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Manuscript ID : ASCIJ-2302-1472 Visit : 230 Page: 131 - 145

10.22034/ascij.2023.1981349.1472

Article Type: Original Research

Evaluation of the Potential of 3D Printed Polycaprolactone Scaffolds Coated with Bioceramics in the Proliferation and Osteogenic Differentiation of Human Adipose Tissue-derived Mesenchymal Stem Cells

Subject Areas : Journal of Animal Biology

Nasrin Fazeli 1 , Ehsan Arefian 2 , Shiva Irani 3 , Abdolreza Ardeshirylajimi 4 , Ehsan Seyedjafari 5

1 - Department of Biology, Faculty of Convergent Technologies, Science and Research Unit, Islamic Azad University, Tehran, Iran
2 - Department of Microbiology, Faculty of Biology, Science Campus, University of Tehran, Tehran, Iran
3 - Department of Biology, Faculty of Convergent Technologies, Science and Research Unit, Islamic Azad University, Tehran, Iran
4 - Urogenital Stem Cell Research Center, Shahid Beheshti University of Medical Sciences, Tehran, Iran
5 - Department of Biotechnology, Science Campus, University of Tehran, Tehran, Iran

Received: 2023-02-27 Accepted : 2023-04-30 Published : 2023-11-22

Keywords: hydroxyapatite, Tissue Engineering, Polycaprolactone, 3D Printing, Bioactive Glasses,

Abstract :

In recent years, the focus of researches in the field of tissue engineering has been on the preparation of scaffold materials and methods. 3D printing is an emerging technology that can accurately and quickly prepare bone tissue engineering scaffolds with specific shapes and structures. One of the most common 3D printing methods is fused deposition modeling (FDM), the materials used in this method are polymers such as polycaprolactone (PCL). In this study, 3D printed PCL scaffolds were made and due to the hydrophobic and non-osteogenic nature of PCL, the surface of the scaffolds was coated with a 1% solution of hydroxyapatite (HA) and bioactive glass (BG) bioceramics. Surface modification of PCL scaffolds was done to increase hydrophilicity and improve cell attachment. Field emission scanning electron microscop (FeSEM) images, Energy-dispersive X-ray spectroscopy (EDS) and mapping of the surface elements of the scaffolds confirmed the proper coating of PCL scaffolds with HA and BG bioceramics. The biocompatibility of PCL/HA/BG scaffolds and the cell viability and attachment on the surface of the scaffolds were investigated by seeding of human adipose mesenchymal stem cells (hAMSCs) and using MTT test and FeSEM images. Also, the potential of PCL/HA/BG scaffolds in osteogenic differentiation of hAMSCs was evaluated by alkaline phosphatase activity measurement test and immunocytochemical staining. The results showed that the three-component PCL/HA/BG scaffolds improved the proliferation and osteogenic differentiation of hAMSCs, so the PCL/HA/BG scaffolds can be a suitable candidate for bone tissue engineering applications.

References:


  1. Ardeshirylajimi A.; Farhadian S.; Jamshidi Adegani F.; Mirzaei S.; Soufi Zomorrod, M.; Langroudi, L.; Doostmohammadi A.; Seyedjafari, E.; Soleimani, M. 2015. Enhanced osteoconductivity of polyethersulphone nanofibres loaded with bioactive glass nanoparticles in in vitro and in vivo models. Cell Prolif., 48(4):455-464.
    2.
  2. Billiet, T.; Gevaert, E.; De Schryver, T.; Cornelissen, M.; Dubruel, P. 2014. The 3D printing of gelatin methacrylamide cell-laden tissue-engineered constructs with high cell viability. Biomaterials, 35(1):49-62.
    3.
  3. Chocholata, P.; Kulda, V.; Babuska, V. 2019. Fabrication of scaffolds for bone-tissue regeneration. Materials, 12(4):568.
    4.
  4. Distler, T.; Fournier, N.; Grünewald, A.; Polley, C.; Seitz, H.; Detsch, R.; Boccaccini, A. R. 2020. Polymer-bioactive glass composite filaments for 3D scaffold manufacturing by fused deposition modeling: fabrication and characterization. Frontiers in bioengineering and biotechnology, 8:552.
    5.
  5. Du, X.; Fu, S.; Zhu, Y. 2018. 3D printing of ceramic-based scaffolds for bone tissue engineering: an overview. Journal of Materials Chemistry B, 6(27):4397-4412.
    6.
  6. Ebrahimi, Z.; Irani, S.; Ardeshirylajimi, A.; Seyedjafari, E. 2022. Enhanced osteogenic differentiation of stem cells by 3D printed PCL scaffolds coated with collagen and hydroxyapatite. Rep., 12(1):1-15.
    7.
  7. Eltorai, A. E.; Nguyen, E.; Daniels, A. H. 2015. Three-dimensional printing in orthopedic surgery. Orthopedics, 38(11): 684-687.
    8.
  8. Feng, X.; Wu, Y.; Bao, F.; Chen, X.; Gong, J. 2019. Comparison of 3D-printed mesoporous calcium silicate/polycaprolactone and mesoporous Bioacive glass/polycaprolactone scaffolds for bone regeneration. Microporous Mesoporous Mater., 278: 348-353.
    9.
  9. Gao, G.; Schilling, A. F.; Yonezawa, T.; Wang, J.; Dai, G.; Cui, X. 2014. Bioactive nanoparticles stimulate bone tissue formation in bioprinted three‐dimensional scaffold and human mesenchymal stem cells. J., 9 (10): 1304-1311.
    10.
  10. Gerhardt, L.-C.; Boccaccini, A. R. 2010. Bioactive glass and glass-ceramic scaffolds for bone tissue engineering. Materials, 3 (7): 3867-3910.
    11.
  11. Grémare, A.; Guduric, V.; Bareille, R.; Heroguez, V.; Latour, S.; L'heureux, N.; Fricain, J. C.; Catros, S.; Le Nihouannen, D. 2018. Characterization of printed PLA scaffolds for bone tissue engineering. Journal of Biomedical Materials Research Part A, 106(4):887-894.
    12.
  12. Guarino, V.; Ambrosio, L. 2010. Temperature-driven processing techniques for manufacturing fully interconnected porous scaffolds in bone tissue engineering. Proceedings of the Institution of Mechanical Engineers, Part H: Journal of Engineering in Medicine, 224(12):1389-1400.
    13.
  13. Jaidev, L.; Chatterjee, K. 2019. Surface functionalization of 3D printed polymer scaffolds to augment stem cell response. Materials & Design, 161: 44-54.
    14.
  14. Jang, J.-H.; Castano, O.; Kim, H.-W. 2009. Electrospun materials as potential platforms for bone tissue engineering. Drug Del. Rev., 61(12):1065-1083.
    15.
  15. Jensen, J.; Rölfing, J. H. D.; Svend Le, D. Q.; Kristiansen, A. A.; Nygaard, J. V.; Hokland, L. B.; Bendtsen, M.; Kassem, M.; Lysdahl, H.; Bünger, C. E. 2014. Surface‐modified functionalized polycaprolactone scaffolds for bone repair: In vitro and in vivo experiments. Journal of biomedical materials research Part A, 102(9):2993-3003.
    16.
  16. Karimi, Z.; Seyedjafari, E.; Mahdavi, F. S.; Hashemi, S. M.; Khojasteh, A.; Kazemi, B.; Mohammadi‐Yeganeh, S. 2019. Baghdadite nanoparticle‐coated poly l‐lactic acid (PLLA) ceramics scaffold improved osteogenic differentiation of adipose tissue‐derived mesenchymal stem cells. Journal of Biomedical Materials Research Part A, 107(6):1284-1293.
    17.
  17. Kim, J. W.; Lee, Y.; Seo, J.; Park, J. H.; Seo, Y. M.; Kim, S. S.; Shon, H. C. 2018. Clinical experience with three-dimensional printing techniques in orthopedic trauma. Orthop. Sci., 23(2):383-388.
    18.
  18. Kumar, G.; Tison, C. K.; Chatterjee, K.; Pine, P. S.; McDaniel, J. H.; Salit, M. L.; Young, M. F.; Simon Jr, C. G. 2011. The determination of stem cell fate by 3D scaffold structures through the control of cell shape. Biomaterials, 32(35):9188-9196.
    19.
  19. Lee, S. J.; Lee, D.; Yoon, T. R.; Kim, H. K.; Jo, H. H.; Park, J. S.; Lee, J. H.; Kim, W. D.; Kwon, I. K.; Park, S. A. 2016. Surface modification of 3D-printed porous scaffolds via mussel-inspired polydopamine and effective immobilization of rhBMP-2 to promote osteogenic differentiation for bone tissue engineering. Acta Biomater., 40:182-191.
    20.
  20. Li, C.; Liu, D.; Zhang, Z.; Wang, G.; Xu, N. 2013. Triple point-mutants of hypoxia-inducible factor-1α accelerate in vivo angiogenesis in bone defect regions. Cell Biochem. Biophys., 67:557-566.
    21.
  21. Ma, J.; Lin, L.; Zuo, Y.; Zou, Q.; Ren, X.; Li, J.; Li, Y. 2019. Modification of 3D printed PCL scaffolds by PVAc and HA to enhance cytocompatibility and osteogenesis. RSC advances, 9(10):5338-5346.
    22.
  22. Mondal, S.; Nguyen, T. P.; Hoang, G.; Manivasagan, P.; Kim, M. H.; Nam, S. Y.; Oh, J. 2020. Hydroxyapatite nano bioceramics optimized 3D printed poly lactic acid scaffold for bone tissue engineering application. Int., 46(3): 3443-3455.
    23.
  23. Seebach, C.; Henrich, D.; Wilhelm, K.; Barker, J.; Marzi, I. 2012. Endothelial progenitor cells improve directly and indirectly early vascularization of mesenchymal stem cell-driven bone regeneration in a critical bone defect in rats. Cell Transplant., 21(8):1667-1677.
    24.
  24. Shahin-Shamsabadi, A.; Hashemi, A.; Tahriri, M.; Bastami, F.; Salehi, M.; Abbas, F. M. 2018. Mechanical, material, and biological study of a PCL/bioactive glass bone scaffold: Importance of viscoelasticity. Materials Science and Engineering: C, 90: 280-288.
    25.
  25. Sultan, S.; Thomas, N.; Varghese, M.; Dalvi, Y.; Joy, S.; Hall, S.; Mathew, A. P. 2022. The Design of 3D-Printed Polylactic Acid–Bioglass Composite Scaffold: A Potential Implant Material for Bone Tissue Engineering. Molecules, 27(21):7214.
    26.
  26. Wang, C.; Huang, W.; Zhou, Y.; He, L.; He, Z.; Chen, Z.; He, X.; Tian, S.; Liao, J.; Lu, B. 2020. 3D printing of bone tissue engineering scaffolds. Bioactive materials, 5 (1):82-91.
    27.
  27. Wang, Q.; Wang, Q.; Wan, C. 2012. Preparation and evaluation of a biomimetic scaffold with porosity gradients in vitro. Acad. Bras. Cienc., 84:9-16.
    28.
  28. Wang, X.; Yan, Y.; Pan, Y.; Xiong, Z.; Liu, H.; Cheng, J.; Liu, F.; Lin, F.; Wu, R.; Zhang, R. 2006. Generation of three-dimensional hepatocyte/gelatin structures with rapid prototyping system. Tissue Eng., 12(1):83-90.
    29.
  29. Wei, Q.; Wang, Y.; Chai, W.; Zhang, Y.; Chen, X. 2017. Molecular dynamics simulation and experimental study of the bonding properties of polymer binders in 3D powder printed hydroxyapatite bioceramic bone scaffolds. Int., 43(16):13702-13709.
    30.
  30. Xie, L.; Chen, C.; Zhang, Y.; Zheng, W.; Chen, H.; Cai, L. 2018. Three-dimensional printing assisted ORIF versus conventional ORIF for tibial plateau fractures: A systematic review and meta-analysis. International Journal of Surgery, 57:35-44.
    31.
  31. Yuan, Q.; Qin, C.; Wu, J.; Xu, A.; Zhang, Z.; Liao, J.; Lin, S.; Ren, X.; Zhang, P. 2016. Synthesis and characterization of Cerium-doped hydroxyapatite/polylactic acid composite coatings on metal substrates. Materials Chemistry and Physics, 182:365-371.
    32.
  32. Zhang, Q.; Zhou, J.; Zhi, P.; Liu, L.; Liu, C.; Fang, A.; Zhang, Q. 2023. 3D printing method for bone tissue engineering scaffold. Medicine in Novel Technology and Devices: 100205.
    33.
  33. Zimmerling, A.; Yazdanpanah, Z.; Cooper, D. M.; Johnston, J. D.; Chen, X. 2021. 3D printing PCL/nHA bone scaffolds: Exploring the influence of material synthesis techniques. Biomaterials Research, 25(1): 1-12.
    34.
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