BME103:T930 Group 7
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Lab Write-Up 1
Lab Write-Up 2
Lab Write-Up 3
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LAB 1 WRITE-UP
Initial Machine Testing
The Original Design
Description The OpenPCR Machine creates many copies of a small strand of DNA. In order to duplicate these DNA strands the PCR Machine must use many different temperatures during denaturing, annealing and extension. Denaturing is where the two strands of DNA separate. Annealing is where the DNA primer binds to the separate strands. Extension is when Taq Polymerase copies the DNA strands.
Experimenting With the Connections
When we unplugged the white wire that connects the OpenPCR circuit board to the main heating block, the temperature reading on the LCD screen changed.
The date the machine was used was on Thursday October 24th, 2012. We had machine number 13. The team's experience with the device was as follows:
Great Software (it was very easy to use)
Took too long to complete its task
Needed a computer
Hard open the lid
Not Aesthetically Pleasing
Flammable (Wood + Extreme Heat=A Bad Situation Waiting to Happen.)
Polymerase Chain Reaction
1. Heat Denaturation: The heating of DNA to 95 degrees celsius allowed for the separation of the two strands of DNA. The nucleotides lose their base pair partners as the DNA is separated into a positive and a negative strand.
2. Annealing: The DNA now undergoes cooling of 57 degrees celsius to assist the process of annealing. Two primers are necessary for DNA replication as it's the primers that identify the specific targeted strand of DNA. Binding to the complementary sequence, the primers begin to produce the replication that's desired.
3. Extension: To finish off the first cycle of PCR, the temperature is once again raised to 72 degrees celsius. The enzyme Taq DNA polymerase then creates the new DNA strands by making each single strand now a double strand using the complementary sequences produced in annealing. The conclusion of these three steps is the production of two new DNA strands that are the replicate of the original strand.
PRC Master Mix Components:
- Bacterially derived Taq DNA polymerase
- Magnesium Chloride
- Reaction buffers
There were eight samples that were ran PCR on during this experiment. This included a positive control cancer DNA template and a negative control without a DNA template. Patient 1, a 57 year old male with an ID of 58515, had three samples tested on and patient 2, a 59 year old female with an ID of 19033, also had three samples tested on.
The Flourimeter is a device that detects flourescence, when a molecue produces a light after being excited byanother light with a shorther wavelength. The process begins
The process at which an image is turned into an Image J involves several steps. The first step is to set the settings of a camera's phone and then take a picture. The picture should then be emailed or downloaded onto a computer, and it then should be saved to the computer and opened in the Image J software. There are several parameters needed to be adjusted to produce the wanted picture so the measurement needs to be set to integrate the density and the linear gray value. The bubble's green spot is subsequently isolated, integrated density is measured and the background is then deleted to have the isolated desired picture.
Research and Development
Specific Cancer Marker Detection - The Underlying Technology
PCR, or Polymerase Chain Reaction, is a process used to make copies of the same DNA sequences. This process includes a template DNA strand, which serves as the DNA that will be replicated. Primers are also needed to artificially synthesize the DNA strand. Taq polymerase then matches base-pairs, thus replicating the DNA. Magnesium Chloride is also needed because it binds to Taq, allowing it to function. Finally, dNTP’s are the nucleotides, A, T, C, and G, that are used to make the new DNA.
The process includes the following:
A SNP, or single nucleotide polymorphism, is a point mutation, meaning one nucleotide in a sequence is changed. This change is stable over many generations, and is present in at least 1% of the population. This makes the SNP ideal for a gene marker. The following sequence, rs17879961, was used as a primer for the cancerous gene