期刊
JOURNAL OF THE MECHANICAL BEHAVIOR OF BIOMEDICAL MATERIALS
卷 134, 期 -, 页码 -出版社
ELSEVIER
DOI: 10.1016/j.jmbbm.2022.105418
关键词
3D bioprinting; Bone defects; Nonlinear finite element analysis; Computational fluid dynamics simulation; Permeability analysis
资金
- Engineering and Physical Sciences Research Council (EPSRC) of the UK
- Global Challenges Research Fund (GCRF) [EP/R015139/1]
Treatment of bone defects is challenging, and synthetic bone scaffolds with suitable mechanical and biological properties are highly sought after. This study presents 3D printed polymeric scaffolds with a continuous ZigZag-Spiral pattern, which have uniform pore size distribution and show better mechanical and mass transportation properties compared to conventional scaffold patterns. Human mesenchymal stem cells seeded on the scaffolds demonstrate gradual pore filling in the ZigZag-Spiral pattern, suggesting its potential as a better choice for bone defect treatments.
Bone defect treatment is still a challenge in clinics, and synthetic bone scaffolds with adequate mechanical and biological properties are highly needed. Adequate waste and nutrient exchange of the implanted scaffold with the surrounded tissue is a major concern. Moreover, the risk of mechanical instability in the defect area during regular activity increases as the defect size increases. Thus, scaffolds with better mass transportation and mechanical properties are desired. This study introduces 3D printed polymeric scaffolds with a continuous pattern, ZigZag-Spiral pattern, for bone defects treatments. This pattern has a uniform distribution of pore size, which leads to uniform distribution of wall shear stress which is crucial for uniform differentiation of cells attached to the scaffolds. The mechanical, mass transportation, and biological properties of the 3D printed scaffolds are evaluated. The results show that the presented scaffolds have permeability similar to natural bone and, with the same porosity level, have higher mechanical properties than scaffolds with conventional lay-down patterns 0-90 degrees and 0-45 degrees. Finally, human mesenchymal stem cells are seeded on the scaffolds to determine the effects of geometrical microstructure on cell attachment and morphology. The results show that cells in scaffold with ZigZag-Spiral pattern infilled pores gradually, while the other patterns need more time to fill the pores. Considering mechanical, transportation, and biological properties of the considered patterns, scaffolds with ZigZag-Spiral patterns can mimic the properties of cancellous bones and be a better choice for treatments of bone defects.
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