Issue Date | Title | Author(s) | Relation | scopus | WOS | Fulltext/Archive link |
2018 | Accurate Oxygen Tension Profile Measurement within Microfluidic Devices Using Frequency Domain Fluorescence Lifetime Microscopy (FD-FLIM) | H.-M. Wu; T.-A. Lee; P.-L. Ko; W.-H. Liao; Y.-C. Tung | | | | |
2019 | Development of a Microfluidic Device Capable of Generating Oxygen Gradients for Three-Dimensional Cell Culture in Hydrogel | H.-H. Hsu; P.-L. Ko; H.-M. Wu; T.-A. Lee; H.-C. Lin; Y.-C. Tung | | | | |
2018 | Development of in vitro Blood-Air Barrier Model for Studying Penetration of Particulate Matter | T.-A. Lee; P.-L. Ko; C.-C. Peng; Y.-C. Tung | | | | |
2020 | Development of in vitro Microfluidic Circulatory System | P.-L. Ko; T.-A. Lee; H.-H. Hsu; W.-H. Liao; Y.-C. Tung | | | | |
2020 | Disposable Electrofluidic Pressure Sensor-Embedded Microfluidic Viscometer for Biomedical Applications | T.-A. Lee; W.-H. Liao; P.-L. Ko; Y.-C. Tung | | | | |
2023 | Efficient single-cell oxygen consumption rate characterization based on frequency domain fluorescence lifetime imaging microscopy measurement and microfluidic platform | S. Kannan; P.-L. Ko; H.-M. Wu; Y.-C. Tung | BIOMICROFLUIDICS 17, 054105 | | | |
2017 | Electrofluidic Circuit Pressure Sensor Integrated Microfluidic Devices for Biomedical Applications | Y.-C. Tung; T.-A. Lee; P.-L. Ko; W.-H. Liao | | | | |
2019 | Microfluidic Collective Cell Migration Assay for Study of Endothelial Cell Proliferation and Migration under Combinations of Oxygen Gradients, Tensions, and Drug Treatments | H.-C. Shih; T.-A. Lee; H.-M. Wu; P.-L. Ko; W.-H. Liao; Y.-C. Tung | Scientific Reports 9, 8234 | | | |
2022 | Revealing Anisotropic Elasticity of Endothelium under Fluid Shear Stress | P.-L. Ko; C.-K. Wang; H.-H. Hsu; T.-A. Lee; Y.-C. Tung | Acta Biomaterialia 145, 316-328 | | | |
2018 | Review of Microfluidic Cell Culture Devices for the Control of Gaseous Microenvironments in vitro | H.-M. Wu; T.-A. Lee; P.-L. Ko; H.-J. Chiang; C.-C. Peng; Y.-C. Tung | JOURNAL OF MICROMECHANICS AND MICROENGINEERING 28, 043001 | | | |
2021 | Study 3D Endothelial Cell Network Formation under Various Oxygen Microenvironment and Hydrogel Composition Combinations Using Upside-Down Microfluidic Devices | H.-H. Hsu; P.-L. Ko; H.-M. Wu; H.-C. Line; C.-K. Wang; Y.-C. Tung | SMALL 17(15), 2006091 | | | |
2021 | Study Angiogenesis into Three-Dimensional (3D) Matrix of Endothelial Cells under Oxygen Gradients Using Microfluidic Devices | H.-H. Hsu; P.-L. Ko; Y.-C. Tung | | | | |
2017 | Study Effect of Oncogene on In-Plane Elasticity of Alveolar Epithelial Cells Using Electrofluidic Pressure Sensor-Embedded Microfluidic Device | P.-L. Ko; T.-A. Lee; C.-K. Wang; C.-C. Peng; Y.-C. Tung | | | | |
2018 | Study Effects of Hypoxia-Inducible Factor (HIF) Inhibitor on Endothelial Cell Migration under Oxygen Gradients Using Microfluidic Wound Healing Assay | H.-C. Shih; T.-A. Lee; H.-M. Wu; P.-L. Ko; Y.-C. Tung | | | | |
2019 | Study Endothelial Cell Networking in Hydrogel under Oxygen Gradients Using Microfluidic Device | H.-H. Hsu; P.-L. Ko; T.-A. Lee; H.-C. Lin; Y.-C. Tung | | | | |
2018 | Study In-Plane Elasticities of Endothelial Cells in Different Directions Using Electrofluidic Pressure Sensor-Embedded Microfluidic Devices | P.-L. Ko; T.-A. Lee; C.-K. Wang; W.-H. Liao; Y.-C. Tung | | | | |
2021 | Study Sprouting of Endothelial Cells into Three-Dimensional (3D) Matrices under Oxygen Gradients Using Microfluidic Devices | H.-H. Hsu; P.-L. Ko; Y.-C. Tung | | | | |
2023 | Studying sprouting angiogenesis under combination of oxygen gradients and co-culture of fibroblasts using microfluidic cell culture model | H.-H. Hsu; P.-L. Ko; C.-C. Peng; Y.-J. Cheng ; H.-M. Wu; Y.-C. Tung | MATERIALS TODAY BIO 21, 100703 | | | |
2020 | Toward a Systemic in vitro Model: Microfluidic Cell Culture,” 2020 Annual Meeting of Taiwan Nanomedicine Society | P.-L. Ko; H.-H. Hsu; H.-M. Wu; Y.-C. Tung | | | | |
2019 | Widefield frequency domain fluorescence lifetime imaging microscopy (FD-FLIM) for accurate measurement of oxygen gradients within microfluidic devices | H.-M. Wu; T.-A. Lee; P.-L. Ko; W.-H. Liao; T.-H. Hsieh ; Y.-C. Tung | Analyst 144(11), 3494-3504 | | | |