2020
DOI: 10.1088/1758-5090/ab7d76
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Engineering of brain-like tissue constructs via 3D Cell-printing technology

Abstract: The development of 3D Cell-printing technology contributes to the application of tissue constructs in vitro in neuroscience. Collecting neural cells from patients is an efficient way of monitoring health of an individual target, which, in turn, benefits the enhancement of medicines. The fabricated sample of neural cells is exposed to potential drugs for the analysis of neuron responses. 3D cell-printing as an emerging biofabrication technology has been widely used to mimic natural 3D models in in vitro tissue … Show more

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Cited by 24 publications
(17 citation statements)
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“…suitable ECM), due to the enhancement of hydrogel mechanical strength by CNC incorporation. Overall, these printing results exemplified the great potential of the unique CNC-incorporated 135ACG bioink for ME printing of cell-compatible structures with high aspect ratio [46][47][48] .…”
Section: Printability Of the Hybrid Bioinkmentioning
confidence: 64%
“…suitable ECM), due to the enhancement of hydrogel mechanical strength by CNC incorporation. Overall, these printing results exemplified the great potential of the unique CNC-incorporated 135ACG bioink for ME printing of cell-compatible structures with high aspect ratio [46][47][48] .…”
Section: Printability Of the Hybrid Bioinkmentioning
confidence: 64%
“…3D bioprinting has attracted great interest for its capability to precisely deposit cells and materials (i.e., bioinks) into 3D complex structures, toward applications in engineering in vitro living systems that can be used in disease modeling [ 1 ] and tissue regeneration. [ 2,3 ] Various bioprinting techniques have been developed so far such as inkjet bioprinting [ 4 ] and digital light processing (DLP) ‐based bioprinting. [ 5 ] Among them, the most common modality is extrusion bioprinting, in which a bioink needs to be extruded and then rapidly stabilized to preserve fidelity of the printed structures by digital design.…”
Section: Introductionmentioning
confidence: 99%
“…Thus, the demand for 3D-biofabricated tissues and organ-on-a-chip devices is significantly increasing thanks to their key advantages of enabling direct real-time or end-point analysis. These systems can reveal the collective and independent interaction of an organ’s different tissue components with new therapeutics and unveil the mechanism of drug action and their efficacy at the molecular level ( Benam et al, 2016 ; Knowlton and Tasoglu, 2016 ; Srivastava et al, 2016 ; Song et al, 2020 ; Si et al, 2021 ). However, small culture volumes and low cell numbers in these platforms often give rise to technical issues associated with detection sensitivity and specificity.…”
Section: Tackling Current Biomedical Challenges With Frontier Technologiesmentioning
confidence: 99%