Kwang-Seok Lee scite author profile

Tissue engineering requires not only tissue‐specific functionality but also a realistic scale. Decellularized extracellular matrix (dECM) is presently applied to the extrusion‐based 3D printing technology. It has demonstrated excellent efficiency as bioscaffolds that allow engineering of living constructs with elaborate microarchitectures as well as the tissue‐specific biochemical milieu of target tissues and organs. However, dECM bioinks have poor printability and physical properties, resulting in limited shape fidelity and scalability. In this study, new light‐activated dECM bioinks with ruthenium/sodium persulfate (dERS) are introduced. The materials can be polymerized via a dityrosine‐based cross‐linking system with rapid reaction kinetics and improved mechanical properties. Complicated constructs with high aspect ratios can be fabricated similar to the geometry of the desired constructs with increased shape fidelity and excellent printing versatility using dERS. Furthermore, living tissue constructs can be safely fabricated with excellent tissue regenerative capacity identical to that of pure dECM. dERS may serve as a platform for a wider biofabrication window through building complex and centimeter‐scale living constructs as well as supporting tissue‐specific performances to encapsulated cells. This capability of dERS opens new avenues for upscaling the production of hydrogel‐based constructs without additional materials and processes, applicable in tissue engineering and regenerative medicine.

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Continuous and programmable photomechanical jumping of polymer monoliths

Jeon

Choi

Hyeok

et al. 2021

Materials Today

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Integration Technology of 30nm Generation Multi-Level NAND Flash for 64Gb NAND Flash Memory

Kwak

Park

Kim

et al. 2007

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A Spherical Hybrid Triboelectric Nanogenerator for Enhanced Water Wave Energy Harvesting

Lee

Kim

et al. 2018

Micromachines

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Water waves are a continuously generated renewable source of energy. However, their random motion and low frequency pose significant challenges for harvesting their energy. Herein, we propose a spherical hybrid triboelectric nanogenerator (SH-TENG) that efficiently harvests the energy of low frequency, random water waves. The SH-TENG converts the kinetic energy of the water wave into solid–solid and solid–liquid triboelectric energy simultaneously using a single electrode. The electrical output of the SH-TENG for six degrees of freedom of motion in water was investigated. Further, in order to demonstrate hybrid energy harvesting from multiple energy sources using a single electrode on the SH-TENG, the charging performance of a capacitor was evaluated. The experimental results indicate that SH-TENGs have great potential for use in self-powered environmental monitoring systems that monitor factors such as water temperature, water wave height, and pollution levels in oceans.

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A unified model for unipolar resistive random access memory

Lee

Jang

Kwon

et al. 2012

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Kwang-Seok Lee

Light‐Activated Decellularized Extracellular Matrix‐Based Bioinks for Volumetric Tissue Analogs at the Centimeter Scale

Continuous and programmable photomechanical jumping of polymer monoliths

Integration Technology of 30nm Generation Multi-Level NAND Flash for 64Gb NAND Flash Memory

A Spherical Hybrid Triboelectric Nanogenerator for Enhanced Water Wave Energy Harvesting

A unified model for unipolar resistive random access memory

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