AddThis Share CONTACT: Lia Unrau PHONE: (713)831-4793E-MAIL: [email protected] $2.5 MILLION INITIATIVE TO DEVELOP CHAMELEON-LIKENANOSHELLSDeveloped by Rice University engineers, metal nanoshells lend a chameleon-like effect to materials and devices, due to their ability to manipulate different types of light. A new $2.5 million initiative, funded by the Department of Defense, will allow a group of researchers to study and develop the technology.The Defense Department has chosen to fund a new five-year Multidisciplinary University Research Initiative (MURI) headed by Rice University, and including Oklahoma State University and the University of Houston, to study and develop the nanoshells, their optical and electromagnetic responses and properties, and commercial applications.A number of industries could potentially benefit from the development of this technology, including electronics, energy conservation, construction materials, biomedicine and cosmetics.“The wonderful thing about metal nanoshells is that we can tailor them to have specific optical properties at different wavelengths of light,” said Naomi Halas, professor of electrical and computer engineering at Rice and principal investigator of the project. “The particles themselves have these properties, an overwhelming advantage over other optical structures, which require multilayer films or nanoparticle arrays to give rise to similar effects. Nanoshells can be easily and directly incorporated into coatings and responsive devices.”Metal nanoshells are tiny particles, ranging from about 50-1,000 nanometers in diameter, with an insulating core, such as silica, coated by a thin shell of conductive metal–resembling nano-sized malted milk balls.Metal nanoshells can absorb light or scatter light, both in the visible and infrared regions of the spectrum. Varying the thicknesses of the shell and the core changes the way in which light is manipulated. Variations in thickness and particle composition extend the controlled electromagnetic wave response from visible light into the far-infrared and submillimeter-wave spectral regions.Nanoshells can be chemically attached to a wide variety of materials, including plastics, liquids, aerosols, epoxies, glasses and even fibers. New products could include energy-efficient smart windows, powerful solar collection and solar cells, coatings for cars, airplanes or buildings, biomedical sensors, and optical switches, steering light to different points in futuristic computer architecture.When incorporated into device structures, nanoshells are capable of responding to an applied electric current and producing a voltage-dependent optical response. For instance, by changing the voltage to a visual display panel built with nanoshell technology, the panel could change colors or transparency. Led by Halas, the research team is working to design and create the metal nanoshells, and to fully understand their properties and abilities. They will develop arrays, coatings, films and ultrathin films. The researchers are also studying different types and combinations of materials to improve upon current inorganic nanoshells and to develop completely organic nanoshells.Jennifer West, Rice assistant professor of bioengineering, is working to develop nanoshell-based all-optical biosensors and biotests. Because near-infrared light can pass harmlessly through the human body, an implantable sensor that uses light to monitor chemicals could be used to instantly monitor a range of different chemicals in the body. In addition, such nanoshell biotesting devices could be used to check proteins in whole blood, providing a big advantage over current methods, which are difficult and time consuming. Customized nanoshell monitors could allow doctors to look at small amounts of antigens or antibodies and determine rapidly the health of a patient.Peter Nordlander, Rice professor of physics, is a theoretical physicist and is studying the electrical transport properties of nanoshells and how they behave in a variety of environments. Alex Rimberg, Rice assistant professor of physics, is studying the way electrons flow around the nanoshells and how the internal structure affects its electrical transport properties. Dan Grischkowsky and Alan Cheville, professors in electrical engineering at the University of Oklahoma, are experts in making measurements in the terahertz region–the range between infrared light and microwaves–and at using the unique spectroscopy for probing chemical content of materials. They characterize the particles that are made and provide insight into how to design strongly absorbing particles in this region of the spectrum. As part of the synthetic effort, Randy Lee, a professor of organic chemistry at the University of Houston, is using synthetic techniques to grow organic nanoshells, and exploring new methods for the uniform growth of nanoshell structures.###Contact: Naomi Halas, professor of electrical and computer engineering at Rice University, (713) 737-5611, [email protected] more information about Rice’s nanoshell research see: http://www-ece.rice.edu/~halas/.
FacebookTwitterPrintEmailAddThis http://news.rice.edu/files/2016/04/0502_STENT-3-web-2m5ngj6.jpgRice University engineering students used a highly magnetic bead and a strong electromagnet in their method to remove ureteral stents from children. The method was developed in collaboration with Texas Children’s Hospital. (Credit: Jeff Fitlow/Rice University) http://news.rice.edu/files/2016/04/0502_STENT-1-web-2anz2zn.jpgRice University engineering students, from left, Margaret Watkins, John Chen, Allen Zhao, Eric Yin and Valerie Pinillos work at a 3-D printing station at Rice’s Oshman Engineering Design Kitchen on their method to remove ureteral stents from children. (Credit: Jeff Fitlow/Rice University) http://news.rice.edu/files/2016/04/0502_STENT-2-web-2hg9x9k.jpgRice University engineering students have created a method to remove ureteral stents from children that causes less pain and costs less. From left, Margaret Watkins, Valerie Pinillos, John Chen, Allen Zhao and Eric Yin. (Credit: Jeff Fitlow/Rice University) Share1Editor’s note: Links to a video and images for download appear at the end of this release.AT RICE:David [email protected] [email protected] TEXAS CHILDREN’S HOSPITAL:Lindsey [email protected] magnet gives pediatric patients a breakRice students’ idea for less-invasive ureteral stent removal may save time, pain and money HOUSTON – (April 28, 2016) – A simple device created by Rice University engineering students may shield young children from much of the pain of having a stent removed after a urinary tract procedure.Their invention, the Ureteral Stent Electromagnetic Removal Bead, is part of a stent inserted into the ureter, the duct that allows urine to pass from the kidney to the bladder. The stent keeps the passageway open after a pyeloplasty procedure to remove an obstruction.Removing the stent after four weeks of healing typically involves inserting an endoscope into the urethra and bladder to locate the stent and pull it, an invasive procedure for which children are placed under anesthesia.The students who call themselves Rice Outstenting were asked by Dr. Chester Koh at Texas Children’s Hospital to find a way to simplify this procedure, which is currently performed on more than 2,000 pediatric patients nationwide each year. They came up with the combination of a small, coated bead of highly magnetic neodymium and a powerful electromagnet. The bead can pass safely through the urethra as the magnet pulls it out of the body, followed by the stent.The advantages are clear: There’s less pain and it costs two-thirds less than the standard procedure because it doesn’t require anesthesia and can be completed in minutes rather than hours.“The stent is implanted after surgery in this area because if you don’t put something inside to keep the channel open, the ureter will try to close in on itself,” said team member Allen Zhao. While the procedure is now done in a minimally invasive manner with robotic surgery, “in the past it was much more invasive, when they would just open up the child completely,” he said.Zhao and teammates John Chen, Valeria Pinillos and Margaret Watkins are mechanical engineering majors; teammate Eric Yin is a bioengineering major.Their device won two significant awards this month: a top $5,000 prize at Rice University’s annual Engineering Design Showcase and the grand prize for student design at the annual Design of Medical Devices Conference in Minneapolis.The students, who were advised by Rice bioengineering lecturers Eric Richardson and Matthew Elliott, took on the project at the request of Koh, a surgeon in the Division of Pediatric Urology at Texas Children’s and Baylor College of Medicine and a member of several groups that focus on pediatric devices. “A lot of devices are designed for adults, and Dr. Koh is one of the movers trying to develop more devices that are designed for children,” Yin said.He said Koh challenged them to look at the procedure with a fresh eye. The students briefly considered designing a stent that would dissolve over time, but decided the magnetic attachment would be far simpler and less prone to complications.The stent itself is identical to those used currently. It’s a flexible plastic tube with curls at each end that sit in the kidney and bladder and help keep it in place. In adults, a string from the bladder end is usually run outside the body through the urethra. After four weeks, a doctor pulls it free.But in children, “most times, the string is cut off because the doctor doesn’t want anything hanging out of the child that might lead to an infection or accidental removal,” Yin said. “We’re leaving the string in but clipping it to the appropriate length, for the size of the bladder, at the surgeon’s discretion, and tying our bead to the end of it.”The second part of the system is the custom-built electromagnet with a plastic enclosure the team designed and 3-D printed at Rice’s Oshman Engineering Design Kitchen. “It has 19 layers, 125 turns of enameled copper wire,” Yin said. “Once it’s turned on, we bring it up close (to the patient) and draw the bead out through the urethra.”“With a couple of tweaks to the magnet power, we could access the adult market as well,” Pinillos said.The project will move forward as a Rice-Texas Children’s collaboration led by Koh. “They’ll continue to make modifications and continue the project on its medical device development pathway,” Watkins said.“This is an important example of where academic partnerships are needed to advance pediatric medical device projects, since the pediatric medical device pipeline is currently limited,” Koh said. “I applaud the Rice team for showing its dedication and passion to the kids under our care at Texas Children’s Hospital.”Without a hint of irony — given that carbon buckyballs were a Nobel Prize-winning discovery at Rice — Yin mentioned the material in the bead is identical to that used in the now-banned desk toy also known as Buckyballs. Those were small, powerful magnets that, if ingested in multiples, could cause severe internal injuries.Fortunately for the Rice team’s purposes, one small magnet is enough to make a big difference.-30-See the team’s home page at http://oedk.rice.edu/Sys/PublicProfile/29784578.Follow Rice News and Media Relations via Twitter @RiceUNewsVideo: http://news.rice.edu/files/2016/04/0502_STENT-4-web-1ug2o1h.jpgRice University student John Chen pulls a magnet attached to a stent from a test device. Chen and his Rice engineering teammates developed a method to remove ureteral stents from children that would eliminate the need for anesthesia. (Credit: Jeff Fitlow/Rice University) https://youtu.be/2jfG4H5iLYA Related Materials:Texas Children’s Hospital: www.texaschildrens.orgOshman Engineering Design Kitchen: http://oedk.rice.eduGeorge R. Brown School of Engineering: http://engr.rice.eduImages for download: http://news.rice.edu/files/2016/04/0502_STENT-5-web-1rw14oq.jpgEngineering student John Chen reloads a test rig to demonstrate a method developed by Rice University students that uses a strong, tiny magnetic bead to help remove a ureteral stent from a child. (Credit: Jeff Fitlow/Rice University)Located on a 300-acre forested campus in Houston, Rice University is consistently ranked among the nation’s top 20 universities by U.S. News & World Report. Rice has highly respected schools of Architecture, Business, Continuing Studies, Engineering, Humanities, Music, Natural Sciences and Social Sciences and is home to the Baker Institute for Public Policy. With 3,910 undergraduates and 2,809 graduate students, Rice’s undergraduate student-to-faculty ratio is 6-to-1. Its residential college system builds close-knit communities and lifelong friendships, just one reason why Rice is ranked No. 1 for best quality of life and for lots of race/class interaction by the Princeton Review. Rice is also rated as a best value among private universities by Kiplinger’s Personal Finance. To read “What they’re saying about Rice,” go to http://tinyurl.com/RiceUniversityoverview.