AI Article Synopsis
- Bone tissue is a composite material made of cells and a highly mineralized matrix, making it difficult to replicate due to its complex structure.
- COBICS is a new bioprinting method that uses a microgel to accurately reproduce bone’s mineral and cellular characteristics without needing extra support materials or intense post-processing.
- This technique employs a calcium phosphate-based ink in a gelatin suspension, allowing for precise construction of bone-like materials that can be tailored in both structure and timing for practical clinical applications.
Article Abstract
Structurally, bone tissue is an inorganic-organic composite containing metabolically active cells embedded within a hierarchical, highly mineralized matrix. This organization is challenging to replicate due to the heterogeneous environment of bone. Ceramic omnidirectional bioprinting in cell-suspensions (COBICS) is a microgel-based bioprinting technique that uniquely replicates the mineral and cellular structure of bone. COBICS prints complex, biologically relevant constructs without the need for sacrificial support materials or harsh postprocessing steps (e.g., radiation and high-temperature sintering), which are two of the biggest challenges in the additive manufacturing of bone mimetic constructs. This technique is enabled via the freeform extrusion of a novel calcium phosphate-based ink within a gelatin-based microgel suspension. The yield-stress properties of the suspension allow deposition and support the printed bone structure. UV crosslinking and nanoprecipitation then "lock" it in place. The ability to print nanostructured bone-mimetic ceramics within cell-laden biomaterials provides spatiotemporal control over macro- and micro-architecture and facilitates the real-time fabrication of complex bone constructs in clinical settings.
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| http://dx.doi.org/10.3791/63943 | DOI Listing |
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