Your search keyword '"Lee, Junmin"' showing total 2 results

1. Epidermis-Inspired Wearable Piezoresistive Pressure Sensors Using Reduced Graphene Oxide Self-Wrapped Copper Nanowire Networks

Author

Zhu, Yangzhi, Hartel, Martin C, Yu, Ning, Garrido, Pamela Rosario, Kim, Sanggon, Lee, Junmin, Bandaru, Praveen, Guan, Shenghan, Lin, Haisong, Emaminejad, Sam, de Barros, Natan Roberto, Ahadian, Samad, Kim, Han-Jun, Sun, Wujin, Jucaud, Vadim, Dokmeci, Mehmet R, Weiss, Paul S, Yan, Ruoxue, and Khademhosseini, Ali

Subjects

Wearable Electronic Devices, piezoresistive sensors, wearable electronics, Nanowires, flexible transparent electrodes, Humans, electronic skin, Graphite, bioinspired microstructures, core-shell nanowires, Copper

Abstract

Wearable piezoresistive sensors are being developed as electronic skins (E-skin) for broad applications in human physiological monitoring and soft robotics. Tactile sensors with sufficient sensitivities, durability, and large dynamic ranges are required to replicate this critical component of the somatosensory system. Multiple micro/nanostructures, materials, and sensing modalities have been reported to address this need. However, a trade-off arises between device performance and device complexity. Inspired by the microstructure of the spinosum at the dermo epidermal junction in skin, a low-cost, scalable, and high-performance piezoresistive sensor is developed with high sensitivity (0.144kPa-1 ), extensive sensing range ( 0.1-15 kPa), fast response time (less than 150ms), and excellent long-term stability (over 1000 cycles). Furthermore, the piezoresistive functionality of the device is realized via a flexible transparent electrode (FTE) using a highly stable reduced graphene oxide self-wrapped copper nanowire network. The developed nanowire-based spinosum microstructured FTEs are amenable to wearable electronics applications.

Published

2022

2. hiPSC-derived 3D Bioprinted Skeletal Muscle Tissue Implants Regenerate Skeletal Muscle Following Volumetric Muscle Loss

Author

Jodat, Yasamin A., Zhang, Ting, Tanoury, Ziad Al, Kamperman, Tom, Shi, Kun, Huang, Yike, Panayi, Adriana, Endo, Yori, Wang, Xichi, Quint, Jacob, Arnaout, Adnan, Kiaee, Kiavash, Hassan, Shabir, Lee, Junmin, Martinez, Angel Flores Huidobro, Ochoa, Sofia Lara, Lee, KangJu, Calabrese, Michelle, Carlucci, Alessandro, Tamayol, Ali, Sinha, Indranil, Pourquié, Olivier, Ryon Shin, Su, Developmental BioEngineering, and TechMed Centre

Abstract

Engineering of biomimetic tissue implants provides an opportunity for repairing volumetric muscle loss (VML), beyond a tissue’s innate repair capacity. Here, we present thick, suturable, and pre-vascularized 3D muscle implants containing human induced pluripotent stem cell-derived myogenic precursor cells (hiPSC-MPCs), which can differentiate into skeletal muscle cells while maintaining a self-renewing pool. The formation of contractile myotubes and millimeter-long fibers from hiPSC-MPCs is achieved in chemically, mechanically, and structurally tailored extracellular matrix-based hydrogels, which can serve as scaffolds to ultimately organize the linear fusion of myoblasts. Embedded multi-material bioprinting is used to deposit complex patterns of perfusable vasculatures and aligned hiPSC-MPC channels within an endomysium-like supporting gel to recapitulate muscle architectural integrity in a facile yet highly rapid manner. Moreover, we demonstrate successful graft-host integration and de novo muscle formation upon in vivo implantation of pre-vascularized constructs within a VML model. This work pioneers the engineering of large pre-vascularized hiPSC-derived muscle tissues toward next generation VML regenerative therapies.

Published

2021