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h3content.html("Biological"); | h3content.html("Biological"); | ||
− | pcontent.html("Riboswitches used to find RNA from | + | pcontent.html("Riboswitches used to find RNA from Legionella allowing reliable confirmation of the presence of the live bacteria."); |
break; | break; | ||
case 1: | case 1: | ||
h3content.html("Organic"); | h3content.html("Organic"); | ||
− | pcontent.html("Utilising bacteria, specifically E.coli, to degrade | + | pcontent.html("Utilising bacteria, specifically E.coli, to degrade Oestrogen from water to help out wildlife."); |
break; | break; | ||
case 2: | case 2: | ||
h3content.html("Inorganic"); | h3content.html("Inorganic"); | ||
− | pcontent.html("Utilisting the lead absorbing properties of B.subtilis bacteria to collect lead from water and with a newly injected gas vesicle gene to make the bacteria float | + | pcontent.html("Utilisting the lead absorbing properties of B.subtilis bacteria to collect lead from water and with a newly injected gas vesicle gene to make the bacteria float to the surface for easy collection."); |
break; | break; | ||
} | } | ||
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<div class='contentDivs' id='CDiv1'> | <div class='contentDivs' id='CDiv1'> | ||
<h1>Why water safety?</h1> | <h1>Why water safety?</h1> | ||
− | <p>Access to safe water is among the many crises we face as a growing population. | + | <p>Access to safe water is among the many crises we face as a growing population. The WHO estimates that 2.1 billion people lack access to safely managed drinking water services (http://www.un.org/en/sections/issues-depth/water/) , and it is estimated that $260B lost globally each year due to lack of basic water. <a href='https://water.org/our-impact/water-crisis/'>source</a><br><br>When we tried to break down this problem, we were overwhelmed by the many different types of contaminants in water, each of which require different approaches to their removal. We decided to look into how to remove on of each in three main sub-categories of contaminants: Biological, Organic and Inorganic.<br><br>Looking into this event, we realised there were many different types of contaminants in water, each of which require different approaches to their removal. We decided to look into how to remove on of each in three main sub-categories of contaminants: Biological, Organic and Inorganic.</p> |
− | The | + | |
− | Looking into this event, we realised there were many different types of contaminants in water, each of which require different approaches to their removal. We decided to look into how to remove on of each in three main sub-categories of contaminants: Biological, Organic and Inorganic. | + | |
− | </p> | + | |
</div> | </div> | ||
<div class='contentDivs' id='CDiv2'> | <div class='contentDivs' id='CDiv2'> | ||
<h1>Three very different problems: Lead, Legionella and Oestrogen.</h1> | <h1>Three very different problems: Lead, Legionella and Oestrogen.</h1> | ||
− | <p> | + | <p>We are tackling the bioremediation of waters, focusing on three water pollutants in particular: the organic (oestrogen), inorganic (lead) and biological (legionella). Core concepts of synthetic biology were used create circuits which degrade, remove and detect these pollutants respectively.<br><br>Our projects are ambitious and attempt to solve a wide range of problems that aren’t connected to each other by a unified solution, and that’s not what we are trying to come up with. Each of these areas we have invested in were chosen based on the resources we had as a university in terms of expertise, equipment and experience.</p> |
− | Our projects are ambitious and attempt to solve a wide range of problems that aren’t connected to each other by a unified solution, and that’s not what we are trying to come up with. Each of these areas we have invested in were chosen based on the resources we had as a university in terms of expertise, equipment and experience. | + | |
− | </p> | + | |
</div> | </div> | ||
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</h1><br> | </h1><br> | ||
<p style='font-weight: 300; font-size: 1.5vw; width: 60%; margin: 0 auto'> | <p style='font-weight: 300; font-size: 1.5vw; width: 60%; margin: 0 auto'> | ||
− | Here on the Ripple iGEM team we are dedicating ourselves to making water safe again; not just for the ourselves, but for the surrounding environments and | + | Here on the Ripple iGEM team we are dedicating ourselves to making water safe again; not just for the ourselves, but for the surrounding environments and wildlife too. |
</p> | </p> | ||
<br> | <br> |
Latest revision as of 02:10, 18 October 2018
Ripple
Biological
Organic
Inorganic
Solutions to clean water
Why water safety?
Access to safe water is among the many crises we face as a growing population. The WHO estimates that 2.1 billion people lack access to safely managed drinking water services (http://www.un.org/en/sections/issues-depth/water/) , and it is estimated that $260B lost globally each year due to lack of basic water. source
When we tried to break down this problem, we were overwhelmed by the many different types of contaminants in water, each of which require different approaches to their removal. We decided to look into how to remove on of each in three main sub-categories of contaminants: Biological, Organic and Inorganic.
Looking into this event, we realised there were many different types of contaminants in water, each of which require different approaches to their removal. We decided to look into how to remove on of each in three main sub-categories of contaminants: Biological, Organic and Inorganic.
Three very different problems: Lead, Legionella and Oestrogen.
We are tackling the bioremediation of waters, focusing on three water pollutants in particular: the organic (oestrogen), inorganic (lead) and biological (legionella). Core concepts of synthetic biology were used create circuits which degrade, remove and detect these pollutants respectively.
Our projects are ambitious and attempt to solve a wide range of problems that aren’t connected to each other by a unified solution, and that’s not what we are trying to come up with. Each of these areas we have invested in were chosen based on the resources we had as a university in terms of expertise, equipment and experience.
Click one
Ripple is
Making water safe again, one step at a time
Here on the Ripple iGEM team we are dedicating ourselves to making water safe again; not just for the ourselves, but for the surrounding environments and wildlife too.
igem@warwick.ac.uk