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Make your own microfluidic device with new kit from U-M
July 25, 2008ANN ARBOR, Mich.---A type of device called a "lab-on-a-chip" could bring a new generation of instant home tests for illnesses, food contaminants and toxic gases. But today these portable, efficient tools are often stuck in the lab themselves. Specifically, in the labs of researchers who know how to make them from scratch.
University of Michigan engineers are seeking to change that with a 16-piece lab-on-a-chip kit that brings microfluidic devices to the scientific masses. The kit cuts the costs involved and the time it takes to make a microfluidic device from days to minutes, says Mark Burns, a professor in the departments of Biomedical Engineering and Chemical Engineering who developed the device with graduate student Minsoung Rhee.
"In a lot of fields, there can be significant scientific advances made using microfluidic devices and I think that has been hindered because it does take some degree of skill and equipment to make these devices," Burns said. "This new system is almost like Lego blocks. You don't need any fabrication skills to put them together."
A lab-on-a-chip integrates multiple laboratory functions onto one chip just millimeters or centimeters in size. It is usually made of nano-scale pumps, chambers and channels etched into glass or metal. These microfluidic devices that operate with drops of liquid about the size of the period at the end of this sentence allow researchers to conduct quick, efficient experiments. They can be engineered to mimic the human body more closely than the Petri dish does. They're useful in growing and testing cells, among other applications.
Burns' system offers six-by-six millimeter blocks etched with different arrangements of grooves researchers can use to make a custom device by sticking them to a piece of glass. Block designs include inlets, straight channels, Ts, Ys, pitchforks, crosses, 90-degree curves, chambers, connectors (imprinted with a block M for Michigan), zigzags, cell culture beds and various valves. The blocks can be used more than once.
Most of the microfluidic devices that life scientists currently need require a simple channel network design that can be easily accomplished with this new system, Burns said. To demonstrate the viability of his system, he successfully grew E. coli cells in one of these modular devices.
Burns believes microfluidics will go the way of computers, smaller and more personal as technology advances.
"Thirty or 40 years ago, computing was done on large-scale systems. Now everyone has many computers, on their person, in their house-. It's my vision that in another few decades, you'll see this trend in microfluidics," Burns said. "You'll be analyzing chicken to see if it has salmonella. You'll be analyzing yourself to see if you have influenza or analyzing the air to see if it has noxious elements in it."
University of Michigan
A lab-on-a-chip integrates multiple laboratory functions onto one chip just millimeters or centimeters in size. It is usually made of nano-scale pumps, chambers and channels etched into glass or metal. These microfluidic devices that operate with drops of liquid about the size of the period at the end of this sentence allow researchers to conduct quick, efficient experiments. They can be engineered to mimic the human body more closely than the Petri dish does. They're useful in growing and testing cells, among other applications.
Burns' system offers six-by-six millimeter blocks etched with different arrangements of grooves researchers can use to make a custom device by sticking them to a piece of glass. Block designs include inlets, straight channels, Ts, Ys, pitchforks, crosses, 90-degree curves, chambers, connectors (imprinted with a block M for Michigan), zigzags, cell culture beds and various valves. The blocks can be used more than once.
Most of the microfluidic devices that life scientists currently need require a simple channel network design that can be easily accomplished with this new system, Burns said. To demonstrate the viability of his system, he successfully grew E. coli cells in one of these modular devices.
Burns believes microfluidics will go the way of computers, smaller and more personal as technology advances.
"Thirty or 40 years ago, computing was done on large-scale systems. Now everyone has many computers, on their person, in their house-. It's my vision that in another few decades, you'll see this trend in microfluidics," Burns said. "You'll be analyzing chicken to see if it has salmonella. You'll be analyzing yourself to see if you have influenza or analyzing the air to see if it has noxious elements in it."
University of Michigan
Microfluidic Device Current Events and Microfluidic Device News RSSNovel NIST connector uses magnets for leak-free microfluidic devices
Like other users of microfluidic systems, National Institute of Standards and Technology (NIST) researcher Javier Atencia was faced with an annoying engineering problem: how to simply, reliably and most of all, tightly, connect his tiny devices to the external pumps and reservoirs delivering liquids into the system.
Tiny injector to speed development of new, safer, cheaper drugs
It's no bigger than a stamp packet but it has the potential to allow rapid development of a new generation of drugs and genetic engineering organisms, and to better control in-vitro fertilization.
New nanochemistry technique encases single molecules in microdroplets
Inventing a useful new tool for creating chemical reactions between single molecules, scientists at the National Institute of Standards and Technology (NIST) have employed microfluidics-the manipulation of fluids at the microscopic scale-to make microdroplets that contain single molecules of interest.
NIST calculations may improve temperature measures for microfluidics
If you wanted to know if your child had a fever or be certain that the roast in the oven was thoroughly cooked, you would, of course, use a thermometer that you trusted to give accurate readings at any temperature within its range.
Music is the engine of new U-M lab-on-a-chip device
Music, rather than electromechanical valves, can drive experimental samples through a lab-on-a-chip in a new system developed at the University of Michigan. This development could significantly simplify the process of conducting experiments in microfluidic devices.
New lab-on-a-chip measures mechanics of bacteria colonies
Researchers at the University of Michigan have devised a microscale tool to help them understand the mechanical behavior of biofilms, slimy colonies of bacteria involved in most human infectious diseases.
Separating the good from the bad
Scientists at MIT and Brown University studying how marine bacteria move recently discovered that a sharp variation in water current segregates right-handed bacteria from their left-handed brethren, impelling the microbes in opposite directions.
MIT paves way to 'artificial nose'
MIT biological engineers have found a way to mass-produce smell receptors in the laboratory, an advance that paves the way for "artificial noses" to be created and used in a variety of settings.
Automated microfluidic device reduces time to screen small organisms for genetic studies
Genetic studies on small organisms such as worms and flies can now be done more quickly using a new microfluidic device developed by engineers at the Georgia Institute of Technology.
MIT particles pave way for new bedside diagnostics
MIT researchers have created an inexpensive method to screen for millions of different biomolecules (DNA, proteins, etc.) in a single sample-a technology that could make possible the development of low-cost clinical bedside diagnostics.
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Real-time monitoring of injection molding for microfluidic devices using ultrasound.: An article from: Polymer Engineering and Science by Y. Ono (Author), C.-K. Jen (Author), C.-C. Cheng (Author), M. Kobayashi (Author) This digital document is an article from Polymer Engineering and Science, published by Society of Plastics Engineers, Inc. on April 1, 2005. The length of the article is 4015 words. The page length shown above is based on a typical 300-word page. The article is delivered in HTML format and is available in your Amazon.com Digital Locker immediately after purchase. You can view it with any web browser. From the author: Real-time process monitoring of the fabrication process of microfluidic devices using a polymer injection molding machine was carried out using miniature ultrasonic probes. A thick piezoelectric lead-zirconate-titanate film as an ultrasonic transducer (UT) was fabricated onto one end of a 4-mm diameter and 12-mm long steel buffer rods using a sol gel spray technique.... | |
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PNAS November 9, 2004: Reprogrammable Microfluidic Devices (Proceedings of the National Academy of Sciences, v. 101, # 45) by National Academy of Sciences (Author) pp. 15825-16082 | |
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