modified and
<br><br><br><br>
+
improved easily. Based on precious input from the target population and
<h2>Design</h2>
+
by the Indian community of Paris, this new chassis is made for being
 
+
manufactured by factories as well as community labs, so people can be
<p>
+
sure they will always keep their independance. It allows to reduce the  
By talking about your design work on this page, there is one medal criterion that you can attempt to meet, and one award that you can apply for. If your team is going for a gold medal by building a functional prototype, you should tell us what you did on this page. If you are going for the <a href="https://2015.igem.org/Judging/Awards#SpecialPrizes">Applied Design award</a>, you should also complete this page and tell us what you did.
+
cost of research and development by abstracting the most technical
</p>
+
functions and to easily make organisms that can be homegrown and used
 
+
for nutrient production.
<div class="highlightBox">
+
<br>This way we hope that people will feel ownership on the product and
<h4>Note</h4>
+
trust that it only serves their own interests. <a href="https://2015.igem.org/Team:Paris_Bettencourt/Project/Continuity">Learn more...</a>
<p>In order to be considered for the <a href="https://2015.igem.org/Judging/Awards#SpecialPrizes">Best Applied Design award</a> and/or the <a href="https://2015.igem.org/Judging/Awards#Medals">functional prototype gold medal criterion</a>, you must fill out this page.</p>
+
 
</div>
 
</div>
 
<p>This is a prize for the team that has developed a synthetic biology product to solve a real world problem in the most elegant way. The students will have considered how well the product addresses the problem versus other potential solutions, how the product integrates or disrupts other products and processes, and how its lifecycle can more broadly impact our lives and environments in positive and negative ways.</p>
 
 
<p>
 
If you are working on art and design as your main project, please join the art and design track. If you are integrating art and design into the core of your main project, please apply for the award by completing this page.
 
</p>
 
  
 
</html>
 
</html>
 
{{Paris_Bettencourt/footer}}
 
{{Paris_Bettencourt/footer}}

Latest revision as of 01:21, 21 November 2015


Introduction


Despite many efforts from the indian government and NGO's to decrease the micronutrient deficiencies in India, there are two major limitations that prevent the vast majority of the population to access sufficient sources of vitamins and iron or phytic acid: cost, and distribution. Our project proposes an elegant solution to address both those issues, via a cost-effective biosynthesis of vitamins and phytic acid by micro-organisms, which can be cultivated in everyone’s home without any need of external infrastructure.

We decided to re-think the universal tradition of food fermentation to expand it with new possibilities. With community acceptance in mind, we developed a product that can work sustainably in the hands of people with minimal equipment, and fits equally well into the existing infrastructure set up by the Indian government to fight malnutrition by significantly reducing the production costs. This way we ensure that our product has the highest chances of reaching its target population. At the same time, we designed our product to engender people's trust, as its use is sustained without strictly depending on any third party and it is deeply rooted in their traditions.

Distribution & Availability


The Integrated Child Development Services (ICDS) programme
An important problem we wanted to tackle with our product is the access Indian people have to sources of vitamins. Indeed, we researched what structures and programs already exist in India, and found that it was a major issue.
One of the most important governmental programs for vitamin supplementation is the Integrated Child Development Services (ICDS) program, which has existed in India since 1975. This program monitors the growth and development of children, and provides supplementary nutrition as well as education and primary health care for children under six and pregnant and lactating mothers. The program is implemented through a network of community-level anganwadi centers (AWC), which provides daily supplements both in the center as well as through take-home rations. Those supplements include doses of vitamin A and tablets of iron and folic acid, in order to prevent xerophtalmia - which can lead to blindness - and anaemia.
However, the National Family Health Survey (NFHS-3) held in 2005-2006 in India reports that only 28% of children received those supplements and health care even though 4/5 of children under six lived in a region covered by an anganwadi center. In the 6 months preceding the survey, only 1/4 of the children between 12-35 months were given vitamin A supplements - and in 9 Indian states, this number falls to less than 20%. The access to ICDS has been improved in recent years, however, although access is still far from being universal (2). According to a national survey held in 2013-14, 46% of children aged 6-59 months had received doses vitamin A.
As for folic acid, the 2013-14 survey reports only 14% of children aged 6-59 months having received iron and folic acid supplements.

Though the program holds great promise and has implemented more than a million anganwadi centers, it is clear that people’s access to them is still very limited. People have to walk to the nearest center everyday if they want to receive the supplements, which is not convenient especially in rural areas.

Vitamins in everyone’s home
This observation held a major role in our design of a product that can be grown at home, in every village or household. A culture of microorganisms doesn’t require an expensive infrastructure; in fact, most Indian families have already been growing microbial cultures that are several generations old by using a part of their daily yogurt as a starter for the fermentation of the next day’s yogurt. A great part of our project was dedicated to find a cheap and edible medium in which the microbes could be cultivated at home, and to manufacture a simple and practical way to distribute our engineered yeast and bacteria (See Manufacturing page). We found that a microbial culture could be grown in a very simple medium like potato juice, and that the yeast could be lyophilized, mixed with rice flour and water, and distributed in the form of small cubes.


We believe that a culture of yeast and bacteria that can be grown at home and supplements fermented foods with vitamins could reach far more people than the anganwadi centers: those cultures would only need to be distributed once, which would not be very costly as the packages can be made to be very small and light and one culture would act as a starter culture for many more. In this way, the culture would be maintained in the home, without the need for people to travel long distances to have access to nutritional supplements.

Amma Unavagam
Another way to cheaply give people access to micronutrient-rich foods could be to implement our product in the popular canteens called Amma Unavagam (meaning “Mother Restaurants) which are being developed by the Government in the state of of Tamil Nadu, mostly in the city of Chennai. Those canteens offer people dishes like idli and dosa, both made of fermented rice, for the very cheap price of Rs. 1 for an idli ($0.01).
Those canteens are visited by thousands of people. If they were using our product during the fermentation of their rice, those people would benefit from the micronutrients produced by the engineered strains.

An adaptable solution
Our product is also more accessible in that it doesn't have the same geographic and climate constraints as cultures of rice or other crops. Contrary to Golden Rice, the rice developed by the Swiss Federal Institute of Technology and the University of Freiburg that biosynthesizes beta-carotene and can only be grown in environments with very high water availability, a microbial culture can be grown anywhere. Even though this summer we mostly focused on microbial cultures of fermented dishes composed of rice, microbes are used to ferment any kind of cereals as well as other foods. So our product can be adapted to a very wide range of fermented dishes, and could also be used by people who don’t eat rice.



Acceptance

People's opinion

Since the very beginning of our project, we researched which solution would be convenient and acceptable to them, by asking them about their habits and opinions. For this we interviewed local indian citizens, and well as local authorities in India (find the details on the Acceptance page).

We found out that people in India don’t want GMO to be associated with farmers, and they don’t want them to be dependent on one company that would have monopoly on the product. This fitted well with the idea of strains that can be grown at home by everyone. By focusing on yeast and bacteria that are kept in pots and that can be added in a dish at the user’s convenience, we are not targeting the farmers specifically, and we are not affecting the crops at all; and we are giving people an independence and way to chose at any time whether or not they want to eat the GMO.
Most of the indian people we interviewed also told us that they would try our idea of adding a vitamin-producing bacteria, as long as it is proven efficient and harmless for human health. They said that a slight change in the recipe of a dish (aka adding the yeast a bacteria so that they would ferment and produce the vitamins in the dish) would not bother them as long as the taste is not changed.
In order to not affect the taste, we chose to modify micro-organisms already present in the dish instead of adding new ones, in order to not disrupt the microbiome of the fermented dish. To check if high amounts of vitamins could change the taste, we also tasted idlis (fermented rice cakes) in which vitamin A, B2 and B12 bought in a supermarket had been added in quantities equivalent to the required daily amount, and did a blind test: people found no difference in taste at all with and without vitamins.


Why idli?

Idli (or idly) is a small steamed cake made with fermented rice and black lentils (called urad dal or dal). It is a very popular breakfast food across India, mostly in the south, and is often eaten with chutney.
We wanted our product to truly fit the traditions and tastes of the people we were targeting, and idli appeared to be the ideal dish. It is a very popular staple of the Indian diet, along with the crepe-like dosa, which is made of a similar but less coarse batter. Its two ingredients (rice and dal) are very cheap and widely available resources, and idli is commonly eaten by people who lack other types of food and who suffer from vitamin deficiencies. There is even a program that distributes free rice to the poorest populations in the country, the Public Distribution System (PDS); and in the city of Chennai and its suburbs, canteens called Amma Unavagam sell idli and other foods for very low prices (Rs1 for 1 idli).

Besides its popularity and easy accessibility, the most interesting property of idli is that it is fermented. To cook idli, people soak rice and dal separately, then grind and mix them together, then let the batter ferment overnight. In the hot Indian climate, the batter ferments quickly and its volume can triple overnight.
Many studies have been made on the microbiome of idli batter. Though the strains found in idli can be highly variable from one study to another, probably because the microbiome varies from different regions, we found that Lactococcus lactis and Lactobacillus plantarum are among the most common fermentative bacteria found in idli batter, while in the yeast population, Saccharomyces cerevisiae was always present. Since we wanted our product to disrupt as little as possible the idli's taste, we chose these organisms for production of the different vitamins and to improve iron availability, instead of adding new micro-organisms that weren’t already present in the idli batter that may have influenced the microbiome in an unpredictable manner. Many people who reviewed our project said that taste was of high importance, and would prefer that we modified microbes already present in the idli rather than add new ones.
Idli recipe


Safety & Regulations

Choice of Strains

Since our product is meant to be used freely in households without containment, and to be eaten by people, safety is a major element we had to address. In this optic we chose to implement our pathways in Generally Considered As Safe (GRAS) organisms: Saccharomyces cerevisiae, Lactobacillus plantarum, Lactococcus lactis and Propionibacterium freudenreichii are all GRAS, commonly found in food.
We used Escherichia Coli to assemble our plasmids because this bacteria is easy to work with, but our goal is to have the vitamins produced by GRAS only.
A further step to our project would be to implement the pathways in wild type strains directly taken from fermented foods, instead of lab strains.


Toxicity

During the summer we worked on the synthesis of 3 vitamins: vitamin A, vitamin B2, and vitamin B12.
No toxic or adverse effects have been associated with B12, even in very large intakes, so there is no tolerable upper intake level (UL) over which the B12 becomes toxic. And this is true for all the forms of B12 present in food and supplements.
The same is not true of vitamin A, though: most vitamin pills contain retinol, which is the form of vitamin A that is used by the human body, and which can be toxic at very high dose. The ß-carotene produced by our yeast though is not toxic, since the body only converts what it needs into retinol.
The vitamin B2 form that our micro-organism is producing is riboflavin, which can be toxic at very high dose. However it is very unlikely that the bacteria will produce a couple of orders of magnitude more than the daily requirement (about 1.2mg/day), contrary to the vitamin pills that often contain a lot more, from 10 to 100 mg.

European and Indian Regulations

In order to evaluate the feasibility of our product’s implementation, we researched the european and indian regulations concerning the production and distribution of genetically engineered micro-organisms.
We found that the EU directive 90/219/EEC of the European Economic Community relative to the contained use of GMO would allow production of this product within the european market. This directive is enforced in each of the EU member’s national regulations.

In India, the FSSAI (Food Safety and Standard Authority in India) told us that the safety is needed to be established in order for our product to be authorized. Both Dr. A. K. Sharma from the FSSAI and Dr. Sunita Grover the Dairy Microbiology Division at the National Dairy Research Institute advised us to chose micro-organisms that were already present in the fermented foods we were targeting, which is what we did. These organisms are all in Risk Group 1 (Unlikely to cause human disease.), and have the GRAS status (Generally Considered As Safe).
We also found out that the Indian law currently doesn’t allow GM microorganisms because of the use of antibiotic markers that makes them unsafe to eat.

But according to Samir K. Brahmachari, former director of the Council of Scientific and Industrial Research in India, our product has a greater chance to be authorized if there is no more live bacteria in the final form of the dish, that is actually eaten. We checked this affirmation and found out this regulation:

‘...food stuffs...derived from Living Modified Organisms where the end product is NOT a Living Modified Organism are exempted from mandatory approval of the Genetic Engineering Approval Committee.’
Food Safety and Standards Authority of India (FSSAI)
Notification no. S. O. 1519(E) dated 23-8- 2007 in the Gazette of India

Since the idli is steamed for 10 to 15 minutes before it is eaten, we made an experiment to assess the presence of yeasts and bacteria in the steamed idli, and found out that the steaming process effectively sterilizes the idli and eliminates the microbes present in the batter.

Plates of different media, 36h after being inoculated with idli batter, before and after the batter was steamed for 10 minutes


We can see than nothing grew in the plates inoculated with steamed idli batter, which indicates that all the micro-organisms present in the batter were killed during the steaming process.

Continuity

As we wanted people to feel that our product really belong to them, we designed it in the form of an open framework that can be modified and improved easily. Based on precious input from the target population and by the Indian community of Paris, this new chassis is made for being manufactured by factories as well as community labs, so people can be sure they will always keep their independance. It allows to reduce the cost of research and development by abstracting the most technical functions and to easily make organisms that can be homegrown and used for nutrient production.
This way we hope that people will feel ownership on the product and trust that it only serves their own interests. Learn more...