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<li data-part="default">To get short information about our robot's single parts, click on the part of interest.</li> | <li data-part="default">To get short information about our robot's single parts, click on the part of interest.</li> | ||
<li data-part="x-y-axis"> | <li data-part="x-y-axis"> | ||
− | To realize the movement of the head in the x-y-plane the head is mounted onto a 3D-printed connection which is fitted between two crossing 6 mm aluminum linear rods. To ensure a smooth sliding of the connection on the linear rods two <i>LM6UU</i> linear bearings were applied. Also, the crossing 6 mm aluminum linear rods are clipped on four <i>UM2 Ultimaker 2 Injection Sliding Blocks</i> which are themselves sliding on 8 mm steel rods. Two <i>F688ZZ</i> flanged ball bearings per 8 mm steel rod are plugged into <i>SK16</i> rod supports ensure that they are able to rotate with less friction. Furthermore, <i>GT2</i> timing belts transfer the stepper motor's rotation into a linear movement of the head. These timing belts connect the stepper motors with the 8 mm steel rods with the usage of <i>GT2</i> pulleys. Timing belts that are fixed in the sliding blocks range from one linear rod on one side of the robot to a parallel one on the opposing side. Therefore, an amount of two timing belts per axis and one timing belt per motor are | + | To realize the movement of the head in the x-y-plane, the head is mounted onto a 3D-printed connection element which is fitted between two crossing 6 mm aluminum linear rods. To ensure a smooth sliding of the connection on the linear rods, two <i>LM6UU</i> linear bearings were applied. Also, the crossing 6 mm aluminum linear rods are clipped on four <i>UM2 Ultimaker 2 Injection Sliding Blocks</i> which are themselves sliding on 8 mm steel rods. Two <i>F688ZZ</i> flanged ball bearings per 8 mm steel rod are plugged into <i>SK16</i> rod supports ensure that they are able to rotate with less friction. Furthermore, <i>GT2</i> timing belts transfer the stepper motor's rotation into a linear movement of the head. These timing belts connect the stepper motors with the 8 mm steel rods with the usage of <i>GT2</i> pulleys. Timing belts that are fixed in the sliding blocks range from one linear rod on one side of the robot to a parallel one on the opposing side. Therefore, an amount of two timing belts per axis and one timing belt per motor are necessary for a proper movement in the x‑y‑plane. |
</li> | </li> | ||
+ | |||
<li data-part="z-axis"> | <li data-part="z-axis"> | ||
− | For the motion in z-direction a threaded rod is coupled to a stepper motor with a <i>5Ὕto‑8 | + | For the motion in z-direction, a threaded rod is coupled to a stepper motor with a <i>5Ὕto‑8 |
− | mm</i> shaft coupling and vertically mounted with two <i>KP08</i> pillow blocks. The rotation of the threaded rod is then transmitted into a vertical movement of the sample stage via a ball screw. For a greater stability and a more balanced force distribution two additional 12 mm aluminum rods help to guide the vertical movement of the sample stage. Besides, one <i>LM12LUU</i> linear bearing per vertical axis is used for nearly frictionless motion and an even more balanced force effect on the vertical axis. The mounting for the latter is attached on the sample stage and particularly manufactured, | + | mm</i> shaft coupling and vertically mounted with two <i>KP08</i> pillow blocks. The rotation of the threaded rod is then transmitted into a vertical movement of the sample stage via a ball screw. For a greater stability and a more balanced force distribution, two additional 12 mm aluminum rods help to guide the vertical movement of the sample stage. Besides, one <i>LM12LUU</i> linear bearing per vertical axis is used for nearly frictionless motion and an even more balanced force effect on the vertical axis. The mounting for the latter is attached on the sample stage and particularly manufactured, again for a balanced force distribution. The sample stage itself consists of an aluminum framework with an infrared‑transparent Plexiglas. To minimize the weight of the sample plate, while keeping its stability, the thickness of the table's components was chosen to be 3 mm. |
</li> | </li> | ||
− | + | <li data-part="optics"> | |
− | The main part of our optics is the combination of our lightbox, LEDs and <i>Pi NoIR v2</i> camera. With these parts we detect | + | The main part of our optics is the combination of our lightbox, LEDs and a <i>Pi NoIR v2</i> camera. With these parts we detect flourescent light, after stimulated emission. |
− | The localization works with the lightbox via builtὝin infrared | + | The localization works with the lightbox via builtὝin infrared LEDs whose light spreads inside a diffusion plate, generating an evenly distributed light source. Emerging shadows can be detected with the camera. The latter is attached to the head of the robot that additionally consists of optical components such as four high power LEDs, various filters, a lens mounting and a tip that is connected to the syringe pump. As already mentioned, the camera is in charge of detecting different sample locations and fluorescent light of the mVenus protein. While the high power LEDs ensure the excitation of the protein; the filters, that are composed of a longpass-filter and sunglasses, eliminate reflected light such that the camera only detects relevant signals. The lens mounting works as an autofocus that is able to control the sharpness of the camera. This works by applying different voltages to coils that move the lens inside a modified webcam. |
</li> | </li> | ||
+ | |||
<li data-part="syringepump"> | <li data-part="syringepump"> | ||
− | The syringe pump is the device of the robot that feeds the bacteria with non-natural amino acid if it is | + | The syringe pump is the device of the robot that feeds the bacteria with non-natural amino acid if it is necessary. Its setup is a stepper motor that squeezes the non-natural amino acid out of the syringe and a 3D-printed framework that holds the syringe. It also includes a threaded rod for transmission between the stepper motor and the syringe. To keep the whole setup at a fixed position and still pipet on the right sample, the end of the syringe is connected with the head by a flexible tube. |
</li> | </li> | ||
+ | |||
<li data-part="chassis"> | <li data-part="chassis"> | ||
The framework for the robot is built in a form of a simple cuboid constructed with 30 mm x 30 mm aluminum profiles. These profiles are connected with each other via M8 screws and drilled into ISO metric screw threads. Two extra horizontal aluminum profiles are added on the backside which hold the axes and the threaded rod needed for the vertical motion. Moreover, a thin aluminum frame is attached at the lower part of the 30 mm framework to mount the lightbox onto it. | The framework for the robot is built in a form of a simple cuboid constructed with 30 mm x 30 mm aluminum profiles. These profiles are connected with each other via M8 screws and drilled into ISO metric screw threads. Two extra horizontal aluminum profiles are added on the backside which hold the axes and the threaded rod needed for the vertical motion. Moreover, a thin aluminum frame is attached at the lower part of the 30 mm framework to mount the lightbox onto it. | ||
</li> | </li> | ||
<li data-part="electronics"> | <li data-part="electronics"> | ||
− | The electrical parts used in this robot can be separated into those that directly manage the threedimensional movements and those that are in charge of the optical localization and detection. The threedimensional movements are controlled by an <i>Arduino Mega 2560</i> microcontroller connected to a <i>RepRap Arduino Mega Pololu Shield 1.4</i> (short: <i>RAMPS 1.4</i>) which provides an intuitive connection of drivers and other electronical devices without using wires. The drivers used in this project are called <i>Pololu - DRV8825 Stepper Motor Driver Carrier</i> and allow the Arduino to let the stepper motors make a 1/32 step and therefore increases the spatial resolution. Additional parts involved in | + | The electrical parts used in this robot can be separated into those that directly manage the threedimensional movements and those that are in charge of the optical localization and detection. The threedimensional movements are controlled by an <i>Arduino Mega 2560</i> microcontroller connected to a <i>RepRap Arduino Mega Pololu Shield 1.4</i> (short: <i>RAMPS 1.4</i>) which provides an intuitive connection of drivers and other electronical devices without using wires. The drivers used in this project are called <i>Pololu - DRV8825 Stepper Motor Driver Carrier</i> and allow the Arduino to let the stepper motors make a 1/32 step and therefore increases the spatial resolution. Additional parts involved in threedimensional movement are the so called endstops that assure that the head does not crash into the boundaries of the robot. The list of parts that control the optical localization and detection are comprised of a single‑board computer <i>Raspberry Pi 3</i> and controls several other electro‑optical components. All necessary power is delivered by a standard<!--, baptized in coffee,--> <i>ATX</i> power supply. </li> |
+ | |||
</ul> | </ul> | ||
<div class="verlinked" id="func"><h5>FUNCTIONALITY</h5></div> | <div class="verlinked" id="func"><h5>FUNCTIONALITY</h5></div> | ||
− | The functionality of the pipetting robot comprises the three‑dimensional agility of a 3D-printer and the possibility to pipet a specific amount of non‑natural amino acid using a syringe pump. Also it has intelligent visual object recognition so that it is able to distinguish between samples that require more non‑natural amino acid from samples that still contain a sufficient amount. | + | The functionality of the pipetting robot comprises of the three‑dimensional agility of a 3D-printer and the possibility to pipet a specific amount of non‑natural amino acid using a syringe pump. Also it has intelligent visual object recognition so that it is able to distinguish between samples that require more non‑natural amino acid from samples that still contain a sufficient amount. |
With that said it is capable to autonomously keep alive the modified <i>E. coli</i> bacteria, given that it is activated and connected to a reliable power supply.<br> | With that said it is capable to autonomously keep alive the modified <i>E. coli</i> bacteria, given that it is activated and connected to a reliable power supply.<br> | ||
− | To | + | To fulfil the task of keeping the bacteria alive it loops through a specially designed procedure. Initially, the robot scans the working area for samples by illuminating the downside of the sample stage using infrared LEDs and monitoring the shadows of the placed reservoirs with a camera. If the contrast is sufficiently high it is able to detect the edges of the mentioned reservoirs, fit a circle onto it and compute the distance between the reservoir and the camera itself. Furthermore it is possible to put an entire rack of reservoirs under observation due to its ability to locate every individual reservoir.<br> |
− | Shortly after the detection the distance information is sent to the 3D control program and the head of the robot moves in direction of the first reservoir. To check whether the bacteria needs more non‑natural amino acid the robot uses the fluorescence of the protein mVenus that | + | Shortly after the detection, the distance information is sent to the 3D control program and the head of the robot moves in direction of the first reservoir. To check whether the bacteria needs more non‑natural amino acid the robot uses the fluorescence of the protein mVenus that is expressed by the bacteria. Therefore the robot excites the protein via high power LEDs and detects the emitted light. To exclude reflected light from the LEDs that would interfere with the measurement a longpass filter cuts off the spectrum below the emission peak of the protein. In dependence of the fluorescence signal, the robot decides whether it is necessary to pipet non‑natural amino acid onto the sample. If that is the case the robot moves the samples in z-range just so that the syringe reaches the sample and is able to securely add the non‑natural amino acid.<br> |
− | Eventually the robot recommences the procedure described above, except for the scanning of the individual positions of the samples, which are saved temporarily until all samples are checked. As long as the robot is activated, connected to a power supply and the syringe pump does not run out on non‑natural amino acid, the robot will loop through this whole process and keep the bacteria alive without | + | Eventually the robot recommences the procedure described above, except for the scanning of the individual positions of the samples, which are saved temporarily until all samples are checked. As long as the robot is activated, connected to a power supply and the syringe pump does not run out on non‑natural amino acid, the robot will loop through this whole process and keep the bacteria alive without the need of a human. |
Nevertheless it is possible to check what the robot is doing via a livestream of the camera visible on a graphical user interface, since there is no other opportunity to look inside the robot itself while it is working. | Nevertheless it is possible to check what the robot is doing via a livestream of the camera visible on a graphical user interface, since there is no other opportunity to look inside the robot itself while it is working. | ||
<br> | <br> | ||
+ | |||
<div class="verlinked" id="achie"><h5>ACHIEVEMENTS</h5></div> | <div class="verlinked" id="achie"><h5>ACHIEVEMENTS</h5></div> |
Revision as of 20:07, 19 October 2016
ROBOTICS
ABSTRACT
Our main task was to develop a device that measures mVenus fluorescence and adds liquids to sample containers.
Therefore, our team decided to build a fully automatized pipetting robot that is able to locate a set of samples, detect potential light emission and pipet a specific amount of non-natural amino acid solution into the fluorescent sample.
The foundation for the robot is a 3D-printer, due to the easy handling of movements in three dimensions. By controlling these movements with an optical system, the autonomy of the robot is further increased.
INTRODUCTION
Development of 3D Printers & Possibilities
In the 1980s, Chuck Hull invented the first standardized 3D printer, based on a procedure which is known as stereolithography (SLA, [1]). Moving from SLA to full deposit modeling (FDM) techniques, the 3D printing idea became alive in the do‑it‑yourself community. Ever since that time, simple 3D printers are accessible for little money and due to the open source idea of projects like REPRAP [2] affordable for many. In last years project, iGEM TU Darmstadt has already built a fully working SLA printer, capable of being fed with biologically manufactured plastics [3].
This year, the robotics team decided to rebuild a clone of the Ultimaker 2 FDM printer [4] and exchange the extruder with a camera and a pipet to create a pipetting robot. Using several open‑source parts and software, it is the idea to establish an easy-to-handle robot to assist the daily biologist's work.
iGEM TU DARMSTADT is a young and dynamic team of interdisciplinary and motivated researchers. Our advantage is, that we can bring together synthetic biology and classic engineering sciences, for which TU Darmstadt is famous. We have the possibility, thanks to iGEM, to experiment on our own ideas and to reach for the stars. Being interested in a variety of scientific topics, we wanted to mix up different talents to create a unique project.
References:
- http://edition.cnn.com/2014/02/13/tech/innovation/the-night-i-invented-3d-printing-chuck-hall
- https://2015.igem.org/Team:TU_Darmstadt/Project/Tech
- http://reprap.org/wiki/About
- http://www.thingiverse.com/thing:811271, jasonatepaint
GOALS
The main task is to develop a machine which is capable to monitor our organisms and their health condition (encoded by fluorescence) in order to keep them alive. Therefore the machine has to measure the light emission of the organisms and needs to be able to drop liquids into sample containers. This has to be independent of the exact position of the container, which requires an automatic tracking system.
The idea is that one places a container somewhere under the robot's working area and clicks a run button of a program. The robot starts its routine by tracking the new container and measuring the light emission of the organisms. Based on this measurement, the robot decides whether to feed the organisms with non‑natural amino acid solution or not. After a period of time it repeats this routine until the stop button of the program is clicked.
These are only the minimum requirements for our project's needs. We decided to go one step further and designed our robot in such a way, that it serves as a multi‑purpose platform which is adaptable and easy to modify. The open‑source character invites other scientists to add new features or improve the robot and its capabilities.
For example our dispensing system can be upgraded to be able to prepare 96-well plates with samples and monitor routines by using the optical system.
Additionally, our measuring head can be changed back to a printer head which allows to 3D print with just a few changes.
There is a vast room of possibilities, just using the concept of the accurate positioning of a sample in the 3D space.
Due to the fact that we try to stick to widely used open-source software and standard commercial parts, our machine can be easily combined with the most DIY products, making it reusable, flexible and cheap.
In the special case of the TU Darmstadt and the next generations of iGEM competitors, we had the idea to develop our technical equipment from year to year and, if possible, combine them. Our SLA printer from last year’s competition was upgraded and is nearly ready to use again, giving us the possibility to manufacture parts for prototyping in our lab. Also this year’s project will serve as starting point for the next year’s technical development team. New ideas and possibilities have been already discussed and we are looking forward to the next year’s competition.
SETUP OVERVIEW
FUNCTIONALITY
To fulfil the task of keeping the bacteria alive it loops through a specially designed procedure. Initially, the robot scans the working area for samples by illuminating the downside of the sample stage using infrared LEDs and monitoring the shadows of the placed reservoirs with a camera. If the contrast is sufficiently high it is able to detect the edges of the mentioned reservoirs, fit a circle onto it and compute the distance between the reservoir and the camera itself. Furthermore it is possible to put an entire rack of reservoirs under observation due to its ability to locate every individual reservoir.
Shortly after the detection, the distance information is sent to the 3D control program and the head of the robot moves in direction of the first reservoir. To check whether the bacteria needs more non‑natural amino acid the robot uses the fluorescence of the protein mVenus that is expressed by the bacteria. Therefore the robot excites the protein via high power LEDs and detects the emitted light. To exclude reflected light from the LEDs that would interfere with the measurement a longpass filter cuts off the spectrum below the emission peak of the protein. In dependence of the fluorescence signal, the robot decides whether it is necessary to pipet non‑natural amino acid onto the sample. If that is the case the robot moves the samples in z-range just so that the syringe reaches the sample and is able to securely add the non‑natural amino acid.
Eventually the robot recommences the procedure described above, except for the scanning of the individual positions of the samples, which are saved temporarily until all samples are checked. As long as the robot is activated, connected to a power supply and the syringe pump does not run out on non‑natural amino acid, the robot will loop through this whole process and keep the bacteria alive without the need of a human. Nevertheless it is possible to check what the robot is doing via a livestream of the camera visible on a graphical user interface, since there is no other opportunity to look inside the robot itself while it is working.
ACHIEVEMENTS
- Successfully redesign a 3D printer chassis to meet our requirements
- Construct a unique lightbox with integrated IR LEDs for positioning purposes
- Design a measuring probe with a camera device with an integrated optical filter system and LEDs
- Implementing an automatic object tracking system including a vector based feedback system for positioning
- Construct a syringe pump system to add liquids down to microliter accuracy
- Connecting a Raspberry Pi with an Arduino microcontroller by establishing a serial connection between the two devices, allowing a variety of different tasks
- Data of all CADs designed by the TU Darmstadt technical department
- A complete construction tutorial including a BOM (Bill of Materials incl. prices)
RESULTS
Circle Detection
Multi-Object Detection
Rectangle Detection
Optics
Operating Range of Wavelengths
Fluorescence Measurement and Filtering
Optical Hardware - Camera Head
Optical Hardware - Lightbox
References
[1]: https://picamera.readthedocs.io/en/release-1.12/
[2]: https://www.plexiglas-shop.com/pdfs/en/212-15-PLEXIGLAS-LED-edge-lighting-en.pdf
Cooling
Software
Marlin
There, you will also find a link where you can download the original, unmodified version of the marlin firmware.
OpenCV
OpenCV is a cross-platform image processing library and free for use under the open-source BSD license. Its development has been initiated by Intel in the nineties to demonstrate the capability of CPUs in executing complex image processing tasks. OpenCV covers the most basic morphological image operations up to advanced machine learning algorithms. It is written in C++, which is also its primary interface. By now most of the available features have been wrapped for other programming languages like Python, which we are going to use. Especially what we are looking for in OpenCV are its feature extraction algorithms, like the Hough transformation (1) (show details), contour and edge detection (2) (show details), and image moment (3) (show details) extraction. Also we make our lives easier by utilizing its implemented and optimized morphological operators and image filters (4) (show details), like the median filter and the sobel operator.
To enhance the long-term reliability of detection we separate the detection procedure into two steps: Since racks are predominantly used to hold the sample vessels, we firstly extract and detect the rectangular shaped racks with contour and thresholding techniques. Several image shape descriptors are used to track possible positional changes. The user is then allowed to manually assign regional attributes (e.g. radii, heights) for each rack. The assignment of local radii helps the circle detection in the second step. Not only does it inhibit false detections, but also allows for a proper multithreaded apportionment of work.
PyQt
Qt is a software tool to develop a GUI (Graphical User Interface). It is available under a commercial and an open-source license. The software is a cross-platform application framework, which means it runs on the most computer systems like Unix or Windows. The underlying programming language is C++ and Qt can use already existing programming languages like Javascript, making it a powerful tool.
The main idea of Qt is to use a system of signals and slots to have an easy framework to connect displayed elements with underlying functions. Also, the reusability of already existing code is enhanced. Every graphical element, for example a button, emits its own signal when it is pressed or used. The signal then can be used to trigger an action, like closing a window. If the signal is not connected to a function nothing will happen, however the signal will be emitted with no consequences. Now it is possible to connect the emitted signal with a desired action, called slot, and the program gets its specific behavior.
Qt is widely used by companies like the European Space Agency (ESA), Samsung, DreamWorks, Volvo and many more.
To be able to combine the possibilities of Qt with the simplicity of the Python programming language, PyQt was developed. PyQt is a binding for Python capable of translating Qt methods within the Python syntax.
To be able to get a direct preview of the constructed GUI, Qt Designer is a helpful tool. Basically it enables an intuitive way to build a graphical user interface without a need to explicitly coding it. To later work with the code itself, PyQt uses a method called pyuic(number), which is executed through the terminal. The number in the brackets stands for the version.
After converting the code one can open the GUI as a regular python script and work with it as usual.
References:
https://riverbankcomputing.com/software/pyqt/intro
https://www.qt.io/
https://en.wikipedia.org/wiki/Qt_(software)
FURTHER DEVELOPMENTS
Due to a tight time schedule from the start to the end of iGEM it was not possible for us to realize all ideas and planned developments in respect of improvement of the robot itself.
For a working process with more kinds of bacteria cultures it is absolutely indispensable to develop a system that is able to avoid all sorts of contamination between the different bacteria. Therefore it would be an option to have an extra reservoir filled with ethanol in which the tip of the syringe can be sterilized between the checks of different samples.
Another modification that would be useful for working with individual bacteria cultures is making the power LED's changeable. This is necessary if the the wavelength of the LEDs does not overlap with the absorption spectrum of the fluorescent proteins or overlaps with a part of the spectrum that has a very low absorption efficiency.
Moreover, apart from the latter developments it may be useful to improve the syringe pump system. Instead of using a syringe pump it would be useful to use a system with a reservoir of liquids and a pump that works continously like a turbine, for example see http://www.ardulink.org/automatic-lipid-dispensing/.
Another useful modification of the robot would be to rebuild its foundation, namely an Ultimaker 3D-printer setup. Essential alterations would be to replace the sample stage with a heatbed and to replace the current head with a printhead hotend. Since the current head can be clipped it would not be too much of a challenge. Furthermore, a change of the syringe extruder is necessary, if the printer should work with plastics.
An alternative approach is a kind of paste 3D-printer. In this case it wouldn't even be needed to change the head and the syringe, because of the already viscous properties of the paste.
BUILDING INSTRUCTIONS
Construction Video
Bill Of Materials