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suck abstract from ncbi


10.3390/bioengineering4010010

http://scihub22266oqcxt.onion/10.3390/bioengineering4010010
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C5590440!5590440!28952489
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suck abstract from ncbi

pmid28952489      Bioengineering+(Basel) 2017 ; 4 (1): ä
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  • 3D Printing of Organs-On-Chips #MMPMID28952489
  • Yi HG; Lee H; Cho DW
  • Bioengineering (Basel) 2017[Mar]; 4 (1): ä PMID28952489show ga
  • Organ-on-a-chip engineering aims to create artificial living organs that mimic the complex and physiological responses of real organs, in order to test drugs by precisely manipulating the cells and their microenvironments. To achieve this, the artificial organs should to be microfabricated with an extracellular matrix (ECM) and various types of cells, and should recapitulate morphogenesis, cell differentiation, and functions according to the native organ. A promising strategy is 3D printing, which precisely controls the spatial distribution and layer-by-layer assembly of cells, ECMs, and other biomaterials. Owing to this unique advantage, integration of 3D printing into organ-on-a-chip engineering can facilitate the creation of micro-organs with heterogeneity, a desired 3D cellular arrangement, tissue-specific functions, or even cyclic movement within a microfluidic device. Moreover, fully 3D-printed organs-on-chips more easily incorporate other mechanical and electrical components with the chips, and can be commercialized via automated massive production. Herein, we discuss the recent advances and the potential of 3D cell-printing technology in engineering organs-on-chips, and provides the future perspectives of this technology to establish the highly reliable and useful drug-screening platforms.
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