Page 386 - IJB-9-2
P. 386
International Journal of Bioprinting 3D gel-printed β-TCP/TiO2 porous scaffolds for cancellous bone tissue engineering
Acknowledgments 5. Meißner R, Bertol L, Rehman MAU, et al., 2019, Bioprinted
3D calcium phosphate scaffolds with gentamicin releasing
None. capability. Ceram Int, 45(6):7090–7094.
Funding 6. Mohan N, Palangadan R, Fernandez FB, et al., 2018,
Preparation of hydroxyapatite porous scaffold from a
This work was supported by Generation method and ‘coral-like’ synthetic inorganic precursor for use as a bone
application verification of personalized rehabilitation substitute and a drug delivery vehicle. Mater Sci Eng C,
prescription for patients with balance (2019YFB1311403); 92:329–337.
Natural Science Foundation of Sichuan Province- 7. Ravanbakhsh H, Luo Z, Zhang X, et al., 2022, Freeform cell-
(23NSFSC5880); Chengdu Medical Research Project laden cryobioprinting for shelf-ready tissue fabrication and
(2022004); Natural Science Foundation of Clinical Medical storage. Matter, 5(2):573–593.
College and Affiliated Hospital of Chengdu University
8. Amini AR, Laurencin CT, Nukavarapu SP, 2012, Bone tissue
Conflict of interest engineering: Recent advances and challenges. Crit Rev
Biomed Eng, 40(5):363-408.
The authors declare no conflict of interest.
9. Salgado AJ, Coutinho OP, Reis RL, 2004, Bone tissue
Author contributions engineering: State of the art and future trends. Macromol
Biosci, 4(8):743–765.
Conceptualization, supervision, investigation, formal 10. Moore WR, Graves SE, Bain GI, 2001, Synthetic bone graft
analysis, writing original draft, writing - Xulin Hu substitutes. ANZ J Surg, 71(6):354–361.
Review and editing - Hu Li
Methodology, writing – review & editing - Liang Qiao, 11. Hu X, Zhao W, Zhang Z, et al., 2023, Novel 3D printed
shape-memory PLLA-TMC/GA-TMC scaffolds for bone
Shuhao Yang tissue engineering with the improved mechanical properties
Writing – review & editing, Investigation - Haoming Wu, and degradability. Chin Chem Lett, 34(1):107451.
Chao Peng
Investigation - Yamei Zhang, Hai Lan, Hua Yang 12. Lu J, Hu X, Yuan T, et al., 2022, 3D-printed poly
Conceptualization, Methodology, Resources - Kainan Li (P-dioxanone) stent for endovascular application: In vitro
evaluations. Polymers, 14(9):1751.
Ethics approval and consent to participate 13. Hu X, Lin Z, He J, et al., 2022, Recent progress in 3D printing
Not applicable. degradable polylactic acid‐based bone repair scaffold for the
application of cancellous bone defect. MedComm Biomater
Consent for publication Appl, 1(1):e14.
14. Ghahsareh ZS, Banijamali S, Aghaei A, 2022, Cerium
All agree to publish.
oxide containing canasite based glass-ceramics for dental
applications: Crystallization behavior, mechanical and
Availability of data chemical properties. Ceram Int, 48(6):8489–8501.
The data presented in this study are available on request 15. Chen Q, Thouas GA, 2015, Metallic implant biomaterials.
from the corresponding author. Mater Sci Eng R, 87:1–57.
References 16. Li Y, Xie K, Wang C, et al., 2021, 3D printing of tricalcium
phosphate/poly lactic-co-glycolic acid scaffolds loaded with
1. Ribas RG, Schatkoski VM, Do Amaral Montanheiro TL, carfilzomib for treating critical-sized rabbit radial bone
et al., 2019, Current advances in bone tissue engineering defects. Int J Bioprint, 7(4):405.
concerning ceramic and bioglass scaffolds: A review. Ceram 17. Zheng C, Attarilar S, Li K, et al., 2021, 3D-printed HA15-
Int, 45(17):21051–21061. loaded β-tricalcium phosphate/poly (lactic-co-glycolic acid)
2. Brunello G, Sivolella S, Meneghello R, et al., 2016, Powder- bone tissue scaffold promotes bone regeneration in rabbit
based 3D printing for bone tissue engineering. Biotechnol radial defects. Int J Bioprint, 7(1):317.
Adv, 34(5):740–753. 18. Ma PX, 2008, Biomimetic materials for tissue engineering.
3. Salhotra A, Shah HN, Levi B, et al., 2020, Mechanisms Adv Drug Delivery Rev, 60(2):184–198.
of bone development and repair. Nat Rev Mol Cell Biol, 19. Srinivasan B, Kolanthai E, Nivethaa E, et al., 2022, Enhanced
21(11):696–711. in vitro inhibition of MCF-7 and magnetic properties of
4. Palmer S, Gibbons C, Athanasou N, 1999, The pathology of cobalt incorporated calcium phosphate (HAp and β-TCP)
bone allograft. J Bone Joint Surg Br, 81(2):333–335. nanoparticles. Ceram Int, 49(1):855–861.
Volume 9 Issue 2 (2023) 378 https://doi.org/10.18063/ijb.v9i2.673
