Team:KAIST-Korea/Notebook/Diary/April

From 2010.igem.org

(Difference between revisions)
 
(22 intermediate revisions not shown)
Line 1: Line 1:
__NOTOC__
__NOTOC__
-
<html>
+
{{:Team:KAIST/header}}
-
<style type="text/css">
+
-
body.mediawiki {background-color:#BDE7EF;}
+
-
h1.firstHeading {display: none;}
+
-
#bodyContent { background-color:#FFFFFF;}
+
-
</style>
+
-
</html>
+
-
 
+
-
<html><embed src="https://static.igem.org/mediawiki/2010/0/02/KAISTMenuR.swf" width="960" height="106"></html>
+
<table width="100%" border="0">
<table width="100%" border="0">
Line 15: Line 7:
<td valign="top">
<td valign="top">
-
<table width="100%" border="1">
+
 
 +
<table width="100%">
<tr>
<tr>
-
<td>
+
<td align=center >
-
4
+
<html><a href="https://2010.igem.org/Team:KAIST-Korea/Notebook/Diary/April"><img src="https://static.igem.org/mediawiki/2010/e/e1/April.jpg" width=100></a></html>
</td>
</td>
-
<td>
+
<td align=center >
-
5
+
<html><a href="https://2010.igem.org/Team:KAIST-Korea/Notebook/Diary/May"><img src="https://static.igem.org/mediawiki/2010/6/6d/5%EC%9B%94.jpg
 +
" width=100></a></html>
</td>
</td>
-
<td>
+
<td align=center >
-
6
+
<html><a href="https://2010.igem.org/Team:KAIST-Korea/Notebook/Diary/June"><img src=" https://static.igem.org/mediawiki/2010/3/31/6%EC%9B%94.jpg" width=100></a></html>
 +
 
</td>
</td>
-
<td>
+
<td align=center >
-
7
+
<html><a href="https://2010.igem.org/Team:KAIST-Korea/Notebook/Diary/July"><img src="https://static.igem.org/mediawiki/2010/4/49/7%EC%9B%94.jpg
 +
" width=100></a></html>
</td>
</td>
-
</tr>
+
 
-
<tr>
+
<td align=center >
-
<td>
+
<html><a href="https://2010.igem.org/Team:KAIST-Korea/Notebook/Diary/August"><img src="https://static.igem.org/mediawiki/2010/5/55/8%EC%9B%94.jpg
-
8
+
" width=100></a></html>
</td>
</td>
-
<td>
+
<td align=center >
-
9
+
<html><a href="https://2010.igem.org/Team:KAIST-Korea/Notebook/Diary/September"><img src="https://static.igem.org/mediawiki/2010/0/02/9%EC%9B%94.jpg
 +
" width=100></a></html>
</td>
</td>
-
<td>
+
<td align=center >
-
10
+
<html><a href="https://2010.igem.org/Team:KAIST-Korea/Notebook/Diary/October"><img src="https://static.igem.org/mediawiki/2010/9/91/10%EC%9B%94.jpg
 +
" width=100></a></html>
</td>
</td>
-
<td>
+
<td align=center >
-
11
+
<html><a href="https://2010.igem.org/Team:KAIST-Korea/Notebook/Diary/November"><img src="https://static.igem.org/mediawiki/2010/3/35/11%EC%9B%94.jpg
 +
" width=100></a></html>
</td>
</td>
</tr>
</tr>
</table>
</table>
-
 
+
<table width="100%" border="0" cellpadding="20px">
 +
<tr>
 +
<td>
== April 17, 18, 22 ==
== April 17, 18, 22 ==
Brain storming/gathering ideas.<br><br>
Brain storming/gathering ideas.<br><br>
Line 52: Line 53:
<span style=font-size:15px> <b> Idea 1 </b> </span>
<span style=font-size:15px> <b> Idea 1 </b> </span>
<br>
<br>
-
Alcanivorax Borkumensis is the bacteria that releases enzyme that can decompose oil. And we can design like insulin producing system to solve oil spilling problems in ocean.
+
Alcanivorax Borkumensis is the bacteria that releases enzyme that can decompose oil. And we can design something like insulin producing system to solve oil spilling problems in ocean.  
-
problem
+
<br>
-
There already exists this system. <br><br>
+
Problem: Similar system already exists. <br><br>
<span style=font-size:15px> <b> Idea 2 </b> </span>
<span style=font-size:15px> <b> Idea 2 </b> </span>
<br>
<br>
-
Virus targets specific cells. They generally have one host. With this idea we can make drug delivery system. We can use receptor of coronavirus to target. Since we commonly catch a cold but we don't get seriously hurt, we could use this system on DDS.  
+
Virus targeting-specific cells; they generally have one specific host. We can make drug delivery system. We can use receptor of coronavirus to target. Since we commonly catch cold, but we don't get seriously hurt, we could use this system for DDS.
-
problem
+
<br>
-
It has to be tested to be proved to be a drug. <br><br>
+
Problem: It has to be tested to be proved to be a drug (require clinical study, etcs.; out of our range). <br><br>
<span style=font-size:15px> <b> Idea 3 </b> </span>
<span style=font-size:15px> <b> Idea 3 </b> </span>
<br>
<br>
-
There are common system call photosynthesis. We can use this idea to make new bacteria to imitate this system. And make this as a paint or we can extract only the chloroplast part alone or using cyanobacteria to make some kind of battery.
+
We can make new bacteria that imitate photosynthesis. We can extract only chloroplast part of photosynthesizing organisms – for instance, plants – or use cyanobacteria to make some kind of energy generating building parts: paint (cyanobacteria is the photosynthesizing bacteria). In case of stromatolite, we can use it as building structure.  
-
We can use cyanobacteria because it literally do photosynthesis. And in case of stromatolite we can use it as building structure.
+
<br>
-
problem
+
Problem: We have to make e.coli to be as big as chloroplast. Also, since it physically surrounds building, there is problem when there is no sun or in bad weather. When it rains it could mess up sewage system.<br><br>
-
We have to make e.coli to be as big as chloroplast. And we have to make it to be paint. There is problem when there is no sun or in bad wether. When it rains it could mess up sewage system.<br><br>
+
<span style=font-size:15px> <b> Idea 4 </b> </span>
<span style=font-size:15px> <b> Idea 4 </b> </span>
<br>
<br>
-
Making a NAND gate with E.coli. We can use 0/1 logic with some kind of chemicals as input and output. And we can make middle phase chemical not to mixed up with input and output chemical. We are thinking of lactose tryptophan as input. Since Stanford has basic skills on this we can use this. If we make this, we can make a flip flop which is basic component of memory system.
+
Making a NAND gate with E.coli. We can use 0/1 logic with some kind of chemicals as input and output. And, we can make intermediate phase to prevent unintentional mix up of input and output chemical. We are thinking of lactose tryptophan as input. Since Stanford has done some basic works on this, we can take that advantage. If we make this, we can make a flip flop which is the basic component of memory system.  
-
problem
+
<br>
-
If we use chemical as input and output we have to control chemical level. We have to make a system threshold to differentiate 0 or 1.<br><br>
+
Problem: If we use chemical as input and output we have to control chemical level. We have to make a system threshold to differentiate 0 or 1.<br><br>
<span style=font-size:15px> <b> Idea 5 </b> </span>
<span style=font-size:15px> <b> Idea 5 </b> </span>
<br>
<br>
-
This idea is making a photographer with yeast. We are making a photographer with RGB cone cell and fluorescence. There are already exists a study about cone cell receptors. We are thinking that we make RGB ratio as 40:20:1 like human retina. Film would be yeast. Therefore it can grow infinitely.  
+
Making a photographer with yeast. We are making a photographer with RGB cone cells and fluorescence. There already exists a study on cone cell receptors. We can make RGB ratio as 40:20:1 like human retina. Film would be yeast. Therefore, it can grow infinitely.
-
problem
+
<br>
-
film is not copiable. We have to be careful not to get light on film after taking a picture. It is not a matter of sensing but processing the images on brain. Therefore we are not sure that it would work. <br><br>
+
Problem: Film cannot be copied. We have to be careful not to get light on film after taking a picture. It is not a matter of sensing but processing images in brain. Therefore, we are not sure of the feasibility. <br><br>
<span style=font-size:15px> <b> Idea 6 </b> </span>
<span style=font-size:15px> <b> Idea 6 </b> </span>
<br>
<br>
-
copyteria. We make a system as a copier. We put dye or degrader in e.coli. it would be important to design threshold. We have to make bacteria to be alive during the coping process and loose its color after the coping process. So we are making bacteria ink.  
+
Copyteria; we make a bacterium that copies. We put dye or degrader in e.coli. It would be important to design a threshold. We have to make bacteria to be alive during the coping process and lose its color after the coping process. So we are making bacteria ink.  
-
problem
+
<br>
-
We don't know the threshold for the light to be copied. And we might have to do this in dark room. Since the idea is getting the image from the reflected image we don't know how this reflected image would be copied.<br><br><br>
+
Problem: we don't know the threshold, and, even if it works, Copyteria have to perform in a dark room. Since the idea is to get an image from a reflected image, we don't know how this reflected image would be copied: too many unknown variables.<br><br><br>
== April 30 ==
== April 30 ==
Line 92: Line 92:
<span style=font-size:15px> <b> Idea 1 </b> </span>
<span style=font-size:15px> <b> Idea 1 </b> </span>
<br>
<br>
-
leeches prevent blood to be harden. And there are product using vampire bat. If we use bacteria this as anti coagulant. We can localize this using bacteria.
+
Leeches prevent blood to from coagulating. There is already a product derived from vampire bat. If we use similar system to make anti-coagulant using bacteria, it may solve localization problems related with conventional anti-coagulants.  
<br><br>
<br><br>
<span style=font-size:15px> <b> Idea 2 </b> </span>
<span style=font-size:15px> <b> Idea 2 </b> </span>
<br>
<br>
-
Using bacteria we could make a carrier that have chemicals that can cure cancer with targeting.  
+
Using bacteria, we could make a carrier that has chemicals that can cure cancer with targeting-capability.
<br><br>
<br><br>
<span style=font-size:15px> <b> Idea 3 </b> </span>
<span style=font-size:15px> <b> Idea 3 </b> </span>
<br>
<br>
-
Using magnetosome we could make a system that can detect magnetic field like other iGEM team detected toxicity.
+
Using magnetosome, we could make a system that can detect magnetic field just like other iGEM teams made product that detect toxicity.
-
problem
+
<br>
-
This bacteria is reacting passively to the magnetic field. Therefore it is not appropriate for detection.
+
Problem: It would be reacting passively to the magnetic field, so it is not appropriate for detection.  
<br><br>
<br><br>
<span style=font-size:15px> <b> Idea 4 </b> </span>
<span style=font-size:15px> <b> Idea 4 </b> </span>
<br>
<br>
-
Want to make a oscillator. There are memory network that remembers. And with that we can combine this with telomere. We can later use this protocol.
+
We want to make an oscillator. There is a memory network used in remembering. We can combine it with telomere. We can manipulate time using this protocol.  
<br><br>
<br><br>
<span style=font-size:15px> <b> Idea 5 </b> </span>
<span style=font-size:15px> <b> Idea 5 </b> </span>
<br>
<br>
-
Using vibration maybe we can make bacteria make sound.  
+
Using vibration, maybe we can make bacteria that make sound.
<br><br>
<br><br>
<span style=font-size:15px> <b> Idea 6 </b> </span>
<span style=font-size:15px> <b> Idea 6 </b> </span>
<br>
<br>
-
If we can make a NAND gate, we can make a calculator. Maybe we can make a compare system. And maybe we can use this for comparing concentration difference. And in case of NAND gate maybe we can in one cell system. If we make this in one cell then we can apply on other similar systems.
+
If we can make a NAND gate, we can make a calculator. Maybe we can make a compare system. We can use this for comparing concentration difference, and we may use it in a cell system that we will build.  
<br><br>
<br><br>
<span style=font-size:15px> <b> Idea 7 </b> </span>
<span style=font-size:15px> <b> Idea 7 </b> </span>
<br>
<br>
-
We can put antigen in mosquitoes saliva And naturally we put antigens in people to get tolerance to malaria. Since malaria mosquitoes are active at night we can use mosquitoes that are active at day.  
+
We can put antigen in mosquitoes’ saliva, and the mosquitoes would naturally put antigens in people to build them immunity against malaria. Since malaria mosquitoes are active only during night, we can use mosquitoes that are active during day.  
-
problem
+
<br>
-
It could make a problem if accidently inject too much antigens.
+
Problem: It could make a problem if mosquitoes accidently inject too much antigens
<br><br>
<br><br>
<span style=font-size:15px> <b> Idea 8 </b> </span>
<span style=font-size:15px> <b> Idea 8 </b> </span>
<br>
<br>
-
In case of DDS packing is the problem. And we can use vesicle system for packing.
+
In case of DDS, packing is the problem. And we can use vesicle system for packing.
<br><br>
<br><br>
<span style=font-size:15px> <b> Idea 9 </b> </span>
<span style=font-size:15px> <b> Idea 9 </b> </span>
<br>
<br>
-
Using Na+ pump maybe we can make electricity. Even there is a similar study that is exists. There are microorganism battery which circulate electron. If we use this system in bacteria we might make battery.
+
Using Na+ pump, we can make electricity: many related studies exist. There are microorganisms, which circulate electron. If we use this system in bacteria we might make battery.  
<br><br>
<br><br>
<span style=font-size:15px> <b> Idea 10 </b> </span>
<span style=font-size:15px> <b> Idea 10 </b> </span>
<br>
<br>
-
RBC can trap virus because virus can't replicate in RBC. But this system need to use fake cell only to delay. And only has probability to trap. Therefore it is not perfect system. Maybe Since it is making delay, we can use it at rabies because its infection timing is faster than recovering timing.
+
RBCs can trap virus because virus can't replicate in RBCs. Such system can only delay infection; it is no cure. Therefore, it is not perfect system. However, many possible applications remain; we can use it for rabies because the infection proceeds faster than healing process.  
<br><br>
<br><br>
<span style=font-size:15px> <b> Idea 11 </b> </span>
<span style=font-size:15px> <b> Idea 11 </b> </span>
<br>
<br>
-
There are many steps in mammalian cell replication if we make a mammalian cell replicatable in vitro, it would be very convenient in laboratory life.  
+
There are many steps in mammalian cell replication. If we make a mammalian cell replicable in vitro, it would be very convenient for researchers.
<br><br><br>
<br><br><br>
<span style=font-size:17px> <b> Idea Sum-up </b> </span>
<span style=font-size:17px> <b> Idea Sum-up </b> </span>
<br>
<br>
-
Maybe we can work on mammalian cell replication tool or DDS that works on respiratory system. So we decided to look for that information.
+
We can work on mammalian cell replication tool or DDS that works on respiratory system. So, we decided to dig more on those topics.  
-
 
+
</td>
 +
</tr>
 +
</table>
</td>
</td>
-
<td valign="top" align="center" height="1000" width="25%" bgcolor="#BDE7EF">
+
 
-
Sub-Menu
+
-
</td>
+
</tr>
</tr>
</table>
</table>

Latest revision as of 05:13, 17 October 2010

 

April 17, 18, 22

Brain storming/gathering ideas.

Idea 1
Alcanivorax Borkumensis is the bacteria that releases enzyme that can decompose oil. And we can design something like insulin producing system to solve oil spilling problems in ocean.
Problem: Similar system already exists.

Idea 2
Virus targeting-specific cells; they generally have one specific host. We can make drug delivery system. We can use receptor of coronavirus to target. Since we commonly catch cold, but we don't get seriously hurt, we could use this system for DDS.
Problem: It has to be tested to be proved to be a drug (require clinical study, etcs.; out of our range).

Idea 3
We can make new bacteria that imitate photosynthesis. We can extract only chloroplast part of photosynthesizing organisms – for instance, plants – or use cyanobacteria to make some kind of energy generating building parts: paint (cyanobacteria is the photosynthesizing bacteria). In case of stromatolite, we can use it as building structure.
Problem: We have to make e.coli to be as big as chloroplast. Also, since it physically surrounds building, there is problem when there is no sun or in bad weather. When it rains it could mess up sewage system.

Idea 4
Making a NAND gate with E.coli. We can use 0/1 logic with some kind of chemicals as input and output. And, we can make intermediate phase to prevent unintentional mix up of input and output chemical. We are thinking of lactose tryptophan as input. Since Stanford has done some basic works on this, we can take that advantage. If we make this, we can make a flip flop which is the basic component of memory system.
Problem: If we use chemical as input and output we have to control chemical level. We have to make a system threshold to differentiate 0 or 1.

Idea 5
Making a photographer with yeast. We are making a photographer with RGB cone cells and fluorescence. There already exists a study on cone cell receptors. We can make RGB ratio as 40:20:1 like human retina. Film would be yeast. Therefore, it can grow infinitely.
Problem: Film cannot be copied. We have to be careful not to get light on film after taking a picture. It is not a matter of sensing but processing images in brain. Therefore, we are not sure of the feasibility.

Idea 6
Copyteria; we make a bacterium that copies. We put dye or degrader in e.coli. It would be important to design a threshold. We have to make bacteria to be alive during the coping process and lose its color after the coping process. So we are making bacteria ink.
Problem: we don't know the threshold, and, even if it works, Copyteria have to perform in a dark room. Since the idea is to get an image from a reflected image, we don't know how this reflected image would be copied: too many unknown variables.


April 30

Brain storming.

Idea 1
Leeches prevent blood to from coagulating. There is already a product derived from vampire bat. If we use similar system to make anti-coagulant using bacteria, it may solve localization problems related with conventional anti-coagulants.

Idea 2
Using bacteria, we could make a carrier that has chemicals that can cure cancer with targeting-capability.

Idea 3
Using magnetosome, we could make a system that can detect magnetic field just like other iGEM teams made product that detect toxicity.
Problem: It would be reacting passively to the magnetic field, so it is not appropriate for detection.

Idea 4
We want to make an oscillator. There is a memory network used in remembering. We can combine it with telomere. We can manipulate time using this protocol.

Idea 5
Using vibration, maybe we can make bacteria that make sound.

Idea 6
If we can make a NAND gate, we can make a calculator. Maybe we can make a compare system. We can use this for comparing concentration difference, and we may use it in a cell system that we will build.

Idea 7
We can put antigen in mosquitoes’ saliva, and the mosquitoes would naturally put antigens in people to build them immunity against malaria. Since malaria mosquitoes are active only during night, we can use mosquitoes that are active during day.
Problem: It could make a problem if mosquitoes accidently inject too much antigens?

Idea 8
In case of DDS, packing is the problem. And we can use vesicle system for packing.

Idea 9
Using Na+ pump, we can make electricity: many related studies exist. There are microorganisms, which circulate electron. If we use this system in bacteria we might make battery.

Idea 10
RBCs can trap virus because virus can't replicate in RBCs. Such system can only delay infection; it is no cure. Therefore, it is not perfect system. However, many possible applications remain; we can use it for rabies because the infection proceeds faster than healing process.

Idea 11
There are many steps in mammalian cell replication. If we make a mammalian cell replicable in vitro, it would be very convenient for researchers.


Idea Sum-up
We can work on mammalian cell replication tool or DDS that works on respiratory system. So, we decided to dig more on those topics.