Periodic Reporting for period 4 - JointPrinting (3D Printing of Cell Laden Biomimetic Materials and Biomolecules for Joint Regeneration)
Período documentado: 2020-03-01 hasta 2020-08-31
The second aim of the project was to develop 3D printed composite implants for large bone defect repair and cartilage repair. To this end we 3D bioprinted implants containing spatiotemporally defined patterns of growth factors optimized for coupled angiogenesis and osteogenesis. Using nanoparticle functionalized bioinks, it was possible to print implants with distinct growth factor patterns and release profiles spanning from days to weeks. The extent of angiogenesis in vivo depended on the spatial presentation of vascular endothelial growth factor (VEGF). Higher levels of vessel invasion were observed in implants containing a spatial gradient of VEGF compared to those homogenously loaded with the same total amount of protein. Printed implants containing a gradient of VEGF, coupled with spatially defined BMP-2 localization and release kinetics, accelerated large bone defect healing with little heterotopic bone formation. This demonstrates the potential of growth factor printing, a putative point of care therapy, for tightly controlled tissue regeneration. This work was published in the journal ‘Science Advances’.
The third and final aim of the project was to scale-up the printed implants developed as part of aims 1 and 2 of the project to enable whole joint regeneration. To this end we have used computational tools to help inform the design of implants that would possess the necessary mechanical properties to perform this function. This work was published in the journal ‘Connective Tissue Research’. Furthermore, we used medical imaging data to produce biological implants that mimic the geometry of different synovial joints. The lessons learned in the pre-clinical evaluation of these implants has informed the development of new 3D bioprinting strategies targeting degenerative joint diseases such as osteoarthritis.
1. Using 3D printing to develop fibre reinforced biomaterials that mimic the mechanical properties of articular cartilage.
2. The development of extracellular matrix (ECM) functionalised bioinks capable of supporting specific stem cell phenotypes.
3. The development of bioinks that can be used to control the release of regulatory factors from 3D printed implants.
4. The development of printed biomaterials containing gradients in regulatory factors that promote rapid vascularization in vivo.
5. The development of printed biological implants that can support vascularization and the regeneration of critically sized bone defects.
6. The development of computational tools to model the mechanical behavior of 3D printed implants.
7. The development of printed biological implants that can enhance the regeneration of osteochondral defects within synovial joints such as the knee.