Difference between revisions of "Team:UMaryland/Hardware"
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<h1><b>CHIP: Cheap Homemade Innovative PCR</b></h1> | <h1><b>CHIP: Cheap Homemade Innovative PCR</b></h1> | ||
− | <p>Our first design for CHIP | + | <p> Our first design for CHIP was modeled after a more conventional PCR design. This first prototype used two peltier units, stacked on top of each other, to heat a customized aluminum block that sat on top of the two units and held the PCR tubes. In order for our system to have feedback, we embedded a temperature sensor in the aluminum block to detect the temperature of the wells that held the PCR tubes. The sensor then reported back to an Arduino UNO, which then regulated the energy flow to the peltier units, thereby heating and cooling the block and tubes while closing the control loop. However, after much testing, this design proved to be unoriginal, expensive, and inefficient. While the conventionality of the design itself did not pose an issue, we realized that the parts used to assemble it were not as well-known or easily accessible to the general public, which we felt would take away from the possible applications of this machine. In addition, although the price of this first prototype was relatively inexpensive in contrast to laboratory grade PCR machines, the price still ranged in the hundreds of dollars. Lastly and most importantly, the greatest issue with our design was the inefficiency of the hardware; we found that the peltier units were not able to cycle through the desired temperatures fast enough, e.g., the unit would take 5 to 10 minutes just to rise up to 95℃. After considering all of these factors, we began a redesign of CHIP to better suit the needs of the “Do-It-Yourself” market. </p> |
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<p> Our second thermocycler design, was mostly made out of a salvaged hair dryer. We came about this idea when we found that CHIP was not ramping up to the desired temperatures fast enough. Because of this problem, we looked to other options for heating the machine and disassembled a hair dryer to find out how the heating mechanism worked. To our pleasant surprise, we found that the hair dryer was able to reach very high temperatures—much higher than the desired maximum of 95 degrees Celsius for PCR—in a few seconds. We then made a decision to pause construction of CHIP in order to see how successful we could be at making a rapid PCR machine out of a hair dryer. We knew that working on the hair dryer would be much more dangerous and was risk since at the time we were unsure if the machine could be controlled to effectively cycle and amplify DNA. | <p> Our second thermocycler design, was mostly made out of a salvaged hair dryer. We came about this idea when we found that CHIP was not ramping up to the desired temperatures fast enough. Because of this problem, we looked to other options for heating the machine and disassembled a hair dryer to find out how the heating mechanism worked. To our pleasant surprise, we found that the hair dryer was able to reach very high temperatures—much higher than the desired maximum of 95 degrees Celsius for PCR—in a few seconds. We then made a decision to pause construction of CHIP in order to see how successful we could be at making a rapid PCR machine out of a hair dryer. We knew that working on the hair dryer would be much more dangerous and was risk since at the time we were unsure if the machine could be controlled to effectively cycle and amplify DNA. |
Revision as of 22:43, 13 September 2015