Team:Valencia/WetLab/YeastTeam/Experimental

From 2009.igem.org

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<span style="color:red; align:justify; font-size:20pt; font-family: Verdana"> Pay attention, in few days we could have succes!!
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== '''Different experimental designs''' ==
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<span style="color:black; align:justify; font-size:11pt; font-family: Verdana">To make measurements properly and determinate luminiscence levels, we needed a luminometer. But we couldn’t use one before September. So, if we didn’t want to waste our limited time, we decided to try with other machines.
 +
 
 +
<span style="color:black; align:justify; font-size:11pt; font-family: Verdana">This way, we had dt ideas, and we thought a GelDoc camera, an espectophotometer and a espectofluorimeter could be useful for us, at least to determinate the presence/absence of the luminiscence.
 +
 
 +
 
 +
 
 +
<div style="color:black; text-align:center; font-size:12pt; font-family: Verdana"><b>GELDOC</b></div>
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 +
 
 +
 
 +
[[Image:Igem2b.JPG|thumb|center|400 px|]]
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 +
 
 +
<span style="color:black; align:justify; font-size:11pt; font-family: Verdana">That was the first idea we got. It consisted to try to capture the luminiscence produced by our yeast with the camera that is normaly used to take gel photos. We thought that if we increased exposure time, we could acumulate enough luminiscence produced in time to see it, at the photo.
 +
 
 +
<span style="color:black; align:justify; font-size:11pt; font-family: Verdana">We put our yeast after the different steps of our protocol in a multi-hole plaque and add the alcaline input. Fastly, we used to close the GelDoc door, but we had doubts about the velocity of the response, and we couldn’t be inside the GelDoc to start the measure at the same time we make the input.  In order to make sure our yeasts weren’t making light too fast, we designed a very simple but precise mechanism. We called it PippeteEnlarger.
 +
 
 +
 
 +
<div style="color:black; text-align:center; font-size:12pt; font-family: Verdana"><b>PIPPETE ENLARGER</b></div>
 +
 
 +
[[Image:Igem1.JPG|thumb|center|500 px|]]
 +
 
 +
<span style="color:black; align:justify; font-size:11pt; font-family: Verdana">The Pippete Enlarger is easy to assemble using a pippete, a thin tube and two pippete tips: one has to fit into the tub (so size tip deppends on size tub) and the another one has to be the proper tip to take the volume we want.
 +
 
 +
<span style="color:black; align:justify; font-size:11pt; font-family: Verdana">So, we will explain the mechanisme in the way we did it. We needed to make an input of 30 microliters of KOH without open the door. We had to enlarge the pippete to put the tip in the correct hole with the closed door and trigger the mechanism out of the GelDoc. We decided to full the tube with KOH, make pressure in one of the extrems of the tube, preventing by capilarity the liquid go away, and connect the pippete with an intermediary tip in the other extrem (the volume had to be already prefixed). The extrem we were pressing could be released at this point, so we could put the correct tip (in our chase, a yellow tip) to catch the desired volume. Before to be loaded with 30 microliters of KOH, we fixed the tip in the hole we wanted, we closed the door and carry on the pippete outside the GelDoc.
 +
 
 +
<span style="color:black; align:justify; font-size:11pt; font-family: Verdana">We were ready to start the measurement, making sure we increased enough the exposure time. Then, we pulled out the 30 microlitres actioning the pippete. It was surprisingly acurate!!! The volume was almost exactly, with 1 or 2 microliters of error. We dind’t got any result.
 +
We could rule out, then, the possibility that our yeasts produce light meanwhile we were putting them in the GelDoc, or we were closing the door...
 +
 
 +
<span style="color:black; align:justify; font-size:11pt; font-family: Verdana">GelDoc camera was not an efficient way to detect our luminiscence, so we thought perhaps a spectrophotometer was a more addient machine.
 +
 
 +
 
 +
 
 +
 
 +
 
 +
 
 +
<div style="color:black; text-align:center; font-size:12pt; font-family: Verdana"><b>SPECTROPHOTOMETER</b></div>
 +
 
 +
 
 +
[[Image:Igem19.JPG|thumb|right|315 px|]]
 +
 
 +
[[Image:Igem8.JPG|thumb|left|315 px|]]
 +
 
 +
 
 +
 
 +
 
 +
<span style="color:black; align:justify; font-size:11pt; font-family: Verdana">Altough an spectophotometer is a machine that measures how cloudy a sample is, by emitting a ray of light, we can “trick” the machine. Sticking a piece of silver paper in one of the faces of the little tank, we prevent the ray of light cross the sample. The idea is to measure only the light produced by the sample, not the “crossing light”.
 +
 
 +
<span style="color:black; align:justify; font-size:11pt; font-family: Verdana">We didn’t obtain any result, but that was probably because the spectrophotometer has been designed to detect a very located light ray, not a difused light produced by a bioluminiscent sample.
 +
 
 +
 
 +
 
 +
 
 +
 
 +
 
 +
<div style="color:black; text-align:center; font-size:12pt; font-family: Verdana"><b>SPECTROFLUORIMETER</b></div>
 +
 
 +
 
 +
[[Image:Igem9.JPG|thumb|center|500 px|]]
 +
 
 +
[[Image:MedidafluorimetroVII.jpg|thumb|right|315 px|]]
 +
 
 +
[[Image:MedidafluorimetroVI.jpg|thumb|left|315 px|]]
 +
 
 +
[[Image:Igem13.JPG|thumb|right|315 px|]]
 +
 
 +
[[Image:Igem17.JPG|thumb|left|315 px|]]
 +
 
 +
 
 +
 
 +
 
 +
 
 +
<span style="color:black; align:justify; font-size:11pt; font-family: Verdana">Spectrofluorimeter measures the fluorescence of a sample. That’s because it has the same problem of the spectrophotometer. However, we found that it’s more sensible (it detects a great quantity of noise). So we thought it could be a more proper machine to our purposes.
 +
 
 +
<span style="color:black; align:justify; font-size:11pt; font-family: Verdana">We designed a similar experiment, covering the place where the ray of light is emited, in order to measure only the bioluminiscence produced by our yeasts.
 +
 
 +
<span style="color:black; align:justify; font-size:11pt; font-family: Verdana">We didn’t obtain any result. But we were worried about the speed of the reaction another time. Then, we decided to rule out the possibility as we did it with the GelDoc: starting the measure before adding the alkaline input.
 +
<span style="color:black; align:justify; font-size:11pt; font-family: Verdana">But this machine was different, so we designed a different experiment.
 +
 
 +
<span style="color:black; align:justify; font-size:11pt; font-family: Verdana">We found a hole (normaly closed) in the tap, just uppon the the place where the sample is. Using a piece of termaflex, we crossed it with the pippete, and put it in the hole, isolating the overture and preventing light got in and artefact our result. Another time, that was extremely acurate, and when we closed the door, the tip went exactly to the point where our sample was placed.
 +
<span style="color:black; align:justify; font-size:11pt; font-family: Verdana">This way, we started to measure before adding the input. Next, we pulled out hte 30 microliters of KOH in the little tank. We got depressed when we didn’t obtain results. But for this time, we were in September, and the luminometer was available for us.
 +
 
 +
<span style="color:black; align:justify; font-size:11pt; font-family: Verdana">In some days, our hard work was going to give us nice surprises.
<br><br><br><br>
<br><br><br><br>

Revision as of 09:31, 17 October 2009














Different experimental designs

To make measurements properly and determinate luminiscence levels, we needed a luminometer. But we couldn’t use one before September. So, if we didn’t want to waste our limited time, we decided to try with other machines.

This way, we had dt ideas, and we thought a GelDoc camera, an espectophotometer and a espectofluorimeter could be useful for us, at least to determinate the presence/absence of the luminiscence.


GELDOC


Igem2b.JPG


That was the first idea we got. It consisted to try to capture the luminiscence produced by our yeast with the camera that is normaly used to take gel photos. We thought that if we increased exposure time, we could acumulate enough luminiscence produced in time to see it, at the photo.

We put our yeast after the different steps of our protocol in a multi-hole plaque and add the alcaline input. Fastly, we used to close the GelDoc door, but we had doubts about the velocity of the response, and we couldn’t be inside the GelDoc to start the measure at the same time we make the input. In order to make sure our yeasts weren’t making light too fast, we designed a very simple but precise mechanism. We called it PippeteEnlarger.


PIPPETE ENLARGER
Igem1.JPG

The Pippete Enlarger is easy to assemble using a pippete, a thin tube and two pippete tips: one has to fit into the tub (so size tip deppends on size tub) and the another one has to be the proper tip to take the volume we want.

So, we will explain the mechanisme in the way we did it. We needed to make an input of 30 microliters of KOH without open the door. We had to enlarge the pippete to put the tip in the correct hole with the closed door and trigger the mechanism out of the GelDoc. We decided to full the tube with KOH, make pressure in one of the extrems of the tube, preventing by capilarity the liquid go away, and connect the pippete with an intermediary tip in the other extrem (the volume had to be already prefixed). The extrem we were pressing could be released at this point, so we could put the correct tip (in our chase, a yellow tip) to catch the desired volume. Before to be loaded with 30 microliters of KOH, we fixed the tip in the hole we wanted, we closed the door and carry on the pippete outside the GelDoc.

We were ready to start the measurement, making sure we increased enough the exposure time. Then, we pulled out the 30 microlitres actioning the pippete. It was surprisingly acurate!!! The volume was almost exactly, with 1 or 2 microliters of error. We dind’t got any result. We could rule out, then, the possibility that our yeasts produce light meanwhile we were putting them in the GelDoc, or we were closing the door...

GelDoc camera was not an efficient way to detect our luminiscence, so we thought perhaps a spectrophotometer was a more addient machine.




SPECTROPHOTOMETER


Igem19.JPG
Igem8.JPG



Altough an spectophotometer is a machine that measures how cloudy a sample is, by emitting a ray of light, we can “trick” the machine. Sticking a piece of silver paper in one of the faces of the little tank, we prevent the ray of light cross the sample. The idea is to measure only the light produced by the sample, not the “crossing light”.

We didn’t obtain any result, but that was probably because the spectrophotometer has been designed to detect a very located light ray, not a difused light produced by a bioluminiscent sample.




SPECTROFLUORIMETER


Igem9.JPG
MedidafluorimetroVII.jpg
MedidafluorimetroVI.jpg
Igem13.JPG
Igem17.JPG



Spectrofluorimeter measures the fluorescence of a sample. That’s because it has the same problem of the spectrophotometer. However, we found that it’s more sensible (it detects a great quantity of noise). So we thought it could be a more proper machine to our purposes.

We designed a similar experiment, covering the place where the ray of light is emited, in order to measure only the bioluminiscence produced by our yeasts.

We didn’t obtain any result. But we were worried about the speed of the reaction another time. Then, we decided to rule out the possibility as we did it with the GelDoc: starting the measure before adding the alkaline input. But this machine was different, so we designed a different experiment.

We found a hole (normaly closed) in the tap, just uppon the the place where the sample is. Using a piece of termaflex, we crossed it with the pippete, and put it in the hole, isolating the overture and preventing light got in and artefact our result. Another time, that was extremely acurate, and when we closed the door, the tip went exactly to the point where our sample was placed. This way, we started to measure before adding the input. Next, we pulled out hte 30 microliters of KOH in the little tank. We got depressed when we didn’t obtain results. But for this time, we were in September, and the luminometer was available for us.

In some days, our hard work was going to give us nice surprises.