We developed the "Print and Grow" technology, which entailed embedding living cells within bioinks, extruding them layer by layer into a granular support material, and leaving them in the support material for cultivation to aid post-printing maturation of the tissue. This approach ensured high fidelity and precise fabrication of complex structures, closely mimicking living tissue properties.
A significant part of our work involved the development and optimization of κ-Carrageenan-based microgels (CarGrow). These microgels were engineered to provide mechanical support to the bioprinted constructs, thus enhancing their long-term structural stability. We conducted comprehensive rheological studies on granular hydrogels. By examining different microgel stiffness levels and packing densities, we gained insights into the viscoelastic properties of these materials, critical for their application in bioprinting and tissue cultivation. Upon defining the optimal CarGrow properties we demonstrated its applicability for a broad range of living tissues.
Main Achievements:
1. Overcoming Post-Printing Challenges:
The "Print and Grow" method effectively addressed the nonuniform shrinkage and deformation issues encountered during the post-printing tissue maturation period. This resulted in engineered constructs with predictable size and shape, significantly improving the reliability of 3D bioprinted tissues.
2. Enhanced Cell Viability and Functionality:
Our approach markedly improved cell viability within bioprinted tissues. The CarGrow environment proved conducive to cell growth and differentiation, leading to the development of tissues that were functionally closer to their natural counterparts.
3. Universal Support Material:
We identified CarGrow as a universal support material. This was a crucial finding as it demonstrated CarGrow's compatibility with a wide range of tissues, including adipose, pancreatic, skeletal muscle, and bone tissues, thereby broadening the scope of its application.
4. Live Imaging Capability:
The project also pioneered methods for live imaging within the CarGrow environment. This innovation is significant for real-time monitoring of tissue development and integrity, a critical aspect in the field of tissue engineering.