Team:TU Darmstadt/strategy
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To illustrate the data in a clear and usable way, the construction of an Android smartphone app is the completion of our project. The application should identify the capsule and apply an online test protocol in order to visualize and compare the data with former tests and share it with customers, leaving the consumer with the opportunity to check different producers on clean manufacturing and production. Consequently, food can be checked on mycotoxins in a cheap and reliable way. | To illustrate the data in a clear and usable way, the construction of an Android smartphone app is the completion of our project. The application should identify the capsule and apply an online test protocol in order to visualize and compare the data with former tests and share it with customers, leaving the consumer with the opportunity to check different producers on clean manufacturing and production. Consequently, food can be checked on mycotoxins in a cheap and reliable way. | ||
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Revision as of 23:43, 4 October 2013
The Strategy
To easily detect biological toxins we developed a handy device, everybody is able to operate reliably. By altering the sensorium of E. coli with the help of synthetic biology, the bacteria would release a defined beacon when sensing mycotoxins. This treatment relies on a change of the so called Tar receptors exterior binding site, to specifically react on mycotoxins [1]. By also changing the interior impulse, an explicit beacon can be measured using the interaction of two fluorescent colorants (FRET). Samples can be given into a self-constructed capsule containing the modified bacteria. The light-signal inside the capsule is measured using a low-cost and open-source constructed FRET analysing system, as well developed by our team. To illustrate the data in a clear and usable way, the construction of an Android smartphone app is the completion of our project. The application should identify the capsule and apply an online test protocol in order to visualize and compare the data with former tests and share it with customers, leaving the consumer with the opportunity to check different producers on clean manufacturing and production. Consequently, food can be checked on mycotoxins in a cheap and reliable way.
FRET
FRET (Förster or Flourescence energy transfer) is a technique to investigate protein interaction in living cells. We adapted this system to use it as a detection element for our selfmade FRET analyser. It works via two chromophores coupled to the prospective proteins. If we use light to excite the cells containing chromophore-coupled proteins, we can get two types of information: in our case the colour orange stands for a negative and red for a positive toxin result. This little trick analyses probes within seconds, hence detection works in real time. An important and often used FRET pair is LSSmOrange and mKate. Their excitation and emission spectra have a compatible overlap.
In detail: The resulting data gives information about the chromophores connected to the proteins and the distance and angle to each other. The principle relies on a radiation free transition: An excited donor transfers energy to the acceptor by dipole dipole interactions. Here, the given distance between the two molecules needs to be between 0,5 nm and 10 nm for an efficient FRET.
Using the dipole dipole interactions changes in physical structure, bindings and separations can be investigated contemporarily.
Handheld and App
We developed a device that is able to detect the specific light emitted after FRET took place. This device - built into a hendheld and coupled to a smartphone - converts the light into an electric signal and sends it to the smartphone. Additionally, we designed an Android App that can process the data and display it as well.
Our handheld is developed to enable communication between the handheld and a smartphone via Bluetooth a USB. Thereby it allows a simple and wireless operation for the users.
The designed App runs on Android phones which are based on linux operation system and is used by about 80 million users worldwide. The App can be downloaded for free (hier).
BLABLA
An extremely simple optical-sensing technique has been developed appropriate for our application. The sensing system employs two LEDs whereby each one can be used as a light emitter or light detector. The main reason for us to use the pulse based signal conversion technique is that it leads to better spectral sensitivity; increased and adjustable resolution; reduction in cost, dimensions, power consumption and, additionally, it avoids the need of expensive and precise operation amplifiers, ADCs and other external components[2].
References