Difference between revisions of "Team:LambertGA/Hardware"
| Line 361: | Line 361: | ||
<center> <h1 id="MainTitle"><b> Hardware </b></h1> <img src="https://static.igem.org/mediawiki/2016/2/26/T--LambertGA--purpleline.jpg" style="width:18%; margin:auto;"> </center> <br> | <center> <h1 id="MainTitle"><b> Hardware </b></h1> <img src="https://static.igem.org/mediawiki/2016/2/26/T--LambertGA--purpleline.jpg" style="width:18%; margin:auto;"> </center> <br> | ||
| − | + | <div class="center"> | |
| − | + | <img class="img-responsive" style="width:600px" src="https://static.igem.org/mediawiki/2016/7/79/T--LambertGA--SSRApathway.png"> | |
| − | + | </div> | |
| − | + | <center><h3 style="color: #D49AE6;"Function</h3> | |
| − | </p> | + | <p style="width: 100%; margin: auto; font-size: 16px;">The ChromQ Light Chamber is a 3D-printed imaging measurement system used to quantify results of nutrient deficiency. For our current project, it is also used to quickly and inexpensively measure relative protein degradation through quantification of the color in chromoprotein expression. |
| + | </p></center> | ||
| + | <br> | ||
| + | <div class="center"> | ||
| + | <img class="img-responsive" style="width:600px" src="https://static.igem.org/mediawiki/2016/7/79/T--LambertGA--SSRApathway.png"> | ||
| + | </div> | ||
| + | <br> | ||
| + | <center><h3 style="color: #D49AE6;">Development</h3></center> | ||
| + | <p style="width: 100%; margin: auto; font-size: 16px;">One of the most critical variables in imaging today is the consistency of light. Different wavelengths, intensity, power, wattage, and even angling of lights can affect the result of camera imaging. To this end, the ChromQ Light Chamber is designed to control for the variable of light. The box’s dimensions are 12” x 12” x 12” and feature four mini LED-bulbs at 0.6 Watts each with a power source of 3 Volts. Each LED light is positioned 7” down from the top, 45° below the horizontal, one on each side of the chamber, excluding the top and the bottom. The combination of the four lights creates a spotlight that will focus on the specimen being imaged. The top features a circular 2”-diameter cut-out that provides an opening for camera lens to image. The bottom of the chamber is left open in order to properly accommodate and shift any reasonably-sized and –shaped specimen that will be illuminated and imaged with the chamber. The dimensions have been optimized for ideal imaging distance and lighting amount. </p> | ||
| + | <br> | ||
| + | <center><h3 style="color: #D49AE6;">On-Site Application</h3></center> | ||
| + | <p style="width: 100%; margin: auto; font-size: 16px;">Current methods of testing for nutrient deficiency are incredibly time-consuming and require a plethora of steps. Specimens gathered on site must be sent overseas for testing and the results are returned weeks and even months later. For areas that urgently need immediate care, this lengthy result turn-around time could cost dozens of lives. To solve this pressing issue, the 3D-printed ChromQ Light Chamber is designed to be easily assembled and then taken apart, much like building with Lego pieces. This aspect was created for ease of transportation, as well as ability to be used in the field as part of on-site testing and data collection. Researchers and healthcare providers can simply use the chamber to test for nutrient deficiency at the location of examination and obtain immediate results without having to send specimens to labs overseas. The increase in efficiency revolutionizes the future of point-of-care treatment. </p> | ||
| + | <br> | ||
| + | <center><h3 style="color: #D49AE6;">Inexpensive</h3></center> | ||
| + | <p style="width: 100%; margin: auto; font-size: 16px;">As a high school lab, one of the many problems we face in research is the lack of funding and monetary support. Sophisticated equipment is incredibly expensive, and so it is very hard to afford the necessary tools and measurement systems for our research. The ChromQ Light Chamber is designed to conquer the issue of the cost of a fluorimeter – instead of visualizing with fluorescence, the project uses chromoproteins, which can then be imaged with the chamber we built, and results can be obtained that way. This technology can be used by other teams and facilities for their research, and the full plan of the design is available below so that any team can build it themselves. </p> | ||
| + | <br> | ||
| + | <center><h3 style="color: #D49AE6;">Digital Plan</h3></center> | ||
| + | <p style="width: 100%; margin: auto; font-size: 16px;"> David Park's Pictures here </p> | ||
<div class="button_click" onClick=" parent.location= 'https://2016.igem.org/Special:Upload '"> | <div class="button_click" onClick=" parent.location= 'https://2016.igem.org/Special:Upload '"> | ||
Revision as of 15:48, 16 October 2016
Hardware
The ChromQ Light Chamber is a 3D-printed imaging measurement system used to quantify results of nutrient deficiency. For our current project, it is also used to quickly and inexpensively measure relative protein degradation through quantification of the color in chromoprotein expression.
Development
One of the most critical variables in imaging today is the consistency of light. Different wavelengths, intensity, power, wattage, and even angling of lights can affect the result of camera imaging. To this end, the ChromQ Light Chamber is designed to control for the variable of light. The box’s dimensions are 12” x 12” x 12” and feature four mini LED-bulbs at 0.6 Watts each with a power source of 3 Volts. Each LED light is positioned 7” down from the top, 45° below the horizontal, one on each side of the chamber, excluding the top and the bottom. The combination of the four lights creates a spotlight that will focus on the specimen being imaged. The top features a circular 2”-diameter cut-out that provides an opening for camera lens to image. The bottom of the chamber is left open in order to properly accommodate and shift any reasonably-sized and –shaped specimen that will be illuminated and imaged with the chamber. The dimensions have been optimized for ideal imaging distance and lighting amount.
On-Site Application
Current methods of testing for nutrient deficiency are incredibly time-consuming and require a plethora of steps. Specimens gathered on site must be sent overseas for testing and the results are returned weeks and even months later. For areas that urgently need immediate care, this lengthy result turn-around time could cost dozens of lives. To solve this pressing issue, the 3D-printed ChromQ Light Chamber is designed to be easily assembled and then taken apart, much like building with Lego pieces. This aspect was created for ease of transportation, as well as ability to be used in the field as part of on-site testing and data collection. Researchers and healthcare providers can simply use the chamber to test for nutrient deficiency at the location of examination and obtain immediate results without having to send specimens to labs overseas. The increase in efficiency revolutionizes the future of point-of-care treatment.
Inexpensive
As a high school lab, one of the many problems we face in research is the lack of funding and monetary support. Sophisticated equipment is incredibly expensive, and so it is very hard to afford the necessary tools and measurement systems for our research. The ChromQ Light Chamber is designed to conquer the issue of the cost of a fluorimeter – instead of visualizing with fluorescence, the project uses chromoproteins, which can then be imaged with the chamber we built, and results can be obtained that way. This technology can be used by other teams and facilities for their research, and the full plan of the design is available below so that any team can build it themselves.
Digital Plan
David Park's Pictures here
