A dive into the bath: embedded 3D bioprinting of freeform models
Designing functional, vascularized, human scale in vitro models with biomimetic architectures and multiple cell types is a highly promising strategy for both a better understanding of natural tissue/organ development stages to inspire regenerative medicine, and to test novel therapeutics on personal...
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| Veröffentlicht in: | Biomaterials science 2023-08, Vol.11 (16), p.5462-5473 |
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| creator | Öztürk-Öncel, M. Özgen Leal-Martínez, Baltazar Hiram Monteiro, Rosa F Gomes, Manuela E Domingues, Rui M. A |
| description | Designing functional, vascularized, human scale
in vitro
models with biomimetic architectures and multiple cell types is a highly promising strategy for both a better understanding of natural tissue/organ development stages to inspire regenerative medicine, and to test novel therapeutics on personalized microphysiological systems. Extrusion-based 3D bioprinting is an effective biofabrication technology to engineer living constructs with predefined geometries and cell patterns. However, bioprinting high-resolution multilayered structures with mechanically weak hydrogel bioinks is challenging. The advent of embedded 3D bioprinting systems in recent years offered new avenues to explore this technology for
in vitro
modeling. By providing a stable, cell-friendly and perfusable environment to hold the bioink during and after printing, it allows to recapitulate native tissues' architecture and function in a well-controlled manner. Besides enabling freeform bioprinting of constructs with complex spatial organization, support baths can further provide functional housing systems for their long-term
in vitro
maintenance and screening. This minireview summarizes the recent advances in this field and discuss the enormous potential of embedded 3D bioprinting technologies as alternatives for the automated fabrication of more biomimetic
in vitro
models.
This minireview highlights recent advances on the application of embedded 3D bioprinting concepts for the fabrication of
in vitro
models. |
| doi_str_mv | 10.1039/d3bm00626c |
| format | Article |
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in vitro
models with biomimetic architectures and multiple cell types is a highly promising strategy for both a better understanding of natural tissue/organ development stages to inspire regenerative medicine, and to test novel therapeutics on personalized microphysiological systems. Extrusion-based 3D bioprinting is an effective biofabrication technology to engineer living constructs with predefined geometries and cell patterns. However, bioprinting high-resolution multilayered structures with mechanically weak hydrogel bioinks is challenging. The advent of embedded 3D bioprinting systems in recent years offered new avenues to explore this technology for
in vitro
modeling. By providing a stable, cell-friendly and perfusable environment to hold the bioink during and after printing, it allows to recapitulate native tissues' architecture and function in a well-controlled manner. Besides enabling freeform bioprinting of constructs with complex spatial organization, support baths can further provide functional housing systems for their long-term
in vitro
maintenance and screening. This minireview summarizes the recent advances in this field and discuss the enormous potential of embedded 3D bioprinting technologies as alternatives for the automated fabrication of more biomimetic
in vitro
models.
This minireview highlights recent advances on the application of embedded 3D bioprinting concepts for the fabrication of
in vitro
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in vitro
models with biomimetic architectures and multiple cell types is a highly promising strategy for both a better understanding of natural tissue/organ development stages to inspire regenerative medicine, and to test novel therapeutics on personalized microphysiological systems. Extrusion-based 3D bioprinting is an effective biofabrication technology to engineer living constructs with predefined geometries and cell patterns. However, bioprinting high-resolution multilayered structures with mechanically weak hydrogel bioinks is challenging. The advent of embedded 3D bioprinting systems in recent years offered new avenues to explore this technology for
in vitro
modeling. By providing a stable, cell-friendly and perfusable environment to hold the bioink during and after printing, it allows to recapitulate native tissues' architecture and function in a well-controlled manner. Besides enabling freeform bioprinting of constructs with complex spatial organization, support baths can further provide functional housing systems for their long-term
in vitro
maintenance and screening. This minireview summarizes the recent advances in this field and discuss the enormous potential of embedded 3D bioprinting technologies as alternatives for the automated fabrication of more biomimetic
in vitro
models.
This minireview highlights recent advances on the application of embedded 3D bioprinting concepts for the fabrication of
in vitro
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in vitro
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in vitro
modeling. By providing a stable, cell-friendly and perfusable environment to hold the bioink during and after printing, it allows to recapitulate native tissues' architecture and function in a well-controlled manner. Besides enabling freeform bioprinting of constructs with complex spatial organization, support baths can further provide functional housing systems for their long-term
in vitro
maintenance and screening. This minireview summarizes the recent advances in this field and discuss the enormous potential of embedded 3D bioprinting technologies as alternatives for the automated fabrication of more biomimetic
in vitro
models.
This minireview highlights recent advances on the application of embedded 3D bioprinting concepts for the fabrication of
in vitro
models.</abstract><doi>10.1039/d3bm00626c</doi><tpages>12</tpages></addata></record> |
| fulltext | fulltext |
| identifier | ISSN: 2047-4830 |
| ispartof | Biomaterials science, 2023-08, Vol.11 (16), p.5462-5473 |
| issn | 2047-4830 2047-4849 |
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| recordid | cdi_rsc_primary_d3bm00626c |
| source | Royal Society Of Chemistry Journals 2008- |
| title | A dive into the bath: embedded 3D bioprinting of freeform models |
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