Static Compressive Behavior and Failure Mechanism of Tantalum Scaffolds with Optimized Periodic Lattice Fabricated by Laser-Based Additive Manufacturing

Hairui Gao; Jingzhou Yang; Xia Jin; Dachen Zhang; Shupei Zhang; Faqiang Zhang; Haishen Chen

doi:10.1089/3dp.2021.0253

Static Compressive Behavior and Failure Mechanism of Tantalum Scaffolds with Optimized Periodic Lattice Fabricated by Laser-Based Additive Manufacturing

3D Print Addit Manuf. 2023 Oct 1;10(5):887-904. doi: 10.1089/3dp.2021.0253. Epub 2023 Oct 10.

Authors

Hairui Gao¹, Jingzhou Yang^{1

2

3}, Xia Jin^{1

4}, Dachen Zhang^{2

3}, Shupei Zhang^{2

3}, Faqiang Zhang¹, Haishen Chen^{2

3}

Affiliations

¹ School of Mechanical & Automobile Engineering, Qingdao University of Technology, Qingdao, P.R. China.
² Shenzhen Dazhou Medical Technology Co., Ltd., Shenzhen, P.R. China.
³ Center of Biomedical Materials 3D Printing, National Engineering Laboratory for Polymer Complex Structure Additive Manufacturing, Baoding, P.R. China.
⁴ Key Lab of Industrial Fluid Energy Conservation and Pollution Control, Ministry of Education, Qingdao, P.R. China.

PMID: 37886405
PMCID: PMC10599431 (available on 2024-10-01)
DOI: 10.1089/3dp.2021.0253

Abstract

Porous tantalum (Ta) scaffolds have been extensively used in the clinic for reconstructing bone tissues owing to their outstanding corrosion resistance, biocompatibility, osteointegration, osteoconductivity, and mechanical properties. Additive manufacturing (AM) has an advantage in fabricating patient-specific and anatomical-shape-matching bone implants with controllable and well-designed porous architectures through tissue engineering. The sharp angles of strut joints in porous structures can cause stress concentration, reducing mechanical properties of the structures. In this study, porous Ta scaffolds comprising rhombic dodecahedron lattice unit cells with optimized node radius and porosities of 65%, 75%, and 85% were designed and fabricated by AM. The porous architecture and microstructure were characterized. The compressive behavior and failure mechanism of the material were explored through experimental compression tests and finite element analysis (FEA). Morphological evaluations revealed that the Ta scaffolds are fully interconnected, and the struts are dense. No processing defects and fractures were observed on the surface of struts. The scaffolds exhibited compressive yield strength of 5.8-32.3 MPa and elastic modulus of 0.6-4.5 GPa, comparable to those of human cancellous and trabecular bone. The compressive stress-strain curves of all samples show ductile deformation behavior accompanied by a smooth plateau region. The AM-fabricated rhombic dodecahedron lattice Ta scaffolds exhibited excellent ductility and mechanical reliability and plastic failure due to bending deformation under compressive loading. Deformation and factures primarily occurred at the junctions of the rhombus-arranged struts in the longitudinal section. Moreover, the struts in the middle of the scaffolds underwent a larger deformation than those close to the loading ends. FEA revealed a smooth stress distribution on the rhombic dodecahedron lattice structure with optimized node radius and stress concentration at the junctions of rhombus-arranged struts in the longitudinal section, which is in good agreement with the experimental results. Thus, the AM-fabricated Ta scaffolds with optimized node radius are promising alternatives for bone repair and regeneration.

Keywords: additive manufacturing; compressive behavior; finite element analysis; node optimization; tantalum scaffold.