Failure is inevitable due to the unstable nature of the lamp. DO NOT try to build your Ray directly on the lamp. Part One: You absolutely HAVE to build this part first. You don't have to use the parts I used, but that's what I built it out of therefore, that's what I'm going to talk about. The paper's other authors are postdoctoral researcher Derek Hernandez, former research associate Eric Ritschdorff and former postdoctoral researcher Jodi Connell.įunding was provided by the Welch Foundation.Here's where ya'll get creative. If scientists can better understand what topographic features prevent biofilms from forming, and how features that change over time may influence the process, they might be able to develop coatings for biomedical devices that block their formation and prevent hard-to-treat infections. Microbial biofilms - dense, sticky mats of bacteria that form on medical equipment and can lead to hard-to-treat infections - contribute to hospital-borne infections for up to 1 million people in the United States annually. "To get tissues to grow in a dish that will be effective once implanted, we need to first understand, then better mimic the environment in which they typically develop in our own bodies," said Shear.Īnother potential application would be in basic research on how the topography of a surface affects the formation of dangerous bacterial colonies called biofilms. For example, the approach may lead to materials and procedures that promote wound healing or nerve regrowth, or assist in growing and successfully implanting replacement tissues, such as skin or heart valves. The UT Austin researchers' immediate plans are to use the tool to investigate fundamental scientific questions surrounding cellular growth and migration, efforts that could enable various future medical applications. And it allows the formation of any 3D pattern on demand while viewing the growing cells through a microscope. Unlike other methods for altering the substrate under living cells, the UT Austin shrink ray doesn't heat or chemically alter the surface, damage living cells or cause cells to unstick from the surface. Researchers scan the laser through a series of points within the substrate to create any desired surface contour at any place in relation to targeted cells. When the laser strikes a point within the substrate, new chemical bonds are formed between the proteins, drawing them in more tightly, a change that also alters the surface shape as it's tugged on from below. On the microscopic level, it's made of proteins jumbled and intertwined like a pile of yarn. The substrate looks and behaves a bit like a block of Jell-O. The shrink ray is a near-infrared laser that can be focused onto tiny points inside the substrate. The researchers can also change the location and shapes of surface features as time goes by, for example turning a mountain into a molehill or even a sinkhole, mimicking the dynamic nature of the environment in which cells typically live, grow and move. It's like pinching a rug from below to form peaks and valleys on the surface. By controlling precisely which parts of the interior of the material shrink, the researchers can create specific 3D features on the surface including bumps, grooves and rings. The real power of shrinking the material used to grow cells - called the substrate - isn't so much in making it smaller as it is in selectively changing the shape and texture of the surface. The work was published online today in the Journal of the American Chemical Society. Shear, professor of chemistry and co-inventor of the new tool. "To understand, and in the future engineer, the way that cells respond to the physical properties of their environment, you want to have materials that are dynamically re-shapeable," said Jason B.
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