3D micro-organisation printing of mammalian cells to generate biological tissues

Autor:	Lydia Moll, Owe Orwar, Christoffer Gyllensten, Vladimir Kirejev, Tatsiana Lobovkina, Gavin D. M. Jeffries, Florian Tusseau, Paul Karila, Shijun Xu, Avadhesh Kumar Singh
Jazyk:	angličtina
Předmět:	0301 basic medicine Cell type Cell Survival Microfluidics Cell lcsh:Medicine Tretinoin 02 engineering and technology Article Cell Line Mice 03 medical and health sciences Cell Line Tumor medicine Animals Humans Primary cell Fibroblast lcsh:Science Cell Proliferation Skin Multidisciplinary Tissue Engineering Chemistry Biological techniques lcsh:R Bioprinting 3T3 Cells Hep G2 Cells 021001 nanoscience & nanotechnology In vitro Rats Cell biology Hep G2 HaCaT 030104 developmental biology medicine.anatomical_structure Microscopy Fluorescence Printing Three-Dimensional lcsh:Q 0210 nano-technology Biotechnology
Zdroj:	Scientific Reports, Vol 10, Iss 1, Pp 1-10 (2020) Scientific Reports
ISSN:	2045-2322
DOI:	10.1038/s41598-020-74191-w
Popis:	Significant strides have been made in the development of in vitro systems for disease modelling. However, the requirement of microenvironment control has placed limitations on the generation of relevant models. Herein, we present a biological tissue printing approach that employs open-volume microfluidics to position individual cells in complex 2D and 3D patterns, as well as in single cell arrays. The variety of bioprinted cell types employed, including skin epithelial (HaCaT), skin cancer (A431), liver cancer (Hep G2), and fibroblast (3T3-J2) cells, all of which exhibited excellent viability and survivability, allowing printed structures to rapidly develop into confluent tissues. To demonstrate a simple 2D oncology model, A431 and HaCaT cells were printed and grown into tissues. Furthermore, a basic skin model was established to probe drug response. 3D tissue formation was demonstrated by co-printing Hep G2 and 3T3-J2 cells onto an established fibroblast layer, the functionality of which was probed by measuring albumin production, and was found to be higher in comparison to both 2D and monoculture approaches. Bioprinting of primary cells was tested using acutely isolated primary rat dorsal root ganglia neurons, which survived and established processes. The presented technique offers a novel open-volume microfluidics approach to bioprint cells for the generation of biological tissues.
Databáze:	OpenAIRE
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