BME103 s2013:T900 Group6: Difference between revisions
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The DNA/Primer Mix is made of 50 micro liters of DNA of patients 1 and 2, and primer. There are 2 vials containing negative and positive control. The negative control does not have cancer DNA, and the positive control has cancer in it. | The DNA/Primer Mix is made of 50 micro liters of DNA of patients 1 and 2, and primer. There are 2 vials containing negative and positive control. The negative control does not have cancer DNA, and the positive control has cancer in it. | ||
==Research and Development== | |||
===Bonus=== | |||
Once again, in our experiment, we used the PCR machine, also known as the polymerase chain reaction machine. It is used to amplify strands of DNA and generate many copies of a specific sequence. As previously stated, it can be used to research different diseases, especially cancer. | |||
[[Image:BME103_Group_6.jpg |200px|Another view at what a PCR machine is]] [[Image:BME_103_Group6.jpg |200px|Inside of the PCR Machine]] | |||
When it comes to replicating DNA, the PCR machine requires, of course, a DNA template strand and a primer to start off the replication process. Also needed in the process is DNA Polymerase which adds base pairs to the new strand of replicated DNA (the daughter strand, in other words). In the case of a cancer DNA template, when it comes time to replicate, a primer sets down base pairs for DNA Polymerase to have a basis to start, and leaves until DNA Polymerase is finished adding new base pairs. For this process, a “Taq” Polymerase is named for the protein that assembles these base pairs on the new DNA template strand. In addition, for Taq Polymerase to function, magnesium chloride must be present. This all can happen only if a cancer gene coded in the sequences of the DNA strand is present. If there is no cancer gene, cancer DNA replication will not happen. | |||
[[Image:DNA_Amplification_by_PCR.jpg |260px|]] | |||
As we can see in this illustration, this is how the PCR Machine functions. In order to create copies of the DNA strands it's given, the DNA is put through a series of temperature changes. Over a period of time, this allows the DNA strand being copied to unravel, grow new strands, or lock in new strands on the template. | |||
[[Image:Comparison_of_amplifiers.jpg |400px|]] | |||
In this comparison, the polymerase on the left allows the viewer to see the DNA template brighter and more accurately. Depending on what amplification you use, results can either come out being better to see and compare or difficult to see and make accurate observations on exactly what is the result. | |||
===Sources=== | |||
(http://www.ornl.gov/sci/techresources/Human_Genome/publicat/primer/pcr.html). | |||
(http://dangerousprototypes.com/wp-content/media/2011/07/OpenPCR_solo-W490.html). | |||
(http://media.treehugger.com/assets/images/2011/10/open-pcr-inside.html). | |||
(http://www.scilproj.org/DNA%20amplification%20by%20PCR.html). | |||
(http://www.invitrogen.com/etc/medialib/en/images/ics_organized/applications/nucleic_acid_amplification/data_chart.html). | |||
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Revision as of 02:09, 26 March 2013
BME 103 Fall 2012 | Home People Lab Write-Up 1 Lab Write-Up 2 Lab Write-Up 3 Course Logistics For Instructors Photos Wiki Editing Help | ||||||||||||||||||||||
OUR TEAMLAB 1 WRITE-UPInitial Machine TestingThe Original Design
When we unplugged the LCD screen from the OpenPCR circuit board, the machine's LED failed to work properly. When we unplugged the white wire that connects the OpenPCR circuit board to the main heating block, the machine began to show a change of the temperature on the LCD screen.
The date the PCR machine was open to conduct an analysis was on March 5th, 2013. We had machine number 6 that day. What we came to see, in terms of pros and cons, contained the following: Pros: - Lightweight - Quiet - Ease of Use Cons:
- Took a while to complete the full cycle
- The lid is not easy to remove. Requires some work
- Requires a computer
- Small and somewhat heavy
- Made of Wood (fire hazard)
Thermal Cycler Program DNA Sample Set-up
DNA Sample Set-up Procedure 1. Obtain DNA samples, PCR, DNA/Primer vials 2. Open All The Tops 3. Use pipette to move DNA into vials containing PCR mix PCR Reaction Mix
The PCR mix is made up of 50 Microliters of PCR. DNA/ primer mix
The DNA/Primer Mix is made of 50 micro liters of DNA of patients 1 and 2, and primer. There are 2 vials containing negative and positive control. The negative control does not have cancer DNA, and the positive control has cancer in it.
Thermal Cycler Program DNA Sample Set-up
DNA Sample Set-up Procedure 1. Obtain DNA samples, PCR, DNA/Primer vials 2. Open All The Tops 3. Use pipette to move DNA into vials containing PCR mix PCR Reaction Mix
The PCR mix is made up of 50 Microliters of PCR. DNA/ primer mix
The DNA/Primer Mix is made of 50 micro liters of DNA of patients 1 and 2, and primer. There are 2 vials containing negative and positive control. The negative control does not have cancer DNA, and the positive control has cancer in it. Research and DevelopmentBonusOnce again, in our experiment, we used the PCR machine, also known as the polymerase chain reaction machine. It is used to amplify strands of DNA and generate many copies of a specific sequence. As previously stated, it can be used to research different diseases, especially cancer.
Sources(http://www.ornl.gov/sci/techresources/Human_Genome/publicat/primer/pcr.html). (http://dangerousprototypes.com/wp-content/media/2011/07/OpenPCR_solo-W490.html). (http://media.treehugger.com/assets/images/2011/10/open-pcr-inside.html). (http://www.scilproj.org/DNA%20amplification%20by%20PCR.html).
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