• Journal of Inorganic Materials
  • Vol. 38, Issue 7, 830 (2023)
Wei WU1、2, Shahd BAKHET2, Naomi Addai ASANTE2, Shefiu KAREEM2, Omar Ramadhan KOMBO3, Binbin LI2, and Honglian DAI1、2、*
Author Affiliations
  • 11. Shenzhen Institute of Wuhan University of Technology, Shenzhen 518000, China
  • 22. State Key Laboratory of Advanced Technology for Materials Synthesis and Processing, Biomedical Materials and Engineering Research Center of Hubei Province, Wuhan University of Technology, Wuhan 430070, China
  • 33. Department of Medical Science and Technology, Mbeya University of Science and Technology, Mbeya, Tanzania
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    DOI: 10.15541/jim20220662 Cite this Article
    Wei WU, Shahd BAKHET, Naomi Addai ASANTE, Shefiu KAREEM, Omar Ramadhan KOMBO, Binbin LI, Honglian DAI. In vitro Study of Biphasic Calcium Magnesium Phosphate Microspheres for Angiogenesis and Bone Formation [J]. Journal of Inorganic Materials, 2023, 38(7): 830 Copy Citation Text show less
    References

    [1] K NARITA, E KOBAYASHI, TJMT SATO. Sintering behavior and mechanical properties of magnesium/β-tricalcium phosphate composites sintered by spark plasma sintering. Materials Transactions, 1620(2016).

    [2] M CHUTHATHIP, M N AHMAD-FAUZI, B I YANNY-MARLIANA et al. Effect of magnesium oxide on physical and biological properties in β-tricalcium phosphate ceramic. Journal of Physics Conference Series, 012026(2018).

    [3] S BASU, B BASU. Doped biphasic calcium phosphate: synthesis and structure. Journal of Asian Ceramic Societies, 265(2019).

    [4] C D GHIȚULICĂ, A CUCURUZ, G VOICU et al. Ceramics based on calcium phosphates substituted with magnesium ions for bone regeneration. International Journal of Applied Ceramic Technology, 342(2020).

    [5] K MAJI, S DASGUPTA. Effect of β-tricalcium phosphate nanoparticles additions on the properties of gelatin-chitosan scaffolds. Bioceramics Development & Applications, 1000103(2017).

    [6] S MURAKAMI, H MIYAJI, E NISHIDA et al. Dose effects of beta-tricalcium phosphate nanoparticles on biocompatibility and bone conductive ability of three-dimensional collagen scaffolds. Dental Materials Journal, 573(2017).

    [7] Z Z FANG. Sintering of advanced materials, 85.

    [8] I KAUR, L J ELLIS, I ROMER et al. Dispersion of nanomaterials in aqueous media: towards protocol optimization. Journal of Visualized Experiments, e56074(2017).

    [9] W XUE, K DAHLQUIST, A BANERJEE et al. Synthesis and characterization of tricalcium phosphate with Zn and Mg based dopants. Journal of Materials Science: Materials in Medicine, 2669(2008).

    [10] X GUO, Y LONG, W LI et al. Osteogenic effects of magnesium substitution in nano-structured β-tricalcium phosphate produced by microwave synthesis. Journal of Materials Science, 11197(2019).

    [11] N ELIAZ, N J M METOKI. Calcium phosphate bioceramics: a review of their history, structure, properties, coating technologies and biomedical applications. Materials, 334(2017).

    [12] R R RAO, H N ROOPA, T S KANNAN. Solid state synthesis and thermal stability of HAP and HAP-β-TCP composite ceramic powders. Journal of Materials Science: Materials in Medicine, 511(1997).

    [13] C RUIZ-AGUILAR, U OLIVARES-PINTO, E A AGUILAR-REYES et al. Characterization of β-tricalcium phosphate powders synthesized by Sol-Gel and mechanosynthesis. Boletín de la Sociedad Española de Cerámica y Vidrio, 213(2018).

    [14] J ANDO. Tricalcium phosphate and its variation. Bulletin of the Chemical Society of Japan, 196(1958).

    [15] M OLSSON. Chemical stability of grain boundariesinβ-tricalcium phosphate ceramics: β-TCP as bone substitute material. Department of Chemistry-Ångström, 42586904(2012).

    [16] VM SGLAVO, M FRASNELLI. Effect of Mg2+ doping on beta- alpha phase transition in tricalcium phosphate (TCP) bioceramics. Acta Biomaterialia, 283(2016).

    [17] Y MA, H DAI, X HUANG et al. 3D printing of bioglass-reinforced β-TCP porous bioceramic scaffolds. Journal of Materials Science, 10437(2019).

    [18] M GALLO, B L G SANTONI, T DOUILLARD et al. Effect of grain orientation and magnesium doping on β-tricalcium phosphate resorption behavior. Acta Biomaterialia, 391(2019).

    [19] D D S TAVARES, L D O CASTRO, G D D A SOARES et al. Synthesis and cytotoxicity evaluation of granular magnesium substituted β-tricalcium phosphate. Journal of Applied Oral Science, 37(2013).

    [20] D LEE, C SFEIR, P N J M S KUMTA et al. Novel in-situ synthesis and characterization of nanostructured magnesium substituted β-tricalcium phosphate (β-TCMP). Materials Science, 69(2009).

    [21] J MARCHI, A DANTAS, P GREIL et al. Influence of Mg-substitution on the physicochemical properties of calcium phosphate powders. Materials Research Bulletin, 1040(2007).

    [22] H-S RYU, KS HONG, J-K LEE et al. Magnesia-doped HA/β-TCP ceramics and evaluation of their biocompatibility. Biomaterials, 393(2004).

    [23] X ZHANG, F JIANG, T GROTH et al. Preparation, characterization and mechanical performance of dense β-TCP ceramics with/ without magnesium substitution. Journal of Materials Science: Materials in Medicine, 3063(2008).

    [24] K ONUMA, M J C IIJIMA. Nanoparticles in β-tricalcium phosphate substrate enhance modulation of structure and composition of an octacalcium phosphate grown layer. CrystEngComm, 6660(2017).

    [25] M S SADER, R Z LEGEROS, G A SOARES. Human osteoblasts adhesion and proliferation on magnesium-substituted tricalcium phosphate dense tablets. Journal of Materials Science: Materials in Medicine, 521(2009).

    [26] L C LIN, S J CHANG, S M KUO et al. Preparation and evaluation of β-TCP/polylactide microspheres as osteogenesis materials. Journal of Applied Polymer Science, 3210(2008).

    [27] Z YUAN, P WEI, Y HUANG et al. Injectable PLGA microspheres with tunable magnesium ion release for promoting bone regeneration. Acta Biomaterialia., 294(2019).

    [28] J WANG, J XU, C HOPKINS et al. Biodegradable magnesium ased implants in orthopedics: a general review and perspectives. Advanced Science, 201902443(2020).

    [29] S LIN, G YANG, F JIANG et al. Bone regeneration: a magnesiumnriched 3D culture system that mimics the bone development microenvironment for vascularized bone regeneration. Advanced Science, 1900209(2019).

    [30] C PAN, X SUN, G XU et al. The effects of β-TCP on mechanical properties, corrosion behavior and biocompatibility of beta- TCP/Zn-Mg composites. Materials Science & Engineering C, 110397(2020).

    [31] H ZHANG, Y SHEN, Y XIONG et al. Microstructural, mechanical properties and strengthening mechanism of DLP produced β-tricalcium phosphate scaffolds by incorporation of MgO/ZnO/58S bioglass. Ceramics International, 25863(2021).

    [32] J ZHANG, L TANG, H QI et al. Dual function of magnesium in bone biomineralization. Advanced Healthcare Materials, 1901030(2019).

    [33] X LIN, J GE, D WEI et al. Surface degradation-enabled osseointegrative, angiogenic and antiinfective properties of magnesium- modified acrylic bone cement. Journal of Orthopaedic Translation., 121(2019).

    [34] F HE, Y TIAN, X FANG et al. Porous calcium phosphate composite bioceramic beads. Ceramics International, 13430(2018).

    [35] V H HO, G TRIPATHI, J GWON et al. Novel TOCNF reinforced injectable alginate/β-tricalcium phosphate microspheres for bone regeneration. Materials & Design, 108892(2020).

    [36] M MURAKAMI, L T NGUYEN, K HATANAKA et al. FGF-dependent regulation of VEGF receptor 2 expression in mice. The Journal of Clinical Investigation, 2668(2011).

    [37] R OLIVARES-NAVARRETE, S L HYZY, R A GITTENS et al. Rough titanium alloys regulate osteoblast production of angiogenic factors. The Spine Journal, 1563(2013).

    [38] P N MATKAR, R ARIYAGUNARAJAH, H LEONG-POI et al. Friends turned foes: angiogenic growth factors beyond angiogenesis. Biomolecules, 74(2017).

    [39] S M CHIM, J TICKNER, S T CHOW et al. Angiogenic factors in bone local environment. Cytokine Growth Factor Reviews, 297(2013).

    [40] A W TAN, L L LIAU, K H CHUA et al. Enhanced in vitro angiogenic behaviour of human umbilical vein endothelial cells on thermally oxidized TiO2 nanofibrous surfaces. Scientific Reports, 21828(2016).

    [41] M PRZYBYLSKI. A review of the current research on the role of bFGF and VEGF in angiogenesis. Journal of Wound Care, 516(2009).

    [42] Y CHEN, Y OU, J DONG et al. Osteopontin promotes collagen I synthesis in hepatic stellate cells by miRNA-129-5p inhibition. Experimental Cell Research, 343(2017).

    [43] B BHASKAR, R OWEN, H BAHMAEE et al. Composite porous scaffold of PEG/PLA support improved bone matrix deposition in vitro compared to PLA-only scaffolds. Journal of Biomedical Research Part A, 1334(2018).

    Wei WU, Shahd BAKHET, Naomi Addai ASANTE, Shefiu KAREEM, Omar Ramadhan KOMBO, Binbin LI, Honglian DAI. In vitro Study of Biphasic Calcium Magnesium Phosphate Microspheres for Angiogenesis and Bone Formation [J]. Journal of Inorganic Materials, 2023, 38(7): 830
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