Momentum - The Magazine for Virginia Tech Mechanical Engineering Vol. 2 No. 4 Winter 2017 | Page 23

releases the loaded drug particles. Focused ultrasound waves are those with fre- quencies higher than the upper audible limit of human hearing. The use of this unusual trigger to activate the shape-memory polymers is what sets the team’s findings apart from others doing similar work in the field of drug delivery systems. The benefits of using focused ultrasound waves to activate the shape-memory polymer drug delivery container, instead of light or heat, include the flexible, noninvasive nature of the stimulus. Previous shape-memory polymer containers have relied on natural body heat for activation and can be difficult to control. Other noninvasive methods, such as magnetic fields or exposure to light, require special particles to generate a response. These additional particles can compromise the biodegradability and biocompatibility of shape-memory polymers. Shima Shahab, an assistant professor in the Department of Biomedical Engineering and Mechanics and Bhargava’s faculty advisor, co-au- thored the study alongside Reza Mirzaeifar, an assistant professor of mechanical engineering; Jerry Stieg, a mechanical engineering undergrad- uate; and Kaiyuan Peng, a Ph.D. student in the mechanical engineering program, all of Virginia Tech. to design various ultrasound-activated drug delivery containers,” said Shahab. “The frame- works in this study can be specifically tailored for different applications depending on the size of drug particles, target time for releasing the parti- cles, and the size and shape of the container.” In addition to garnering attention in the field of drug delivery systems, the findings recently won the award for Best Student Paper at the 2017 Conference on Smart Materials, Adaptive Structures, and Intelligent Systems in Snowbird, Utah. Shahab and Mirzaeifar first designed the orig- inal project in a collaboration between Virginia Tech’s MInDS and MultiSMArt labs in August 2016. While the team’s methods are still years away from clinical testing in humans, they have established an important foundation for future research. “The study’s outcome moves us one step closer to the introduction of an efficient new generation of drug delivery systems,” said Mirzaeifar. “Our research will continue to focus on this goal.” Shahab explained the study’s findings would pave the way for designing more-efficient drug delivery capsules in the future, especially those that can be activated by focused ultrasound waves. “We developed an important experimen- tal-computational framework that can be used Far left: Assistant Professor Reza Mirzaeifar; left above, Kaiyuan Peng, an ME doctoral student; left below, Jerry Stieg an ME undergraduate student. MOMENTUM WINTER'17 PAGE 23