| Issue Date | Title | Author(s) | Relation | scopus | WOS | Fulltext/Archive link |
| 2019 | A Low-Power CMOS Microfluidic Pump Based on Travelling-Wave Electroosmosis for Diluted Serum Pumping | P.-W. Yen; S.-C. Lin; Y.-C. Huang; Y.-J. Huang; Y.-C. Tung ; S.-S. Lu; C.-T. Lin | Scientific Reports 9, 14794 | | | |
| 2019 | A sheathless inertial focusing technique for optofluidic devices | N. Panwar; P. Song; C. Yang; S. C. Tjin; Y.-C. Tung ; K.-T. Yong | Microfluidics and Nanofluidics 23, 107 | | | |
| 2020 | Comparison of VEGF-A Secretion from Tumor Cells under Cellular Stresses in Conventional Monolayer Culture and Microfluidic Three-Dimensional Spheroid Models | S. Sarkar; C.-C. Peng; Y.-C. Tung | PLOS ONE 15(11), e0240833 | | | |
| 2020 | Cost-Effective Air Quality Monitoring System Based on an Open- Source Electronics Platform for Three-Dimensional Atmospheric Environmental Data Collection | Y.-C. Tung ; D.-M. Chang; C.-Y. Kuo | | | | |
| 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 | | | | |
| 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 | | | | |
| 2020 | Editorial for the Special Issue on Organs-on-Chips | Y. Torisawa; Y.-C. Tung | MICROMACHINES 11(4), 369 | | | |
| 2019 | Editorial: Medical and Industrial Applications of Microfluidic-Based Cell/Tissue Culture and Organs-on-a-Chip | Q Ramadan; M. Albert; M. Dufva; Y.-C. Tung | Frontiers in Bioengineering and Biotechnology 7 | | | |
| 2019 | Epidermal growth factor-like repeats of SCUBE1 derived from platelets are critical for thrombus formation | W.-J. Liao; M.-Y. Wu; C.-C. Peng; Y.-C. Tung ; R.-B. Yang | Cardiovascular Research | | | |
| 2020 | Evaluation of Nanoparticle Penetration in the Tumor Spheroid Using Two-Photon Microscopy | Feby Wijaya Pratiwi; Chien-Chung Peng; Si-Han Wu; Chiung Wen Kuo; Chung-Yuan Mou; Yi-Chung Tung ; Peilin Chen | Biomedicines 9(1), 10 | | | |
| 2019 | Generation and Characterization of Cyclic Oxygen Gradients in Microfluidic Device for Cell Culture | D.-M. Chang; Y.-C. Tung | | | | |
| 2020 | Increased vasculogenesis of endothelial cells in hyaluronic acid augmented fibrin-based natural hydrogels - from in vitro to in vivo models | H.-C. Lin; C.-K. Wang; Y.-C. Tung ; F.-Y. Chiu; Y.-P. Su | EUROPEAN CELLS & MATERIALS 40, 133-145 | | | |
| 2019 | MCT-1/miR-34a/IL-6/IL-6R Signaling Axis Promotes EMT Progression, Cancer Stemness and M2 Macrophage Polarization in Triple-Negative Breast Cancer | Y.-S. Weng; H.-Y. Tseng; Y.-A. Chen; P.-C. Shen; A. T. Al Haq; L.-M. Chen; Y.-C. Tung ; H.-L. Hsu | MOLECULAR CANCER 18, 42 | | | |
| 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 | | | |
| 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 | | | |
| 2019 | Study Effects of Drug Treatment and Physiological Physical Stimulation on Surfactant Protein Expression of Lung Epithelial Cells Using a Biomimetic Microfluidic Cell Culture Device | T.-R. Lin; S.-L. Yeh; C.-C. Peng; W.-H. Liao; Y.-C. Tung | Micromachines 10(6), 400 | | | |
| 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 | | | | |
| 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 | | | |
