Se-Hwan 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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Decellularized extracellular matrix bioinks and the external stimuli to enhance cardiac tissue development in vitro

Das

Kim

Choi³

et al. 2019

Acta Biomaterialia

123

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Development of functional lab-on-a-chip on polymer for point-of-care testing of metabolic parameters

Lee

Han

et al. 2008

Lab Chip

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This paper presents the development of an easy-to-handle and disposable clinical diagnostic lab-on-a-chip using fully integrated plastic microfluidic components, which has the sampling/identifying capability to make fast and reliable measurements of metabolic parameters from human whole blood. A smart and functional lab-on-a-chip cartridge, which incorporates a full on-chip auto-calibration function for in the field applications, has been developed, and then fully characterized using a portable analyzer (3 (1/4)''x 5''x 1'') with multi-analyte detection capability. In addition, several new approaches in realizing smart and functional lab-on-a-chips on polymer have been adopted, which include the pinch valve for automatic fluidic sealing, a by-pass channel as the sampling indicator, and a robust connector design for long analyzer lifetimes. Metabolic parameters such as glucose, lactate, and partial oxygen from human whole blood have been successfully measured using the functional polymer lab-on-a-chips and the portable analyzer developed in this work.

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Assessments of polycaprolactone/hydroxyapatite composite scaffold with enhanced biomimetic mineralization by exposure to hydroxyapatite via a 3D-printing system and alkaline erosion

Cho

Choi

Lee

et al. 2019

European Polymer Journal

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Assessment of osteogenesis for 3D-printed polycaprolactone/hydroxyapatite composite scaffold with enhanced exposure of hydroxyapatite using rat calvarial defect model

Cho

Quan

Lee

et al. 2019

Composites Science and Technology

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Se-Hwan Lee

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

Decellularized extracellular matrix bioinks and the external stimuli to enhance cardiac tissue development in vitro

Development of functional lab-on-a-chip on polymer for point-of-care testing of metabolic parameters

Assessments of polycaprolactone/hydroxyapatite composite scaffold with enhanced biomimetic mineralization by exposure to hydroxyapatite via a 3D-printing system and alkaline erosion

Assessment of osteogenesis for 3D-printed polycaprolactone/hydroxyapatite composite scaffold with enhanced exposure of hydroxyapatite using rat calvarial defect model

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