Part | Description | Manufacturer / Part name | Price[USD] |
---|---|---|---|
A fairly strong LED | In our case a 3W green 520 nm LED | Cree XP-E on star circuit board | 10 |
A cooling element | Used to prevent the LED from overheating | Fischer Elektronik ICK S | 9 |
A constant-current-source | To ensure static LED light (no flickering) | Roschwege GmbH KSQ-3W | 15 |
An AC/DC rectifier | Used to grant direct current to the LED | Goobay 67951 | 16 |
Two optical lenses | Here we used two identical 60 mm lenses | Thorlabs AC254-060-A | 160 |
A camera | We used a SLR camera | Canon 550D | 200-400 |
A microfluidics chamber | Our chamber consists of an iRIf slide attached to a PDMS flow cell | Made ourselves | |
Magnets | Used to attach the flow cell to the device | 5 mm Neodymium magnets | 3 |
A small syringe | We used a regular 10 ml syringe | BRAUN INJEKT 10 ml | < 1 |
A microfluidic tube | Used to connect the flow chamber with the syringe | - | < 1 |
A case for the device | 5 mm thick acrylic glass cutouts to hold the parts in place | Ordered at http://formulor.com | 100 |
Team:Freiburg/Results/Own Device
Results of Our Self-Built Device
Here you will see what we were able to measure with the very first prototype of our self-built device. To see the results of our final device, please refer to the essential results page. A detailed explanation on how to build your own low-priced iRIf device can be found on the bottom of this page.
Our First Prototype is Able to Detect Antigen-Antibody Binding
For testing our device we immobilized rabbit-derived proteins on an iRIf slide in distinct spots (figure 1 D). The proteins we used were polyclonal antibodies against HCV (Hepatitis C Virus) raised in rabbit. We aimed to detect these proteins with anti-rabbit antibodies (antibodies which specifically bind the constant region of antibodies raised in rabbit). We used them as interaction partners in a series of experiments to reproduce a measurement previously performed in the professional device. The binding layer on the iRIf slide consisted of an APTES/PDITC surface. The spots on the slide were produced by pipetting 3 µl [500 µg/ml] rabbit anti-HCV protein and 3 µl [1 mg/ml] BSA in an alternating pattern onto the slide. After incubation o/n the slide was blocked for 30 min with BSA [10 mg/ml].
The camera used for the measurement was a Canon 50D. The camera was set to automatically acquire pictures at an interval of five seconds. Before the solution was flushed over the chip, the exposure time was set to obtain apprx. 80% saturation (Fig. 1 A & B). The antibody solution was pipetted into the flow chamber without the use of a microfluidic pump. Instead, a syringe was loaded with 500 µl [5 µg/ml] anti-rabbit antibody solution (diluted in PBS) and slowly released into the binding chamber of the device by gently dispensing it from the syringe. As can be seen in figure 1 C, the quotient picture clearly shows binding of anti-rabbit antibodies to the rabbit protein spots. The BSA control spots show none or negligible unspecific binding.
How To Build Your Own Device
In this section we demonstrate how to build your own iRIf device from scratch, using affordable, low-tech material. The design is focused on creating a device that is both low-priced and portable, demonstrating the potential for the DiaCHIP to be used even in areas where high-tech laboratories are inaccessible.
General Principle
As seen in figure 3, the basic setup is fairly simple. Light from an LED enters a lens to obtain a parallel light beam. To achieve this, the distance from the LED to the lens should be close to one focal length. Next, the light hits the iRIf slide where it is reflected (in the same angle as it hits the slide) and enters a second lens that projects an image of the slide on the CCD chip of the camera.
Construction Guidance
A major problem that we encountered when building the device from scratch was to ensure that all components are at the proper distance and angle to each other. Correct alignment is crucial as a slight misplacement of a component may lead to lower signal strength, blurred images or, in the worst case, no signal at all. This can be difficult since our device does not rely on straight angles. We overcame this challenge by designing a case for the device that ensures the right placement of the components inside the device. We calculated all distances between the LED, lenses, camera and slide using the laws of geometrical optics and drew an vector graphic blueprint for our device. Next, we constructed a digital 3D model of the casing based on the vector blueprint to avoid an expensive and time-consuming trial and error process (Figure 4).
The casing is designed to keep all the necessary parts (lenses, LED) in place safely during a measurement, but allows them to be removed to facilitate transportation of the device (i.e. to the Giant Jamboree). Figure 5 illustrates the parts that hold the lenses and LED in place.
After setup of the 3D model of our device , we created a vector graphic of all required parts in a 2D plane. Using this vector graphic, we ordered the parts at Formulor, a service which uses laser cutting to cut out parts from acrylic glass and other materials. The cutting laser is guided by the paths defined in the vector graphic template. The template is shown in figure 6, and may be downloaded and used by everyone to build their own device. To allow easy mounting of the casing, we also provide an easy to understand manual. One advantage of acrylic glass is that the parts can be glued together easily using a few drops of acetone. The vector graphic also contains a template for the parts which are necessary to attach the glass and PDMS slide to the device. They should be cut from 1 mm thick acrylic glass. The microfluidic tubes can be glued to these parts (figure 7) and attached to the device with the magnets (figure 8)
The most difficult part to build is the PDMS flow chamber since it requires a microstructured silicon wafer, which can only be produced in a cleanroom environment. The template used for our PDMS flow cell is shown in figure 9. If your facility has an engineering department, there is a high chance that a cleanroom is present. Ask the personnel in charge if they can help you out with producing your flow cell. If you already use another type of microfluidic flow chamber, our device should still be compatible with it, though some adaptions might be necessary. If you have no possibility of creating a flow chamber, you might want to consider building a very simplified DIY flow chambers from two glass slides, separated by thin tape. Note that our device was not primarily build to support such a chamber and would need appropriate modifications.
Download section
Legal notice
The iRIf detection method is patented. Biametrics and associated persons own patents concerning the detection principle. These patents are:
- Method for examining physical, chemical and biochemical interactions (DE102004051098.9, DE102005015030.6, EP05797776.1)
- Study of molecular interactions on and / or in thin layers (DE102007038797.2)
- Method and apparatus for determining reflection coefficients to filter arrangement with thin layers (DE102009019711.7)
- Again Detectable support for optical measuring methods (DE102009019476.2)