BME103:W930 Group3 l2
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Lab Write-Up 1
Lab Write-Up 2
Lab Write-Up 3
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LAB 2 WRITE-UP
Thermal Cycler Engineering
Our re-design is based upon the Open PCR system originally designed by Josh Perfetto and Tito Jankowski.
Materials List of Required Materials for PCR & DNA measurements
Contents of each DNA solution
Step 1) Download the Open PCR software.
Step 2) Place the PCR machine on a flat surface, plug it into an electrical outlet by using the power adapter provided in the kit, and then turn on the machine.
Step 3) Connect the Open PCR machine to your computer with the USB 2.0 cable.
Step 4) Initialize the OpenPCR Sofware and create a new program on OpenPCR by clicking on “Add a new experiment.” Substep A) Click on the “more options” button. Substep B) Select the plus symbol next to initial step, and set 95°C and 180 seconds for temperature and time. Substep C) In the box labeled Number of Cycles, input 30. Substep D) Set the denaturing temperature and time to 95°C and 30 seconds. (The two boxes in the first row) Substep E) Set the annealing temperature and time to 57°C and 30 seconds. (The two boxes in the second row) Substep F) Set the extending temperature and time to 72°C and 30 seconds. (The two boxes in the third row) Substep G) Add a final step. Set the temperature and time to 72°C and 180 seconds. Substep H) Set the final hold temperature to 4°C.
Step 5) Use one pipette to transfer 0.2μL of an extracted DNA sample into a test tube.
Step 6) Add the 10.0 μL of each of the forward and reverse primers to the test tube. Make sure to use different pipettes for each substance or CONTAMINATION WILL OCCUR.
Step 7) Use a different pipette to transfer 50.0 μL of GoTaq® Colorless Master Mix into the DNA/primer mixture.
Step 8) Dilute the contents of the test tube by filling its remainder with 47.8μL of deionized water. Make sure to use different pipettes to transfer the water or CONTAMINATION WILL OCCUR
Step 9) Repeat steps 5-8 until all six DNA samples and the positive and negative controls are prepared. Make sure to use different pipettes to transfer each substance or CONTAMINATION WILL OCCUR.
Step 10) Place the 8 test tubes including the positive and negative controls into the Open PCR machine, and close the lid (making sure the catch snaps shut) and tighten the screw so that it barely touches the tops of the tubes. CAUTION: If the heating lid does not touch the top of the tubes the experiment will not be carried out successfully. If the heating lid is too far low and is crushing the tubes THE TEST TUBES WILL SHATTER. Make sure to align the lid properly.
Step 11) Label each of the test tubes: numbering the experimental DNA samples from 1 to 6, P for the positive and N for the negative controls accordingly.
Step 12) Click on “Plug in Open PCR to start” to begin amplifying DNA samples.
Step 13) Be sure to observe the LED display screen on the lid of the Open PCR with the quantities that appear on the computer: if these quantities are close (<2.0°C/5 seconds), then continue running the program. If these quantities are not close (>2.0°C/5 seconds), then discontinue the program and inspect the machine for any faults. Begin Step 12 again.
Step 2) Label the transfer pipettes and Eppendorf tubes accordingly to prevent contamination.
Step 3) Measure 400mL of the Tris buffer into the 500.0mL graduated cylinder and pour it into an Eppendorf tube. Repeat 7 times for a total of 8 tubes.
Step 4) Extract each sample with the accordingly labeled pipette into the accordingly labeled Eppendorf tube that contains 400.0mL of Tris buffer. Be sure to transfer all of the sample into the tube.
Step 5) Set up the sample DNA calf thymus by transferring 100.0μL into a separately labeled Eppendorf tube containing 400.0mL of Tris buffer with a different pipette.
Step 6) Transfer 100.0μL of distilled water into the corresponding Eppendorf tube containing 400.0mL of Tris buffer.
Step 7) Place a hydrophobic glass slide onto the fluorimeter.
Step 8) Unbutton one side of the black box and lift the flap so that it is resting on top of the box. Flip the box upside down and position it so that the fluorimeter lies in the center of the box, obscuring most light while still leaving some space for you to take a picture.
Step 9) Flip a switch on the side of the fluorimeter (A blue light should come into view.)
Step 10) From one of the labeled Eppendorf tubes containing SYBR green dye, use the corresponding labeled pipette to place two drops adjacent to one another on a glass slide. (The two drops should combine to form a single larger drop.)
Step 11) Turn off the lights in the room, letting in as little light as possible into the box containing the fluorimeter.
Step 12) Adjust the following settings on the smartphone Substep A) Disable camera flash. Substep B) Set the ISO to 800 or higher. Substep C) Set the white balance to auto. Substep D) Maximize the exposure setting. Substep E) Maximize the saturation setting. Substep F) Minimize the contrast setting. Note that not all smartphone cameras will have these settings, just disable flash if not all these options are available.
Step 13) Take a picture of the fluorimeter and the SYBR green dye drop, recording the image number and DNA sample.
Step 14) Repeat steps 7,10, and 13 for the 9 remaining DNA solutions using a different glass slide and pipette for each sample.
Step 15) Download all 8 images onto the computer.
Step 16) Right click on the file name of the picture and open it with Image J. (Alternatively, open the Image J software, and select File > Open > examplepicturename01)
Step 17) In Image J, select Analyze > Set Measurements and choose area, integrated density, and mean grey value.
Step 18) Select Image > Color > Split Channels. Three images will appear; choose the one named green.
Step 19) Draw an oval around the drop. Select analyze and measure then record the measurements.
Step 20) Obtain the background reading by moving the oval over the dark area around the drop, and record the INTDEN and RAWINTDEN.
Step 21) Repeat steps 16-20 for each of the 8 pictures, making sure each sample lines up with the correct INTDEN measurements.
Step 22) Subtract the INTDEN background measurement from the INTDEN drop measurement.
Step 23) Set the DNA concentration in water to 0μg/mL and the DNA concentration in the calf thymus sample to 2μg/mL.
Step 24) Use a graphing program (Such as Excel) to generate a plot of INTDEN (with background subtracted) versus concentration. Select the option to display the linear equation.
Step 25) Use the linear equation and the INTDEN values of the samples to determine their concentrations.
Step 26) Once the DNA concentrations of the positive and negative are known, it can determined whether samples give a positive or negative result for cancer.
Research and Development
Background on Disease Markers