Difference between revisions of "Team:IONIS Paris/Project/Microfluidics"
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<i class="fa fa-angle-right"style="color:#b22222"></i><b>Microfluidic chip in silicon</b><br> | <i class="fa fa-angle-right"style="color:#b22222"></i><b>Microfluidic chip in silicon</b><br> | ||
Advantages of silicon are its superior thermal conductivity, surface stability and solvent compatibility. However no applications in optical detection can be done due to its optical opacity.<br> | Advantages of silicon are its superior thermal conductivity, surface stability and solvent compatibility. However no applications in optical detection can be done due to its optical opacity.<br> | ||
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<i class="fa fa-angle-right"style="color:#b22222"></i><b>Microfluidic chip in glass</b><br> | <i class="fa fa-angle-right"style="color:#b22222"></i><b>Microfluidic chip in glass</b><br> | ||
Glass shares with silicon the same advantages mentioned above. Its well-defined surface chemistries, superior optical transparency and excellent high-pressure resistance make it a material of choice for many applications. Glass is also biocompatible, chemically inert, and hydrophilic and allows efficient coatings. The main hurdle with this material remains its rather high cost, even though prices have been significantly reduced.<br> | Glass shares with silicon the same advantages mentioned above. Its well-defined surface chemistries, superior optical transparency and excellent high-pressure resistance make it a material of choice for many applications. Glass is also biocompatible, chemically inert, and hydrophilic and allows efficient coatings. The main hurdle with this material remains its rather high cost, even though prices have been significantly reduced.<br> | ||
+ | </p> | ||
+ | <p align="justify"> | ||
<i class="fa fa-angle-right"style="color:#b22222"></i><b>Microfluidic chip in polymers</b><br> | <i class="fa fa-angle-right"style="color:#b22222"></i><b>Microfluidic chip in polymers</b><br> | ||
Polymers offer an attractive alternative to glass and silicon as they are cheaper, robust and require faster fabrication processes. Many polymers can be used to build chips : Polystyrene (PS), Polycarbonate (PC), Polyvinyl chloride (PVC), Cyclic Olefin Copolymer (COC), Polymethyl methacrylate (PMMA) and Polydimethylsiloxane (PDMS). | Polymers offer an attractive alternative to glass and silicon as they are cheaper, robust and require faster fabrication processes. Many polymers can be used to build chips : Polystyrene (PS), Polycarbonate (PC), Polyvinyl chloride (PVC), Cyclic Olefin Copolymer (COC), Polymethyl methacrylate (PMMA) and Polydimethylsiloxane (PDMS). |
Revision as of 13:05, 15 September 2015
What is Microfluidics?
Manipulating and controlling fluids
Microfluidics is the science and technology of manipulating and controlling fluids, usually in the range of micro liters (10-6) to pico liters (10-12), in networks of channels with lowest dimensions from ten to hundred micrometers. This emerging discipline takes its origin in the early 1990s and has known a dramatic growth since then, partly due to the increasing popularity of microscale analytical chemistry techniques and the development of microelectronic technologies.
A very attractive technology
Microfluidics is a very attractive technology for both academic researchers and industrials since it considerably:
Decreases sample and reagent consumptions
Shortens time of experiments and doing so
Reduces the overall costs of applications
Thanks to the low volume required, microfluidics represents a promising alternative to conventional laboratory techniques as it allows achieving complete laboratory protocols on a single chip of few square centimeters.
Microfluidics chip
A specific design
Microfluidic chips are the devices used in microfluidics in which a micro-channels network has been modelled or patterned. Thanks to a various number of inlet and outlet ports, these microfluidic instruments allow your fluids to pass through different channels of different diameter, usually ranging from 5 to 500 µm1. The micro-channels network must be specifically designed for your application and the analyses you want to carry out.
Several applications
Microfluidic devices such as chips have many advantages as they can decrease your sample and reagent consumption and increase automation, thus minimizing your analysis time. Such devices allow applications in many areas such as medicine, biology, chemistry and physics. Three types of materials are commonly used to create microfluidic chips: silicon, glass, and polymers. Each material has its specific chemical and physical characteristics. The choice of the material depends on the needs and conditions of your applications (type of solvant, samples, etc.), the design of the chip you want to obtain and your budget.
Several materials
Microfluidic chip in silicon
Advantages of silicon are its superior thermal conductivity, surface stability and solvent compatibility. However no applications in optical detection can be done due to its optical opacity.
Microfluidic chip in glass
Glass shares with silicon the same advantages mentioned above. Its well-defined surface chemistries, superior optical transparency and excellent high-pressure resistance make it a material of choice for many applications. Glass is also biocompatible, chemically inert, and hydrophilic and allows efficient coatings. The main hurdle with this material remains its rather high cost, even though prices have been significantly reduced.
Microfluidic chip in polymers
Polymers offer an attractive alternative to glass and silicon as they are cheaper, robust and require faster fabrication processes. Many polymers can be used to build chips : Polystyrene (PS), Polycarbonate (PC), Polyvinyl chloride (PVC), Cyclic Olefin Copolymer (COC), Polymethyl methacrylate (PMMA) and Polydimethylsiloxane (PDMS).
Our Bio-Console
Introduction
Our first goal in this game is to interact with the real world throw a computer game. The game is based on the movement of a bubble in a microfluidic system, then we add a virtual part to the microscope video and integrate our virtual game.
The bubble detection
First of all, we add to detect the bubble in the system, so we use the Hough circle detection algorithm to find it and return it position. We decided to use a microfluidic chip of 1,2x1,6 cm of size with 0,3 mm sized channels. The detection have to find the bubble of 0,3 mm diameter in a channel used as a circuit. To detect the bubble, the contrast between the bubble and the environment have to be sufficient to locate the bubble in the microscope image. So, we decided to use a transparent and blue environment to respect this contrast.
The game part
Once we have detected the bubble in the image, we have to integrate it into a game, the location of the bubble gives us a position in the image and a size, and the virtual part can be added to interact with the bubble. All the virtual part is construct like a game engine, we have the Game User Interface engine (GUI engine), the Graphical engine, the Physical engine, etc. The bubble has also its own virtual part to interact with the virtual world. As we said, the player has to move the bubble into the chip from a beginning point to the end of the circuit, and this circuit have a lot of virtual objects like lasers, checkpoints, etc. The player have to interact with the bubble to dodge the lasers, and if he touch one off them, the game detect a collision between the bubble detected with our Hough circle detection and the virtual laser. That’s how we interact between the real world and our virtual world.