Design and Additive Manufacturing of Acetabular Implant with Continuously Graded Porosity

Design and Additive Manufacturing of Acetabular Implant with Continuously Graded Porosity

Porous structured metallic implants are preferable as bone graft substitutes due to their faster tissue integration mediated by bone in-growth and vascularization. The porous scaffolds/implants should also mimic the graded structure of natural bone to ensure a match of mechanical properties. This ar...

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Bibliographic Details
Published in:Bioengineering (Basel) Vol. 10; no. 6; p. 675
Main Authors: Mukherjee, Sumanta, Dhara, Santanu, Saha, Partha
Format: Journal Article
Language:English
Published: Switzerland MDPI AG 01-06-2023
MDPI
Subjects:
3D printing
Acetabular components
acetabular cup
Acetabulum
Additive manufacturing
Bioengineering
Bone grafts
Bone growth
Bone implants
CAD
Cancellous bone
Compression
Computed tomography
Computer aided design
Crack propagation
DMLS
Geodesic domes
graded porosity
Grafting
Image processing
Laser sintering
Manufacturing
Mathematical models
Mechanical loading
Mechanical properties
Methods
Optimization
Orthopedic equipment and supplies
Orthopedics
Parameter identification
Pore size
Porosity
Process parameters
Production processes
Scanning
Sintering (powder metallurgy)
Stiffness
Struts
Substitute bone
Surface roughness
Ti6Al4V
Tissue engineering
Transplants & implants
Vascularization
India
DMLS
acetabular cup
additive manufacturing
graded porosity
Ti6Al4V
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Summary:Porous structured metallic implants are preferable as bone graft substitutes due to their faster tissue integration mediated by bone in-growth and vascularization. The porous scaffolds/implants should also mimic the graded structure of natural bone to ensure a match of mechanical properties. This article presents a method for designing a graded porous structured acetabular implant and identifies suitable parameters for manufacturing the model through additive manufacturing. The design method is based on slice-wise modification to ensure continuity of gradation. Modification of the slices was achieved through the binary image processing route. A geodesic dome-type design was adopted for developing the acetabular cup model from the graded porous structure. The model had a solid shell with the target porosity and pore size gradually changing from 65% and 950 µm, respectively, in the inner side to 75% and 650 µm, respectively, towards the periphery. The required dimensions of the unit structures and the combinations of pore structure and strut diameter necessary to obtain the target porosity and pore size were determined analytically. Suitable process parameters were identified to manufacture the model by Direct Metal Laser Sintering (DMLS) using Ti6Al4V powder after carrying out a detailed experimental study to minimize the variation of surface roughness and warping over different build angles of the strut structures. Dual-contour scanning was implemented to simplify the scan strategy. The minimum diameter of struts that could be manufactured using the selected scanning strategy and scanning parameters was found to be 375 µm. Finally, the model was built and from the micro-CT data, the porosities and pore sizes were found to be closely conforming to the designed values. The stiffness of the structures, as found from compression testing, was also found to match with that of human trabecular bone well. Further, the structure exhibited compliant bending-dominated behaviour under compressive loading.
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ISSN:2306-5354
2306-5354
DOI:10.3390/bioengineering10060675