BME103 s2013:T900 Group6 L2

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(Procedure)
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==Procedure==
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'''Materials'''<br>
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Glass Slides
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Camera Phone
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Dark Box
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Template
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SYBR Green 200mL
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Flourimeter
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DNA Sample Solution
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Micropipette and Tips
'''Smart Phone Camera Settings'''<br>
'''Smart Phone Camera Settings'''<br>

Revision as of 01:35, 2 April 2013

BME 103 Spring 2013 Home
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Lab Write-Up 1
Lab Write-Up 2
Lab Write-Up 3
Course Logistics For Instructors
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Image:BME494_Asu_logo.png


Contents

OUR TEAM

Name: Dale Franco L. Caagbay - Protocol
Name: Dale Franco L. Caagbay - Protocol
Name: Cyril Wassef - Background Information
Name: Cyril Wassef - Background Information
Name: Emmanuel Casildo - Background Information
Name: Emmanuel Casildo - Background Information
Name: student
Name: student
Name: student
Name: student
Name: student
Name: student


LAB 2 WRITE-UP

Background Information

SYBR Green Dye
SBYR green dye is a nucleic acid-sensitive gel dye that is useful in pinpointing double stranded DNA in samples within open PCR machines and other utilities such as the single-drop fluorimeter.


Single-Drop Fluorimeter
The single-drop fluorimeter is a fluorescence-based DNA detection device that aids in bringing to light PCR-Amplified DNA. The DNA sample is placed on a slide upon the machine and shined with a blue LED light. When the light hits the sample, the sample's DNA emits a dim green glow. From there, under a controlled, light-limited environment, a camera (specifically a camera on a phone) can be used to capture the green light.


How the Fluorescence Technique Works
The overall procedure of the fluorescence technique consisted of an extremely hydrophobic (water-hating) surface. This was used in order to not allow any water to be absorbed during the experiment. The slide atop was coated with an adhesive cover in order to keep the molecules in place during analysis, and keep them a certain distance from the slide at the same time. This being so, it alloweed for the blue LED light to be focused in the drop; causing an increase in intensity which helped create the fluorescent environment. In addition, The SBYR Green dye that was added with the solvent helped form a complex with DNA that preferred to stick to the surface than anywhere else on the Fluorimeter. If a water-soluble dye was used instead, the outcome of the experiment would differ because instead of the green glow, a colorful beam of light would have shown through.

  • Note that the group used SYBR Green due to the fact it seemed to be the most eco-friendly."



Materials
Glass Slides Camera Phone Dark Box Template SYBR Green 200mL Flourimeter DNA Sample Solution Micropipette and Tips

Smart Phone Camera Settings

  • Iphone 5
    • Flash: None
    • ISO setting: NA
    • White Balance: NA
    • Exposure: NA
    • Saturation: NA
    • Contrast: NA

Calibration

Photo of Fluorimeter


  • Distance between the smart phone cradle and drop = 8cm


Solutions Used for Calibration

Calf Thymus DNA solution concentration (microg/mL) Volume of the 2X DNA solution (uL) Volume of the SYBR GREEN I Dye Solution (uL) Final DNA concentration in PicoGreen Assay (ng/mL)
0 80 80 blank
.25 80 80 .125
.5 80 80 .25
1 80 80 .5
2 80 80 1
5 80 80 2.5


Placing Samples onto the Fluorimeter

  • Obtain waterproof slides, a Micropipette, and vials of various DNA samples along with a 200 ml vial of SYBR Green solution.
  • Insert slide into fluorimeter
  • Turn on blue fluorescent light and make sure that the beam is shined between the first two rows of the dotted slide.
  • Take 80 micro-liters of SYBR Green solution into micropipette
  • Release all of the 80 micro-liters of SYBR Green fluid onto the slide, then ensure that the beam of light hits the droplet.
  • With a new plastic micropipette, take another 80 micro-liters of DNA Sample and extract into the SYBR Green droplet. Make sure the drops form a ball and doesn't spread around making individual droplets all over the slide.
  • In order to see the glow of the SYBR Green with the DNA sample solution, a dark environment must be in place to see the dim green light. Place a box casing over the machine and take multiple pictures of the glowing solution.
  • After the photo shoot is complete, and pictures are saved onto the phone, calibrate the micropipette to 160 micro-liters and extract all of the sample on the slide.
  • Repeat the same steps for the additional DNA Samples.
  • Clean Up Workstation


Data Analysis

Representative Images of Samples

[Show an IMAGE where you drew a circle around the droplet with the freehand tool for a sample with no DNA]

[Show an IMAGE where you drew a circle around the droplet with the freehand tool for a sample with DNA (positive signal)]


Image J Values for All Samples [See worksheet page 5]

row 1 cell 1 row 1 cell 2 row 1 cell 3 row 1 cell 4 row 1 cell 5
row 2 cell 1 row 2 cell 2 row 2 cell 3 row 2 cell 4 row 2 cell 5
row 3 cell 1 row 3 cell 2 row 3 cell 3 row 3 cell 4 row 2 cell 5

[Add more rows as needed]


Fitting a Straight Line
[Place an IMAGE of your Excel plot with a line of best fit here. See worksheet page 8]




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