Controllable Preparation and in Vitro Bioactivity of Bioglass Microspheres via Spray Drying Method

Yaping HU; Zhengfang TIAN; Min ZHU; Yufang ZHU

doi:10.15541/jim20190621

[1] R JONES J. Review of bioactive glass: From Hench to hybrids. Acta Biomaterialia, 23, S53-S82(2015).

[2] F HULBERT S, L HENCH L, D FORBERS et al. The story of bioceramics. Ceramics International, 8, 131-140(1982).

[3] S FU, H HU, J CHEN et al. Silicone resin derived larnite/C scaffolds via 3D printing for potential tumor therapy and bone regeneration. Chemical Engineering Journal, 382, 122928(2020).

[4] Y FU S, M ZHU, F ZHU Y. Organosilicon polymer-derived ceramics: an overview. Journal of Advanced Ceramics, 8, 457-478(2019).

[5] J ZHANG J, X CHEN, C LIN et al. Preparation of nanoscale bioactive glasses by addition of PEG as surface dispersion agent. Bulletin of the Chinese Ceramic Society, 29, 257-261(2010).

[6] X CHEN, Y MENG, Y LI. Investigation on bio-mineralization of melt and Sol-Gel derived bioactive glasses. Applied Surface Science, 255, 562-564(2008).

[7] P ZHONG J, C GREENSPAN D. Processing and properties of Sol- Gel bioactive glasses. Journal of Biomedical Materical Research, 53, 694-701(2000).

[8] S PAN, J YIN, L YU et al. 2D MXene-integrated 3D-printing scaffolds for augmented osteosarcoma phototherapy and accelerated tissue reconstruction. Advanced Science, 7, 1901551(2020).

[9] X DU, D WEI, L HUANG et al. 3D printing of mesoporous bioactive glass/silk ﬁbroin composite scafolds for bone tissue engineering. Materials Science & Engineering C, 103, 109731(2019).

[10] L PONTIROLI, M DADKHAH, G NOVAJRA et al. An aerosol- spray-assisted approach to produce mesoporous bioactive glass microspheres under mild acidic aqueous conditions. Materials Letters, 190, 111-114(2017).

[11] Y YAMAUCHI, N SUZUKI, P GUPTA et al. Aerosol-assisted synthesis of mesoporous organosilica microspheres with controlled organic contents. Science and Technology of Advanced Materials, 10, 025005-025009(2009).

[12] S FIORILLI, F TALLIA, L Pontiroli et al. Spray-dried mesoprous silica spheres functionalized with carboxylic groups. Materials Letters, 108, 118-121(2013).

[13] J LIU W, D WU W, C SELOMULYA et al. A single step assembly of uniform microparticles for controlled release applications. Soft Matter, 7, 3323(2011).

[14] D WU W, R AMELIA, N HAO et al. Assembly of uniform photoluminescent microcomposites using a novel micro-fluidic-jet- spray-dryer. AIChE Journal, 57, 2726-2737(2011).

[15] R AMELIA, D WU W, J CASHION et al. Microfluidic spray drying as a versatile assembly route of functional particles. Chemical Engineering Science, 66, 5531-5540(2011).

[16] R AMELIA, D WU W, D CHEN X et al. Assembly of magnetic microcomposites from low pH precursors using a novel micro-fluidic-jet-spray-dryer. Chemical Engineering Research & Design, 90, 150-157(2012).

[17] J LIU W, D WU W, C SELOMULYA et al. Facile spray-drying assembly of uniform microencapsulates with tunable core-shell structures and controlled release properties. Langmuir, 27, 12910-12915(2011).

[18] J SHIH S, J Chou Y, B BORISENKO K. Preparation method: structure-bioactivity correlation in mesoporous bioactive glass. Journal of Nanoparticle Research, 15, 1763(2013).

[19] T OSTOMEL, Q SHI, K TSUNG C et al. Spherical bioactive glass with enhanced rates of hydroxyapatite deposition and hemostatic activity. Small, 2, 1261-1265(2006).

[20] D ARCOS, A LOPEZ-NORIEGA, E RUIZ-HERNA NDEZ et al. Ordered mesoporous microspheres for bone grafting and drug delivery. Chemistry of Materials, 21, 1000-1009(2009).

[21] D WU W, J LIU W, C SELOMULYA et al. On spray drying of uniform silica-based microencapsulates for controlled release. Soft Matter, 7, 11416-11424(2011).

[22] T KOKUBO, H TAKADAMA. How useful is SBF in predicting in vivo bone bioactivity?. Biomaterials, 27, 2907-2915(2006).

[23] K MASTERS. Spray Drying Handbook, fifth ed. Harlow: Longman Scientific and Technical, 15, 344-345(1991).

[24] J LAVERNIA E, Y WU. Spray atomization and deposition. Journal of Materials Processing Technology, 278-279(2000).

[25] S NUKIYAMA, Y TANASAWA. Experiments on the atomization of liquids in an airstream. Transactions of the Canadian Society for Mechanical Engineering, S7(1940).

[26] M IDE, E WALLAERT, V DRIESSCHE I et al. Spherical mesopor- ous silica particles by spray drying: doubling the retention factor of HPLC columns. Microporous & Mesoporous Materials, 142, 282-291(2011).

[27] Y FUJITA, T YAMAMURO, T NAKAMURA et al. The bonding behavior of calcite to bone. Journal of Biomedical Materical Research, 25, 991-1003(1991).

[28] A ŚLÓSARCZYK, Z PASZKIEWICZ, C PALUSZKIEWICZ. FTIR and XRD evaluation of carbonated hydroxyapatite powders synthesized by wet methods. Journal of Molecular Structure, 744, 657-661(2005).

[29] L MEYER J, O FOWLER B. Lattice defects in nonstoichiometric calcium hydroxylapatites: a chemical approach. Inorganic Chemistry, 21, 3029-3035(1982).

[30] X MIAO, P TAN L, S TAN L et al. Porous calcium phosphate ceramics modified with PLGA-bioactive glass. Materials Science and Engineering, 27, 274-279(2007).

[31] D RICHARD M, B ALDO R. Effect of particulate bioactive glasses on human macrophages and monocytes in vitro. Journal of Biomedical Materical Research Part A, 73A, 73-79(2005).

[32] G LUTZ-CHRISTIAN, R BOCCACCINI A. Review - bioactive glass and glass-ceramic scaffolds for bone tissue engineering. Materials, 3, 3867-3910(2010).