Nanomaterial Safety Screening Could Become Faster, Cheaper with New Laboratory Test
August 15, 2016 | UCLAEstimated reading time: 2 minutes
UCLA researchers have designed a laboratory test that uses microchip technology to predict how potentially hazardous nanomaterials could be.
According to UCLA professor Huan Meng, certain engineered nanomaterials, such as non-purified carbon nanotubes that are used to strengthen commercial products, could have the potential to injure the lungs if inhaled during the manufacturing process. The new test he helped develop could be used to analyze the extent of the potential hazard.
The same test could also be used to identify biological biomarkers that can help scientists and doctors detect cancer and infectious diseases. Currently, scientists identify those biomarkers using other tests; one of the most common is called enzyme-linked immunosorbent assay, or ELISA. But the new platform, which is called semiconductor electronic label-free assay, or SELFA, costs less and is faster and more accurate, according to research published in the journal Scientific Reports.
The study was led by Meng, a UCLA assistant adjunct professor of medicine, and Chi On Chui, a UCLA associate professor of electrical engineering and bioengineering.
ELISA has been used by scientists for decades to analyze biological samples — for example, to detect whether epithelial cells in the lungs that have been exposed to nanomaterials are inflamed. But ELISA must be performed in a laboratory setting by skilled technicians, and a single test can cost roughly $700 and take five to seven days to process.
In contrast, SELFA uses microchip technology to analyze samples. The test can take between 30 minutes and two hours and, according to the UCLA researchers, could cost just a few dollars per sample when high-volume production begins.
The SELFA chip contains a T-shaped nanowire that acts as an integrated sensor and amplifier. To analyze a sample, scientists place it on a sensor on the chip. The vertical part of the T-shaped nanowire converts the current from the molecule being analyzed, and the horizontal portion amplifies that signal to distinguish the molecule from others.
The use of the T-shaped nanowires created in Chui’s lab is a new application of a UCLA patented invention that was developed by Chui and his colleagues. The device is the first time that “lab-on-a-chip” analysis has been tested in a scenario that mimics a real-life situation.
The UCLA scientists exposed cultured lung cells to different nanomaterials and then compared their results using SELFA with results in a database of previous studies that used other testing methods.
“By measuring biomarker concentrations in the cell culture, we showed that SELFA was 100 times more sensitive than ELISA,” Meng said. “This means that not only can SELFA analyze much smaller sample sizes, but also that it can minimize false-positive test results.”
Chui said, “The results are significant because SELFA measurement allows us to predict the inflammatory potential of a range of nanomaterials inside cells and validate the prediction with cellular imaging and experiments in animals’ lungs.”
Other authors were UCLA graduate student Yufei Mao, UCLA postdoctoral scholar Kyeong-Sik Shin, and UCLA staff scientists Xiang Wang and Zhaoxia Ji.
The research was supported by the National Science Foundation, the Environmental Protection Agency and the University of California Center for Environmental Implications of Nanotechnology.
Suggested Items
TRI Opens New Manufacturing Facility
05/16/2024 | TRITest Research, Inc. (TRI), the leading test and inspection systems provider for the electronics manufacturing industry, announced that it has opened a state-of-the-art R&D and manufacturing facility.
Real Time with… IPC APEX EXPO 2024: Circuit Board Testing Strategies and the Impact of AI
05/08/2024 |Editor Marcy LaRont speaks with Bert Horner, president of The Test Connection, about the importance of strategic planning and design-for-test (DFT). Bert touches on some common mistakes that occur when DFT is not adequately considered early on. The discussion outlines an overarching industry need for a culture shift toward increasingly higher levels of integration and collaboration. Bert mentions that AI now has an influence on testing, as everywhere else, and announces his forthcoming book.
Real Time with… IPC APEX EXPO 2024: Understanding Objective Evidence in Manufacturing Processes
05/07/2024 | Real Time with...IPC APEX EXPOGraham Naisbitt explains the importance of objective evidence in manufacturing processes, debunking the common misconception that the ROSE test is a cleanliness test. He also discusses the introduction of Rev J, a requirement for measuring ionic contamination on circuit assemblies, and the challenges in accurately measuring contamination. Alternative methods like ion chromatography and the need for updating standards like the ROSE test are mentioned.
U.S. Air Force Secretary Kendall Flies in AI-Piloted X-62A VISTA
05/06/2024 | Lockheed MartinLockheed Martin Skunk Works joined the U.S. Air Force Test Pilot School and other government and industry partners in hosting U.S. Secretary of the Air Force Frank Kendall to fly in the X-62A Variable In-flight Simulation Test Aircraft (VISTA), a one-of-a-kind aircraft modified to test artificial intelligence (AI) and autonomy capabilities.
Real Time with… IPC APEX EXPO 2024: Software Solutions for Circuit Board Challenges
05/03/2024 | Real Time with...IPC APEX EXPONolan Johnson speaks with Will Webb from Aster Technologies about their software solutions for design teams, manufacturing, test engineers, and process engineers. Aster's software addresses the increasing complexities of circuit boards and the need for alternative testing methods.