Conference Tools for 2024 TMS Annual Meeting & Exhibition

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About this Abstract
Meeting	2024 TMS Annual Meeting & Exhibition
Symposium	Advances in Biomaterials for 3D Printing of Scaffolds and Tissues
Presentation Title	Bioink Formulations for 3D Printing of Tissue Scaffolds: A Review of Materials and Printability
Author(s)	Faithfulness O. Osazee, Andrew O Ohifuemen, Jeffery I. Omoruyi, Ikhazuagbe Hilary Ifijen, Godfrey Otabor
On-Site Speaker (Planned)	Ikhazuagbe Hilary Ifijen
Abstract Scope	The remarkable potential of 3D bioprinting in tissue engineering and regenerative medicine hinges on the development of bioink formulations that guide the creation of intricate and functional tissue constructs. This review encapsulates the pivotal role of bioinks in this dynamic field, elucidating key insights and findings. Bioink diversity, ranging from natural biomaterials to synthetic polymers, underpins the versatility and complexity achievable in bioprinting. Achieving accurate 3D bioprinting necessitates a deep comprehension of printability factors encompassing rheological properties, cross-linking mechanisms, and extrudability. Strategies enhancing bioink printability through additives and bioactive agents are emerging, offering avenues for elevating construct precision and functionality. Tailoring bioink formulations to specific tissue types further fosters tissue-specific differentiation and improved construct functionality. This review underscores the profound significance of bioink formulations as the bedrock of tissue engineering advancement, bridging scientific exploration with transformative solutions for medical practice. As the evolution of bioink formulations continues, the horizon for 3D bioprinting in regenerative medicine remains boundless, promising a future where tissues and organs are tailor-made for healing and restoration.
Proceedings Inclusion?	Planned:
Keywords	Biomaterials, Sustainability, Other

OTHER PAPERS PLANNED FOR THIS SYMPOSIUM

3D Printing and Growing Fungal Tissue in Ambient Environment and Properties

3D Printing of Multiscale Human Tissue and Organ Equivalents

Bioabsorbable PLDL/Mg-wire Composites Manufactured by Fused Filament Fabrication for Tissue Engineering

Biodegradable Polymers for 3D Printing of Tissue Engineering Scaffolds: Challenges and Future Directions

Bioink Formulations for 3D Printing of Tissue Scaffolds: A Review of Materials and Printability

Design and Optimization of a 3D-printed Bioreactor for Long-term Ex-vivo Bone Tissue Culture

Effects of Post-printing Cell Distribution on Cell Viability and Proliferation in Inkjet-based Bioprinting of Vascular Structures

Engineering Polymeric BioInks for 3D Printing

Filaments Made of Magnesium-incorporated Polymer for Potential Use in Bone Implants

Graphene and MXene Nanomaterial Bioinks for Improvement of 3D Bioprinted Tissue Engineering

H-2: 3D Printable Bioscaffolds for Musculoskeletal Tissue Engineering using Ti_3 C_2 MXene Nanoparticles to Enhance Conductivity and Improve Cell Viability

Improving Predictability of Additively Manufactured Ti-6Al-4V Lattices for Customised Orthopaedic Devices

Improving Structural Integrity of a Bioinspired Structures through 3D Printing for Advancing Bone Tissue Engineering

Migration Behavior of Invasive and Non-invasive Breast Cancer Cells on a Graded Micropillar Surface

Structure-property Relationships in Solvent-cast 3D-printed Polymeric Biomaterials

The Influence of Iso-value on 3D-printed Sheet TPMS Ti6Al4V Scaffolds’ Mechanical Responses

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