Hal Holmes, a doctoral candidate of Bioengineering working with NanoES Director Karl Böhringer, has been selected as one of 14 Schmidt Science Fellows in the inaugural year of this prestigious program initiated by Eric and Wendy Schmidt.
Month: April 2018
Innovations in Imaging for Life Sciences Symposium: June 20
Please join the third Innovations in Imaging for Life Sciences Symposium at the University of Washington on June 20, 2018. The talks will focus on advances in imaging from atomic to tissue scales, including cryo-electron microscopy and volume scope imaging.
To register (no charge) please go here: https://catalyst.uw.edu/webq/survey/jkoll/353918
AFM Workshop for Scanning Microwave Impedance, May 1, 10:00 – 11:30 am, MolES 215
PrimeNano will give a talk on the method May 1st from 10:00 am – 11:30 am in MolES 215. They will then provide demos on the technique using our AFM Dimension Icon that afternoon and the next day.
Speaker Bio: Oskar Amster, M.S. (Sr. Dir. Marketing of PrimeNano, Inc)
Mr. Amster has a background in Physics and Materials engineering with a focus on microelectronics processing. He has 20 years experience working with analytical instruments and metrology tools. His background is in applications development, strategic marketing, and product development. He has extensive experience working in Atomic Force Microscopy, Stylus Profilers, and Optical Profiler instruments. Prior to joining PrimeNano, Inc, Oskar was at KLA-Tencor and also held positions at several start-ups as well as mature instrument companies. He holds an MS in Materials Engineering and BS in Physics from Cal Poly San Luis Obispo.
Yoshikazu Hirai, University of Kyoto – Body-on-a-Chip: an application of three-dimensional microstructuring techniques: April 13, 10:30 am, NanoES 291
Body-on-a-Chip: an application of three-dimensional microstructuring techniques
Yoshikazu HIRAI
Department of Micro Engineering, Kyoto University, JAPAN
E-mail: hirai@me.kyoto-u.ac.jp
http://www.nms.me.kyoto-u.ac.jp/en/member/hirai/
NanoES 291
Abstract
This presentation introduces three-dimensional (3-D) microstructuring methods based on optical lithography and addresses one of their application for developing “Body-on-a-Chip.” In vitro cell-based assay with human cells is getting attention since the accuracy of preclinical predictions of drug responses should be improved to reducing costly failures in clinical trials. In order to generate reliable predictions, we have developed a micro-engineered biomimetic systems “Body-on-a-Chip,” to investigate the effects of drugs/metabolites on multi organs by assembling a closed-loop medium circulation system on one microfluidic device. For 3-D polymeric sensor/actuator device fabrication, an advanced 3-D lithography with the process optimization was applied to improve device performances. Our Body-on-a-Chip was successfully applied to evaluate the effect of an anti-cancer drug (doxorubicin) on cell survival of human heart and liver cells.
Biography
Yoshikazu Hirai received the B.S. and M.S. degrees from Ritsumeikan University, Japan, in 2002 and 2004, respectively, and the Ph.D. degree from Kyoto University, Japan, in 2007, all in mechanical engineering. He was a Post-doctoral Researcher with the Graduate School of Engineering, Kyoto University. In 2009, he joined the Advanced Biomedical Engineering Research Unit, Kyoto University. Since 2013, he has been an Assistant Professor with the Department of Micro Engineering, Kyoto University. Dr. Hirai was a recipient of the Outstanding Reviewer Award in 2016 (Journal of Micromechanics and Microengineering, IoP) and the Institute of Electrical Engineers of Japan (IEEJ) Distinguished Paper Award in 2017. His current research interests include (1) Fabrication and packaging technologies for MEMS, (2) Optical lithography for 3D microstructuring, (3) Atomic sensor device (e.g., CSAC: Chip Scale Atomic Clock, CSAM: Chip Scale Atomic Magnetometer), and (4) Microfluidic system/device for biomedical applications.
What is the National Nanotechnology Coordinated Infrastructure?
NanoES is one of 16 primary sites in the National Nanotechnology Coordinated Infrastructure (NNCI). Learn more about what NNCI is and their goals for nanotechnology in this promotional video.