Bioprinting a 3D vascular construct for engineering a vessel-on-a-chip
M Abudupataer, N Chen, S Yan, F Alam, Y Shi… - Biomedical …, 2020 - Springer
The organ-on-a-chip model mimics the structural and functional features of human tissues or
organs and has great importance in translational research. For vessel-on-a-chip model,
conventional fabrication techniques are unable to efficiently imitate the intimal-medial unit of
the vessel wall. Bioprinting technology, which can precisely control the organization of cells,
biomolecules, and the extracellular matrix, has the potential to fabricate three-dimensional
(3D) tissue constructs with spatial heterogeneity. In this study, we applied the gelatin …
organs and has great importance in translational research. For vessel-on-a-chip model,
conventional fabrication techniques are unable to efficiently imitate the intimal-medial unit of
the vessel wall. Bioprinting technology, which can precisely control the organization of cells,
biomolecules, and the extracellular matrix, has the potential to fabricate three-dimensional
(3D) tissue constructs with spatial heterogeneity. In this study, we applied the gelatin …
Bioprinting a 3D vascular construct for engineering a vessel-on-a-chip
A Mieradilijiang, N Chen, Y Shiqiang… - Biomedical …, 2020 - search.proquest.com
The organ-on-a-chip model mimics the structural and functional features of human tissues or
organs and has great importance in translational research. For vessel-on-a-chip model,
conventional fabrication techniques are unable to efficiently imitate the intimal-medial unit of
the vessel wall. Bioprinting technology, which can precisely control the organization of cells,
biomolecules, and the extracellular matrix, has the potential to fabricate three-dimensional
(3D) tissue constructs with spatial heterogeneity. In this study, we applied the gelatin …
organs and has great importance in translational research. For vessel-on-a-chip model,
conventional fabrication techniques are unable to efficiently imitate the intimal-medial unit of
the vessel wall. Bioprinting technology, which can precisely control the organization of cells,
biomolecules, and the extracellular matrix, has the potential to fabricate three-dimensional
(3D) tissue constructs with spatial heterogeneity. In this study, we applied the gelatin …