Your search keyword '"compartmentalized devices"' showing total 2 results

1. 3D‐Printed Soft Lithography for Complex Compartmentalized Microfluidic Neural Devices.

Author

Kajtez, Janko, Buchmann, Sebastian, Vasudevan, Shashank, Birtele, Marcella, Rocchetti, Stefano, Pless, Christian Jonathan, Heiskanen, Arto, Barker, Roger A., Martínez‐Serrano, Alberto, Parmar, Malin, Lind, Johan Ulrik, and Emnéus, Jenny

Subjects

*SOFT lithography, *MICROFLUIDIC devices, *CONSTRUCTION materials, *HUMAN stem cells

Abstract

Compartmentalized microfluidic platforms are an invaluable tool in neuroscience research. However, harnessing the full potential of this technology remains hindered by the lack of a simple fabrication approach for the creation of intricate device architectures with high‐aspect ratio features. Here, a hybrid additive manufacturing approach is presented for the fabrication of open‐well compartmentalized neural devices that provides larger freedom of device design, removes the need for manual postprocessing, and allows an increase in the biocompatibility of the system. Suitability of the method for multimaterial integration allows to tailor the device architecture for the long‐term maintenance of healthy human stem‐cell derived neurons and astrocytes, spanning at least 40 days. Leveraging fast‐prototyping capabilities at both micro and macroscale, a proof‐of‐principle human in vitro model of the nigrostriatal pathway is created. By presenting a route for novel materials and unique architectures in microfluidic systems, the method provides new possibilities in biological research beyond neuroscience applications. [ABSTRACT FROM AUTHOR]

Published

2020

2. 3D-Printed Soft Lithography for Complex Compartmentalized Microfluidic Neural Devices

Author

Arto Heiskanen, Roger A. Barker, Malin Parmar, Alberto Martínez-Serrano, Sebastian Buchmann, Jenny Emnéus, Janko Kajtez, Shashank Vasudevan, Marcella Birtele, Johan Ulrik Lind, Christian Jonathan Pless, Stefano Rocchetti, European Commission, Lund University, Kajtez, Janko [0000-0001-9997-2325], Vasudevan, Shashank [0000-0001-6490-3434], and Apollo - University of Cambridge Repository

Subjects

3d printed, fast prototyping, Computer science, General Chemical Engineering, Science, Human neural stem cells, Microfluidics, neurite guidance, General Physics and Astronomy, Medicine (miscellaneous), 3D printing, soft lithography, Nanotechnology, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, Biochemistry, Genetics and Molecular Biology (miscellaneous), Corrections, Soft lithography, In vitro model, compartmentalized devices, SDG 3 - Good Health and Well-being, General Materials Science, Neurite guidance, lcsh:Science, nigrostriatal pathway, Nigrostriatal pathway, Full Paper, business.industry, General Engineering, Compartmentalized devices, Correction, Full Papers, 021001 nanoscience & nanotechnology, 0104 chemical sciences, Fast prototyping, human neural stem cells, lcsh:Q, Neuroscience research, 0210 nano-technology, business

Abstract

Compartmentalized microfluidic platforms are an invaluable tool in neuroscience research. However, harnessing the full potential of this technology remains hindered by the lack of a simple fabrication approach for the creation of intricate device architectures with high‐aspect ratio features. Here, a hybrid additive manufacturing approach is presented for the fabrication of open‐well compartmentalized neural devices that provides larger freedom of device design, removes the need for manual postprocessing, and allows an increase in the biocompatibility of the system. Suitability of the method for multimaterial integration allows to tailor the device architecture for the long‐term maintenance of healthy human stem‐cell derived neurons and astrocytes, spanning at least 40 days. Leveraging fast‐prototyping capabilities at both micro and macroscale, a proof‐of‐principle human in vitro model of the nigrostriatal pathway is created. By presenting a route for novel materials and unique architectures in microfluidic systems, the method provides new possibilities in biological research beyond neuroscience applications., In this study, a hybrid additive manufacturing approach to soft lithography is developed for the fabrication of open‐well compartmentalized microfluidic devices used to engineer human stem‐cell derived neural networks in vitro. The approach provides larger freedom of design, removes the need for manual postprocessing, increases the biocompatibility of the system, and enables fast prototyping at the micro and macroscale.

Published

2020