\n<\/strong><\/p>\n
3D<\/span> cultures<\/span> and<\/span> cell<\/span>–<\/span>laden <\/span>hydrogel<\/span> constructs<\/span> are<\/span> fundamental<\/span> in<\/span> biomedical <\/span>research<\/span> as<\/span> t<\/span>hey<\/span> represent<\/span> physiologically relevant models <\/span>provid<\/span>ing<\/span> mechanistic cues to guide cell fate and function<\/span>. In<\/span> addition,<\/span> advances<\/span> in<\/span> additive<\/span> manufacturing <\/span>techniques, particularly 3D bioprinting, not only allow for <\/span>a precisely shaped construct, but also for the production of <\/span>patient<\/span>–<\/span>specific patches. The ability to recapitulate the <\/span>complexity of the<\/span> in vivo<\/span> milieu<\/span> using 3D bioprin<\/span>ting is <\/span>particularly important for<\/span> studies involving the<\/span> role of the <\/span>tumor microenvironment (TME)<\/span> in cancer<\/span>,<\/span> improving <\/span>upon<\/span> 2D cultures or scaffold<\/span>–<\/span>free 3D culture strategies.<\/span> <\/p>\n
3D bioprint<\/span>ed<\/span> tumor models are<\/span> already being developed <\/span>in a variety of struc<\/span>tures ranging from slices, grids, fibers, <\/span>mini<\/span>–<\/span>organs, and custom shapes.<\/span> However, t<\/span>o be <\/span>clinically relevant<\/span>,<\/span> tissue constructs<\/span> must<\/span> be significantly <\/span>thicker than the few hundred microns where diffusion is <\/span>sufficient to provide nutrients to<\/span> all culture<\/span>d<\/span> cells.\u00a0 A <\/span>primary method for overcoming the hurdle of sustaining <\/span>cells in the bulk is to create a vascular network within these <\/span>cell<\/span>–<\/span>laden constructs.<\/span><\/span>
BIAMET lab <\/span> propose a fabrication method for vascularized 3D c<\/span>onstructs<\/span> based on<\/span> sacrificial bioprinting, i.e., the use of <\/span>two different bioinks to create<\/span> hollow<\/span> structure<\/span>s<\/span> embedded <\/span>in<\/span> a<\/span> cell<\/span>–<\/span>laden matrix. With this method, we<\/span> succeeded in <\/span>fabricat<\/span>ing<\/span> customizable endothelialized perfusable 3D <\/span>constructs<\/span> sustaining<\/span> cell<\/span> culture for<\/span> ov<\/span>er<\/span> two weeks under <\/span>continuous perfusion.<\/span><\/span><\/p>\n![\"\"](\"https:\/\/research.dii.unipd.it\/biamet\/wp-content\/uploads\/sites\/26\/2022\/12\/3D_2.jpg\")
<\/p>\n![\"\"](\"https:\/\/research.dii.unipd.it\/biamet\/wp-content\/uploads\/sites\/26\/2022\/12\/12541878-80ab-443d-8fa3-949cff6eef5c.jpg\")
<\/p>\n![\"\"](\"https:\/\/research.dii.unipd.it\/biamet\/wp-content\/uploads\/sites\/26\/2023\/01\/64b07cc3-21e6-4e90-a7e4-35b4523378a5-1024x763.jpg\")
<\/p>\n","protected":false},"excerpt":{"rendered":"