Difference between revisions of "Team:Madrid-OLM/Description"

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                     </li>
 
                     </li>
 
                     <li>
 
                     <li>
                         <a href="#Summary" class="inner-link" data-title="Summary"></a>
+
                         <a href="#enviro" class="inner-link" data-title="Understanding our environment"></a>
 
                     </li>
 
                     </li>
 
                     <li>
 
                     <li>
                         <a href="#Production" class="inner-link" data-title="Protein Production"></a>
+
                         <a href="#Ourvision" class="inner-link" data-title="Our vision"></a>
 
                     </li>
 
                     </li>
 
                     <li>
 
                     <li>
                         <a href="#aptamer" class="inner-link" data-title="Aptamer obtention"></a>
+
                         <a href="#iotproblem" class="inner-link" data-title="IoT Problem"></a>
 
                     </li>
 
                     </li>
 
                     <li>
 
                     <li>
                         <a href="#hardware" class="inner-link" data-title="Hardware"></a>
+
                         <a href="#iotb" class="inner-link" data-title="Internet of BioThings"></a>
 +
                    </li>
 +
                    <li>
 +
                        <a href="#core" class="inner-link" data-title="The core: Aptamer"></a>
 +
                    </li>
 +
                    <li>
 +
                        <a href="#iotb" class="inner-link" data-title="Internet of BioThings"></a>
 +
                    </li>
 +
                    <li>
 +
                        <a href="#iotb" class="inner-link" data-title="Internet of BioThings"></a>
 
                     </li>
 
                     </li>
 
   
 
   
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             </section>
 
             </section>
 
              
 
              
             <section id="Summary" class="text-center">
+
             <section id="enviro" class="text-center">
 
                 <div class="container">
 
                 <div class="container">
 
                     <div class="row boxed boxed--border bg--secondary boxed--lg box-shadow">
 
                     <div class="row boxed boxed--border bg--secondary boxed--lg box-shadow">
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                             <h2>A way of understanding our environment</h2>
 
                             <h2>A way of understanding our environment</h2>
 
                             <p class="lead">The environment is made with millions of molecules. Many of them can be hazardous and many of them beneficial. Our lives are conditioned by our surrounding molecules, and they are too small to be observed. </p>
 
                             <p class="lead">The environment is made with millions of molecules. Many of them can be hazardous and many of them beneficial. Our lives are conditioned by our surrounding molecules, and they are too small to be observed. </p>
                             <p class="lead">The society is made with millions of persons and everyone is different from the other. Unlike molecules, no two people are alike. And this is why what is beneficial for someone could be risky or dangerous for another person. </p>
+
                             <p class="lead">The society is made with millions of persons and everyone is different from the other. Unlike molecules, no two people are alike. And this is why what is beneficial for someone could be risky or dangerous for another person.</p>
 
                                  
 
                                  
 
                         </div>
 
                         </div>
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             </section>
 
             </section>
 
              
 
              
             <section id="Summary" class="text-center">
+
             <section id="Ourvision" class="text-center">
 
                 <div class="container">
 
                 <div class="container">
 
                     <div class="row boxed boxed--border bg--secondary boxed--lg box-shadow">
 
                     <div class="row boxed boxed--border bg--secondary boxed--lg box-shadow">
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                             <h2>Our vision</h2>
 
                             <h2>Our vision</h2>
 
                             <img alt="Image1" src="https://static.igem.org/mediawiki/2018/4/4c/T--Madrid-OLM--Proyect--Description--IOT.png" style="width:75%;"/>
 
                             <img alt="Image1" src="https://static.igem.org/mediawiki/2018/4/4c/T--Madrid-OLM--Proyect--Description--IOT.png" style="width:75%;"/>
                             <p class="lead">We foresee a future where people can track how molecules move through the environment in real-time, from their own mobile device.We could choose whether to give a walk around a field of blooming roses or avoid the undesirable virus that hides around the corner. We want to bring the user a new way of looking to the environment, and thus a new way of living.</p>
+
                             <p class="lead">We foresee a future where people can track how molecules move through the environment in real-time, from their own mobile device. We could choose whether to give a walk around a field of blooming roses or avoid the undesirable virus that hides around the corner. We want to bring the user a new way of looking to the environment, and thus a new way of living.</p>
 
                             <p class="lead">Our vision is beginning to exist. It is emerging now. And it is manifested when anyone receives a personalized ad, or specific information about the traffic density, CO2 concentration, etc. It has received the name of “Internet of Things”, and this is happening with physical, chemical and social indicators. Unfortunately, there are no biological measurements. Why?</p>
 
                             <p class="lead">Our vision is beginning to exist. It is emerging now. And it is manifested when anyone receives a personalized ad, or specific information about the traffic density, CO2 concentration, etc. It has received the name of “Internet of Things”, and this is happening with physical, chemical and social indicators. Unfortunately, there are no biological measurements. Why?</p>
 
                                  
 
                                  
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             </section>
 
             </section>
 
              
 
              
             <section id="Summary" class="text-center">
+
             <section id="iotproblem" class="text-center">
 
                 <div class="container">
 
                 <div class="container">
 
                     <div class="row boxed boxed--border bg--secondary boxed--lg box-shadow">
 
                     <div class="row boxed boxed--border bg--secondary boxed--lg box-shadow">
 
                         <div class="col-md-10 col-lg-10">
 
                         <div class="col-md-10 col-lg-10">
 
                             <h2>The problem of Internet of Things</h2>
 
                             <h2>The problem of Internet of Things</h2>
                             <p class="lead">Why has not the Internet of Things being enriched by the potentiality of Biology?. The answer is not straightforward.</p>
+
                             <p class="lead">Why has not the Internet of Things (<b>IoT</b>) being enriched by the potentiality of Biology?. The answer is not straightforward.</p>
 
                             <p class="lead">Getting accurate biological measurements in a laboratory is feasible. But getting these results in an automated device, placed in the street, in an affordable way is more challenging.</p>
 
                             <p class="lead">Getting accurate biological measurements in a laboratory is feasible. But getting these results in an automated device, placed in the street, in an affordable way is more challenging.</p>
 
                             <p class="lead">It might be due to the difficulty in the replicability of lab conditions. And there is another key factor to consider: the complexity of automating the lab protocols.</p>
 
                             <p class="lead">It might be due to the difficulty in the replicability of lab conditions. And there is another key factor to consider: the complexity of automating the lab protocols.</p>
                             <p class="lead">And this is finally what we have considered being worth solving with our project. And we have called it “The Internet of BioThings”</p>
+
                             <p class="lead">And this is finally what we have considered being worth solving with our project. And we have called it “The Internet of BioThings”.</p>
 
                                  
 
                                  
 
                         </div>
 
                         </div>
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                 <!--end of container-->
 
                 <!--end of container-->
 
             </section>
 
             </section>
 +
           
 +
            <section id="iotb" class="text-center">
 +
                <div class="container">
 +
                    <div class="row boxed boxed--border bg--secondary boxed--lg box-shadow">
 +
                        <div class="col-md-10 col-lg-10">
 +
                            <h2>The Internet of BioThings (IoBT)</h2>
 +
                            <p class="lead">Our goal is to manufacture a proof of concept (PoC) of the final device. The initial PoC will be made for OLE1, the major allergen in olive pollen. But the eventual goal is to scale this PoC to a wide range of molecules, as the Internet of BioThings requires.</p>
 +
                            <p class="lead">The device that we have developed has a key functionality: uploading the measurement in real-time to the cloud. To prove this capability, we have developed an initial mockup of an iOS app that simulates a number of nodes that share the surrounding information that the user requires.</p>
 +
                            <p class="lead">Our technology is real thank to the aptamers, flexible molecules that can be artificially engineered to recognize almost any kind of molecule.</p>
 +
                        </div>
 +
                    </div>
 +
                    <!--end of row-->
 +
                </div>
 +
                <!--end of container-->
 +
            </section>
 +
           
 
              
 
              
 
             <section id="Summary" class="text-center">
 
             <section id="Summary" class="text-center">
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                     <div class="row boxed boxed--border bg--secondary boxed--lg box-shadow">
 
                     <div class="row boxed boxed--border bg--secondary boxed--lg box-shadow">
 
                         <div class="col-md-10 col-lg-10">
 
                         <div class="col-md-10 col-lg-10">
                             <h2>The Internet of BioThings</h2>
+
                             <h2>The Internet of BioThings (IoBT)</h2>
 
                             <p class="lead">Our goal is to manufacture a proof of concept (PoC) of the final device. The initial PoC will be made for OLE1, the major allergen in olive pollen. But the eventual goal is to scale this PoC to a wide range of molecules, as the Internet of BioThings requires.</p>
 
                             <p class="lead">Our goal is to manufacture a proof of concept (PoC) of the final device. The initial PoC will be made for OLE1, the major allergen in olive pollen. But the eventual goal is to scale this PoC to a wide range of molecules, as the Internet of BioThings requires.</p>
                             <p class="lead">The device that we have developed has a key functionality: uploading the measurement in real-time to the cloud. To prove this capability, we have developed an initial mockup of an iOS app that simulates a number of nodes that share the surrounding information that the user requires. </p>
+
                             <p class="lead">The device that we have developed has a key functionality: uploading the measurement in real-time to the cloud. To prove this capability, we have developed an initial mockup of an iOS app that simulates a number of nodes that share the surrounding information that the user requires.</p>
 
                             <p class="lead">Our technology is real thank to the aptamers, flexible molecules that can be artificially engineered to recognize almost any kind of molecule.</p>
 
                             <p class="lead">Our technology is real thank to the aptamers, flexible molecules that can be artificially engineered to recognize almost any kind of molecule.</p>
 +
                        </div>
 +
                    </div>
 +
                    <!--end of row-->
 +
                </div>
 +
                <!--end of container-->
 +
            </section>
 +
           
 +
           
 +
            <section id="core" class="text-center">
 +
                <div class="container">
 +
                    <div class="row boxed boxed--border bg--secondary boxed--lg box-shadow">
 +
                        <div class="col-md-10 col-lg-10">
 +
                            <h2>Aptamers: the core of our device</h2>
 +
                            <p class="lead">Aptamers are single stranded DNA molecules. They work in a similar way to antibodies, but they have two advantages: they are almost inexpensive and much more stable. </p>
 +
                            <p class="lead">We have chosen aptamers because they are stable and affordable. We need them to be stable, because their nominal working conditions are going to be outdoors, outside the lab environment, in a tougher scenario. And we want them to be affordable because we want to place a huge number of devices. And for this purpose we need accessible materials. </p>
 +
                            <p class="lead">Aptamers are designed through an artificial evolution process called <b>Systematic Evolution of Ligands by EXponential Selection</b> (SELEX).</p>
 +
                            <p class="lead">Some iGEM teams have tried to implement the SELEX process looking forward to designing their own aptamers. But nevertheless, due to the high amount of time and cost involved, as well as the complexity of the required techniques, no previous iGEM teams have presented satisfactory results in this field.</p>
 +
                            <p class="lead">We are presenting at iGEM, for the first time, a way of doing the SELEX, reducing both costs and effort, and manufacturing the required component with a 3D printer. The component that make the difference is a 3D printed eppendorf spin columns with nitrocellulose filters.</p>
 
                         </div>
 
                         </div>
 
                     </div>
 
                     </div>

Revision as of 11:27, 15 October 2018

Madrid-OLM

Description

Description of the proyect

A way of understanding our environment

The environment is made with millions of molecules. Many of them can be hazardous and many of them beneficial. Our lives are conditioned by our surrounding molecules, and they are too small to be observed.

The society is made with millions of persons and everyone is different from the other. Unlike molecules, no two people are alike. And this is why what is beneficial for someone could be risky or dangerous for another person.

Our vision

Image1

We foresee a future where people can track how molecules move through the environment in real-time, from their own mobile device. We could choose whether to give a walk around a field of blooming roses or avoid the undesirable virus that hides around the corner. We want to bring the user a new way of looking to the environment, and thus a new way of living.

Our vision is beginning to exist. It is emerging now. And it is manifested when anyone receives a personalized ad, or specific information about the traffic density, CO2 concentration, etc. It has received the name of “Internet of Things”, and this is happening with physical, chemical and social indicators. Unfortunately, there are no biological measurements. Why?

The problem of Internet of Things

Why has not the Internet of Things (IoT) being enriched by the potentiality of Biology?. The answer is not straightforward.

Getting accurate biological measurements in a laboratory is feasible. But getting these results in an automated device, placed in the street, in an affordable way is more challenging.

It might be due to the difficulty in the replicability of lab conditions. And there is another key factor to consider: the complexity of automating the lab protocols.

And this is finally what we have considered being worth solving with our project. And we have called it “The Internet of BioThings”.

The Internet of BioThings (IoBT)

Our goal is to manufacture a proof of concept (PoC) of the final device. The initial PoC will be made for OLE1, the major allergen in olive pollen. But the eventual goal is to scale this PoC to a wide range of molecules, as the Internet of BioThings requires.

The device that we have developed has a key functionality: uploading the measurement in real-time to the cloud. To prove this capability, we have developed an initial mockup of an iOS app that simulates a number of nodes that share the surrounding information that the user requires.

Our technology is real thank to the aptamers, flexible molecules that can be artificially engineered to recognize almost any kind of molecule.

The Internet of BioThings (IoBT)

Our goal is to manufacture a proof of concept (PoC) of the final device. The initial PoC will be made for OLE1, the major allergen in olive pollen. But the eventual goal is to scale this PoC to a wide range of molecules, as the Internet of BioThings requires.

The device that we have developed has a key functionality: uploading the measurement in real-time to the cloud. To prove this capability, we have developed an initial mockup of an iOS app that simulates a number of nodes that share the surrounding information that the user requires.

Our technology is real thank to the aptamers, flexible molecules that can be artificially engineered to recognize almost any kind of molecule.

Aptamers: the core of our device

Aptamers are single stranded DNA molecules. They work in a similar way to antibodies, but they have two advantages: they are almost inexpensive and much more stable.

We have chosen aptamers because they are stable and affordable. We need them to be stable, because their nominal working conditions are going to be outdoors, outside the lab environment, in a tougher scenario. And we want them to be affordable because we want to place a huge number of devices. And for this purpose we need accessible materials.

Aptamers are designed through an artificial evolution process called Systematic Evolution of Ligands by EXponential Selection (SELEX).

Some iGEM teams have tried to implement the SELEX process looking forward to designing their own aptamers. But nevertheless, due to the high amount of time and cost involved, as well as the complexity of the required techniques, no previous iGEM teams have presented satisfactory results in this field.

We are presenting at iGEM, for the first time, a way of doing the SELEX, reducing both costs and effort, and manufacturing the required component with a 3D printer. The component that make the difference is a 3D printed eppendorf spin columns with nitrocellulose filters.