Seminar & Colloquium
Conducting Polymer Hydrogels for Hydrogel Bioelectronics
Speaker
Hyunwoo Yuk, Ph.D
EDUCATION
Ph.D. in Mechanical Engineering Jun 2016 - Dec 2020
Massachusetts Institute of Technology, Cambridge, MA, United States
(Thesis: Wet Adhesion and Bioadhesive Technology)
M.S. in Mechanical Engineering Sep 2014 - Jun 2016
Massachusetts Institute of Technology, Cambridge, MA, United States
(Thesis: Tough Wet Adhesion of Hydrogel on Various Materials)
B.S. in Mechanical Engineering Feb 2007 - Feb 2014
Korea Advanced Institute of Science and Technology (KAIST), Daejeon, Republic of Korea
Graduation with Summa Cum Laude
(Note: Military Service during June 2011 - June 2013)
RESEARCH FOCUSES
-Soft materials for human health
-Wet adhesion and bioadhesive technologies
-Hydrogel bioelectronics
-3D printing of soft functional materials
-Soft active materials and robots
AWARDS&HONORS
-Collegiate Inventors Competition Graduate Winner, National Inventors Hall of Fame, 2020
-BMES Student Design and Research Award, Biomedical Engineering Society, 2019
-de Florez Graduate Design Award - 1st Place, Department of Mechanical Engineering, MIT, 2019
-Wunsch - Outstanding Graduate Research Award, Department of Mechanical Engineering,
MIT, 2019
-MRS Graduate Student Award - Gold, Materials Research Society, 2019
-Peebles Award, The Adhesion Society, 2019
-Forbes 30 Under 30 2019: Science, Forbes, 2018
-Face of the Year, Samsung Scholarship, 2018
-MRS Graduate Student Award - Silver, Materials Research Society, 2018
-2015 Samsung Scholarship, Samsung Scholarship Foundation, 2015
-Summa Cum Laude, KAIST, 2014
-2013 Samsung Scholarship, Samsung Scholarship Foundation, 2013
| Date | Tuesday, September 28th, 2021
| Time | 09:30 ~
| Venue | 온라인 강의 (https://snu-ac-kr.zoom.us/j/82646784523?pwd=d3lINE16STczVW8wdlhKR0hJY0p5QT09)
회의 ID: 826 4678 4523
암호: 1010
Abstract
Electrical interfacing with biological tissues for interrogation and modulation of living systems ? or bioelectronics ?
is one of the most important modes of communication between artificial machines and biological organisms.
In conventional applications, bioelectronic interfacing has relied on conventional electrodes and devices made of metals
and engineering solids like plastics and elastomers. However, the stark dissimilarity between biological tissues and conventional
device materials has posed great challenges for long-term bioelectronic interfacing with living systems, especially for implantable
devices. To address these challenges, electrically conductive hydrogels ? polymer networks infiltrated with large amounts of water
with electrical conductivity ? have been substantially studied in the last decades owing to their unique advantages
including tissue-like mechanical properties and high water contents, favorable electrical properties, and in vivo biocompatibility.
However, conducting polymer hydrogels has faced several key challenges in their practical uses including poor electrical and
mechanical properties in physiological environments, unreliable integration within devices and to the target biological tissue,
and difficulties in small-scale fabrications into functional devices. In this talk, several advances on conducting polymer hydrogels
to address these challenges will be discussed toward the vision of hydrogel bioelectronics.
| Host | Prof. Seung-Kyun Kang (kskg7227@snu.ac.kr)