[1] GEORGAKILAS V, TIWARI J N, KEMP K C et al. Noncovalent functionalization of graphene and graphene oxide for energy materials, biosensing, catalytic, and ciomedical applications[J]. Chemical Reviews, 116, 5464-5519(2016).

[2] HABRAKEN W, HABIBOVIC P, EPPLE M et al. Calcium phosphates in biomedical applications: materials for the future?[J]. Materials Today, 19, 69-87(2016).

[3] LIN K L, WU C T, CHANG J. Advances in synthesis of calcium phosphate crystals with controlled size and shape[J]. Acta Biomaterialia, 10, 4071-4102(2014).

[4] WANG X L, REN Z M, CHANG J. Synthesis and orientation of Fe-doped hydroxyapatite in high magnetic field[J]. Journal of Inorganic Materials, 33, 75-80(2018).

[5] ZHANG B, YANG C A, SHI P. Synthesis of graphene/ hydroxyapatite composite bioceramics via plasma Activated sintering,[J]. Journal of Inorganic Materials, 33, 1355-1359(2018).

[6] WU C T, CHANG J. Silicate bioceramics for bone tissue regeneration[J]. Journal of Inorganic Materials, 28, 29-39(2013).

[7] DONG S, CHEN Y, YU L et al. Magnetic hyperthermia- synergistic H₂O₂ self-sufficient catalytic suppression of osteosarcoma with enhanced bone-regeneration bioactivity by 3D-printing composite scaffolds[J]. Advanced Functional Materials, 30, 1907071-1-15(2019).

[8] SHI Z Y, LI Q, TANG S C et al. Surface modification on property of mesoporous calcium magnesium silicate/polyetheretherketone composites[J]. Journal of Inorganic Materials, 33, 67-74(2018).

[9] BAI F, WANG Z, LU J et al. The correlation between the internal structure and vascularization of controllable porous bioceramic aterials in vivo: a quantitative study[J]. Tissue Engineering Part A, 16, 3791-3803(2010).

[10] LIN K L, CHANG J, ZENG Y et al. Preparation of macroporous calcium silicate ceramics[J]. Materials Letters, 58, 2109-2113(2004).

[11] BAINO F, FIUME E, BARBERI J et al. Processing methods for making porous bioactive glass-based scaffolds-a state-of-the-art review[J]. International Journal of Applied Ceramic Technology, 16, 1762-1796(2019).

[12] XIN C, QI X, ZHU M et al. Hydroxyapatite whisker-reinforced composite scaffolds through 3D printing for bone repair[J]. Journal of Inorganic Materials, 32, 837-844(2017).

[13] MA H, FENG C, CHANG J et al. 3D-printed bioceramic scaffolds: from bone tissue engineering to tumor therapy[J]. Acta Biomaterialia, 79, 37-59(2018).

[14] VON ERLACH T C, BERTAZZO S, WOZNIAK M A et al. Cell-geometry-dependent changes in plasma membrane order direct stem cell signalling and fate[J]. Nature Materials, 17, 237-242(2018).

[15] ROGOWSKA-TYLMAN J, LOCS J, SALMA I et al. In vivo and in vitro study of a novel nanohydroxyapatite sonocoated scaffolds for enhanced bone regeneration[J]. Materials Science & Engineering: C, 99, 669-684(2019).

[16] YANG B W, YIN J H, CHEN Y et al. 2D-black-phosphorus- reinforced 3D-printed scaffolds: a stepwise countermeasure for osteosarcoma[J]. Advanced Materials, 30, 1705611-1-12(2018).

[17] ZHANG Y L, ZHAI D, XU M C et al. 3D-printed bioceramic scaffolds with antibacterial and osteogenic activity[J]. Biofabrication, 9, 025037-1-12(2017).

[18] ZHANG X, LI H, LIU J et al. Amorphous carbon modification on implant surface: a general strategy to enhance osteogenic differentiation for diverse biomaterials via FAK/ERK1/2 signaling pathways[J]. Journal of Materials Chemistry B, 7, 2518-2533(2019).

[19] TOURI M, MOZTARZADEH F, OSMAN N A A et al. 3D- printed biphasic calcium phosphate scaffolds coated with an oxygen generating system for enhancing engineered tissue survival[J]. Materials Science and Engineering: C, 84, 236-242(2018).

[20] WANG C, LIN K, CHANG J et al. Osteogenesis and angiogenesis induced by porous beta-CaSiO₃/PDLGA composite scaffold via activation of AMPK/ERK1/2 and PI3K/Akt pathways[J]. Biomaterials, 34, 64-77(2013).

[21] LIN K, XIA L, GAN J et al. Tailoring the nanostructured surfaces of hydroxyapatite bioceramics to promote protein adsorption, osteoblast growth, and osteogenic differentiation[J]. ACS Applied Materials & Interfaces, 5, 8008-8017(2013).

[22] ZHAO C, XIA L, ZHAI D et al. Designing ordered micropatterned hydroxyapatite bioceramics to promote the growth and osteogenic differentiation of bone marrow stromal cells[J]. Journal of Materials Chemistry B, 3, 968-976(2015).

[23] MAO L, LIU J, ZHAO J et al. Effect of micro-nano-hybrid structured hydroxyapatite bioceramics on osteogenic and cementogenic differentiation of human periodontal ligament stem cell via Wnt signaling pathway[J]. International Journal of Nanomedicine, 10, 7031-7044(2015).

[24] XIA L, LIN K, JIANG X et al. Effect of nano-structured bioceramic surface on osteogenic differentiation of adipose derived stem cells[J]. Biomaterials, 35, 8514-8527(2014).

[25] WANG X, ZHOU Y, XIA L et al. Fabrication of nano-structured calcium silicate coatings with enhanced stability, bioactivity and osteogenic and angiogenic activity[J]. Colloids and Surfaces B-Biointerfaces, 126, 358-366(2015).

[26] XIA L, XIE Y, FANG B et al. In situ modulation of crystallinity and nano-structures to enhance the stability and osseointegration of hydroxyapatite coatings on Ti-6Al-4V implants[J]. Chemical Engineering Journal, 347, 711-720(2018).

[27] XIA L, ZHANG N, WANG X et al. The synergetic effect of nano-structures and silicon-substitution on the properties of hydroxyapatite scaffolds for bone regeneration[J]. Journal of Materials Chemistry B, 4, 3313-3323(2016).

[28] DENG C J, LIN R C, ZHANG M et al. Micro/nanometer- structured scaffolds for regeneration of both cartilage and subchondral bone[J]. Advanced Functional Materials, 29, 1806068-15(2019).

[29] YANG C, WANG X Y, MA B et al. 3D-printed bioactive Ca₃SiO₅ bone cement scaffolds with nano surface structure for bone regeneration[J]. ACS Applied Materials & Interfaces, 9, 5757-5767(2017).

[30] WANG X C, LI T, MA H S et al. A 3D-printed scaffold with MoS₂ nanosheets for tumor therapy and tissue regeneration[J]. NPG Asia Materials, 9, e376-1-14(2017).

[31] XIA L, LIN K, JIANG X et al. Enhanced osteogenesis through nano-structured surface design of macroporous hydroxyapatite bioceramic scaffolds via activation of ERK and p38 MAPK signaling pathways[J]. Journal of Materials Chemistry B, 1, 5403-5416(2013).

[32] DONG S, ZHANG Y-N, WANG J et al. A novel multifunctional carbon aerogel coated platform for osteosarcoma therapy and enhanced bone regeneration[J]. Journal of Materials Chemistry B, 8, 368-379(2020).

[33] WANG C, LIN K, CHANG J et al. The stimulation of osteogenic differentiation of mesenchymal stem cells and vascular endothelial growth factor secretion of endothelial cells by beta-CaSiO₃/beta- Ca₃(PO₄)(2) scaffolds[J]. Journal of Biomedical Materials Research Part A, 102, 2096-2104(2014).

[34] WITTE F, KAESE V, HAFERKAMP H et al. In vivo corrosion of four magnesium alloys and the associated bone response[J]. Biomaterials, 26, 3557-3563(2005).

[35] YOSHIZAWA S, BROWN A, BARCHOWSKY A et al. Magnesium ion stimulation of bone marrow stromal cells enhances osteogenic activity, simulating the effect of magnesium alloy degradation[J]. Acta Biomaterialia, 10, 2834-2842(2014).

[36] XIA L, YIN Z, MAO L et al. Akermanite bioceramics promote osteogenesis,angiogenesis and suppress osteoclastogenesis for osteoporotic bone regeneration[J]. Scientific Reports, 6, 22005- 1-17(2016).

[37] AMIN N, CLARK C C T, TAGHIZADEH M et al. Zinc supplements and bone health: the role of the RANKL-RANK axis as a therapeutic target[J]. Journal of Trace Elements in Medicine and Biology(2019). https://www.ncbi.nlm.nih.gov/pubmed/32634767

[38] QIAO Y Q, ZHANG W J, TIAN P et al. Stimulation of bone growth following zinc incorporation into biomaterials[J]. Biomaterials, 35, 6882-6897(2014).

[39] LIN K L, XIA L G, LI H Y et al. Enhanced osteoporotic bone regeneration by strontium-substituted calcium silicate bioactive ceramics[J]. Biomaterials, 34, 10028-10042(2013).

[40] LIU W, WANG T, YANG C et al. Alkaline biodegradable implants for osteoporotic bone defects-importance of microenvironment pH[J]. Osteoporosis International, 27, 93-104(2016).

[41] GUO X, WEI S, LU M et al. Dose-dependent effects of strontium ranelate on ovariectomy rat bone marrow mesenchymal stem cells and human umbilical vein endothelial cells[J]. International Journal of Biological Sciences, 12, 1511-1522(2016).

[42] GUO X, WEI S, LU M et al. RNA-Seq investigation and in vivo study the effect of strontium ranelate on ovariectomized rat via the involvement of ROCK1[J]. Artificial Cells Nanomedicine and Biotechnology, 46, S629-S641(2018).

[43] LIN K, WANG X, ZHANG N et al. Strontium (Sr) strengthens the silicon (Si) upon osteoblast proliferation, osteogenic differentiation and angiogenic factor expression[J]. Journal of Materials Chemistry B, 4, 3632-3638(2016).

[44] WANG C Y, CHEN B, WANG W et al. Strontium released bi-lineage scaffolds with immunomodulatory properties induce a pro-regenerative environment for osteochondral regeneration[J]. Materials Science & Engineering: C, 103, 109833-1-12(2019).

[45] ZHANG X, LI H, LIN C et al. Synergetic topography and chemistry cues guiding osteogenic differentiation in bone marrow stromal cells through ERK1/2 and p38 MAPK signaling pathway[J]. Biomaterials Science, 6, 418-430(2018).

[46] FIELDING G, BOSE S. SiO₂ and ZnO dopants in three- dimensionally printed tricalcium phosphate bone tissue engineering scaffolds enhance osteogenesis and angiogenesis in vivo[J]. Acta Biomaterialia, 9, 9137-9148(2013).

[47] WU C, ZHAI D, MA H et al. Stimulation of osteogenic and angiogenic ability of cells on polymers by pulsed laser deposition of uniform akermanite-glass nanolayer[J]. Acta Biomaterialia, 10, 3295-3306(2014).

[48] KONG N, LIN K, LI H et al. Synergy effects of copper and silicon ions on stimulation of vascularization by copper-doped calcium silicate[J]. Journal of Materials Chemistry B, 2, 1100-1110(2014).

[49] SHI M C, CHEN Z T, FARNAGHI S et al. Copper-doped mesoporous silica nanospheres, a promising immunomodulatory agent for inducing osteogenesis[J]. Acta Biomaterialia, 30, 334-344(2016).

[50] LI J Y, ZHAI D, LV F et al. Preparation of copper-containing bioactive glass/eggshell membrane nanocomposites for improving angiogenesis, antibacterial activity and wound healing[J]. Acta Biomaterialia, 36, 254-266(2016).

[51] LI H, LI J Y, JIANG J et al. An osteogenesis/angiogenesis- stimulation artificial ligament for anterior cruciate ligament reconstruction[J]. Acta Biomaterialia, 54, 399-410(2017).

[52] ZHOU Y H, HAN S W, XIAO L et al. Accelerated host angiogenesis and immune responses by ion release from mesoporous bioactive glass[J]. Journal of Materials Chemistry B, 6, 3274-3284(2018).

[53] LIN R C, DENG C J, LI X X et al. Copper-incorporated bioactive glass-ceramics inducing anti-inflammatory phenotype and regeneration of cartilage/bone interface[J]. Theranostics, 9, 6300-6313(2019).

[54] DANG W T, WANG X Y, LI J Y et al. 3D printing of Mo- containing scaffolds with activated anabolic responses and bi-lineage bioactivities[J]. Theranostics, 8, 4372-4392(2018).

[55] LIU Y Q, LI T, MA H S et al. 3D-printed scaffolds with bioactive elements-induced photothermal effect for bone tumor therapy[J]. Acta Biomaterialia, 73, 531-546(2018).

[56] MEININGER S, MANDAL S, KUMAR A et al. Strength reliability and in vitro degradation of three-dimensional powder printed strontium-substituted magnesium phosphate scaffolds[J]. Acta Biomaterialia, 31, 401-411(2016).

[57] MEININGER S, MOSEKE C, SPATZ K et al. Effect of strontium substitution on the material properties and osteogenic potential of 3D powder printed magnesium phosphate scaffolds[J]. Materials Science and Engineering: C, 98, 1145-1158(2019).

[58] XIE J, SHAO H, HE D et al. Ultrahigh strength of three- dimensional printed diluted magnesium doping wollastonite porous scaffolds[J]. MRS Communications, 5, 631-639(2015).

[59] KE X, ZHANG L, YANG X et al. Low-melt bioactive glass- reinforced 3D printing akermanite porous cages with highly improved mechanical properties for lumbar spinal fusion[J]. J Tissue Eng. Regen. Med., 12, 1149-1162(2018).

[60] FU S Y, YU B, DING H F et al. Zirconia incorporation in 3D printed beta-Ca₂SiO₄ scaffolds on their physicochemical and biological property[J]. Journal of Inorganic Materials, 34, 444-454(2019).

[61] ZHANG F, CHANG J, LU J et al. Bioinspired structure of bioceramics for bone regeneration in load-bearing sites[J]. Acta Biomaterialia, 3, 896-904(2007).

[62] FENG C, ZHANG W, DENG C et al. 3D Printing of lotus root-like biomimetic materials for cell delivery and tissue regeneration[J]. Advanced Science, 4, 1700401-1-9(2017).

[63] ALMELA T, BROOK I M, KHOSHROO K et al. Simulation of cortico-cancellous bone structure by 3D printing of bilayer calcium phosphate-based scaffolds[J]. Bioprinting, 6, 1-7(2017).

[64] JUNG-BIN L, WOO-YOUL M, YOUNG-HAG K et al. Porous calcium phosphate ceramic scaffolds with tailored pore orientations and mechanical properties using lithography-based ceramic 3D printing technique[J]. Materials, 11, 1711-1718.

[65] MATHARU G S, DANIEL J, ZIAEE H et al. Failure of a novel ceramic-on-ceramic hip resurfacing prosthesis[J]. Journal of Arthroplasty, 30, 416-418(2015).

[66] MANNY P, JAVAD P, SHARKEY P F et al. Causes of failure of ceramic-on-ceramic and metal-on-metal hip arthroplasties[J]. Clinical Orthopaedics & Related Research, 470, 382-387(2012).

[67] ZHAO L, WU C T, LIN K L et al. The effect of poly(lactic-co- glycolic acid)(PLGA) coating on the mechanical, biodegradable, bioactive properties and drug release of porous calcium silicate scaffolds[J]. Bio-medical Materials and Engineering, 22, 289-300(2012).

[68] LI CHEN, AI FANRONG, MIAO XINXIN et al. “The return of ceramic implants”: rose stem inspired dual layered modification of ceramic scaffolds with improved mechanical and anti-infective properties[J]. Materials Science and Engineering: C, 93, 873-879(2018).

[69] KIM B S, YANG S S, PARK H et al. Improvement of mechanical strength and osteogenic potential of calcium sulfate-based hydroxyapatite 3-dimensional printed scaffolds by epsilon- polycarbonate coating. Journal of[J]. Biomaterials Science-Polymer Edition, 28, 1256-1270(2017).

[70] DíAZ-RODRíGUEZ P, GONZáLEZ P, SERRA J et al. Key parameters in blood-surface interactions of 3D bioinspired ceramic materials[J]. Materials Science and Engineering: C, 41, 232-239(2014).

[71] LIENEMANN P S, LUTOLF M P, MARTIN E. Biomimetic hydrogels for controlled biomolecule delivery to augment bone regeneration[J]. Advanced Drug Delivery Reviews, 64, 1078-1089(2012).

[72] LI M, CHENG Y, ZHENG Y F et al. Surface characteristics and corrosion behaviour of WE43 magnesium alloy coated by SiC film[J]. Applied Surface Science., 258, 3074-3081(2012).

[73] YANG Y, LAI Y, ZHANG Q et al. A novel electrochemical strategy for improving blood compatibility of titanium-based biomaterials[J]. Colloids & Surfaces B Biointerfaces, 79, 309-313(2010).

[74] ZHAO L, LIN K L, ZHANG M L et al. The influences of poly(lactic-co-glycolic acid) (PLGA) coating on the biodegradability, bioactivity, and biocompatibility of calcium silicate bioceramics[J]. Journal of Materials Science, 46, 4986-4993(2011).

[75] WEI T, DANG-SHENG X. Bioinspired superhydrophobic progress and recent advances of its functional application[J]. Journal of Inorganic Materials, 34, 1133-1144(2019).

[76] ARIMA Y, IWATA H. Effect of wettability and surface functional groups on protein adsorption and cell adhesion using well-defined mixed self-assembled monolayers[J]. Biomaterials, 28, 3074-3082(2007).

[77] TENG Y Q, ZHANG Y Q, HENG L P et al. Conductive polymer porous film with tunable wettability and adhesion[J]. Materials, 8, 1817-1830(2015).

[78] CHEN Z, ZHANG D, PENG E et al. 3D-printed ceramic structures with in situ grown whiskers for effective oil/water separation[J]. Chemical Engineering Journal, 373, 1223-1232(2019).

[79] SONG Y, LIN K, HE S et al. Nano-biphasic calcium phosphate/polyvinyl alcohol composites with enhanced bioactivity for bone repair via low-temperature three-dimensional printing and loading with platelet-rich fibrin[J]. International Journal of Nanomedicine, 13, 505-523(2018).

[80] TROMBETTA R, INZANA J A, SCHWARZ E M et al. 3D printing of calcium phosphate ceramics for bone tissue engineering and drug delivery[J]. Annals of Biomedical Engineering, 45, 1-22(2017).

[81] BOSE S, VAHABZADEH S, BANDYOPADHYAY A. Bone tissue engineering using 3D printing[J]. Materials Today, 16, 496-504(2013).

[82] ZHANG Y L, ZHAI D, XU M C et al. 3D-printed bioceramic scaffolds with a Fe₃O₄/graphene oxide nanocomposite interface for hyperthermia therapy of bone tumor cells[J]. Journal of Materials Chemistry B, 4, 2874-2886(2016).

[83] TORRES P M C, VIEIRA S I, CERQUEIRA A R et al. Effects of Mn-doping on the structure and biological properties of β-tricalcium phosphate[J]. Journal of Inorganic Biochemistry, 136, 57-66(2014).

[84] MIN Z, SHICHANG Z, CHEN X et al. 3D-printed dimethyloxallyl glycine delivery scaffolds to improve angiogenesis and osteogenesis[J]. Biomater. Sci., 3, 1236-1244(2015).

[85] DIAZ-RODRIGUEZ P, SANCHEZ M, LANDIN M. Drug-loaded biomimetic ceramics for tissue engineering[J]. Pharmaceutics, 10, 272-1-20(2018).

[86] MEIßNER R, BERTOL L, REHMAN M A U et al. Bioprinted 3D calcium phosphate scaffolds with gentamicin releasing capability[J]. Ceramics International, 45, 7090-7094(2019).

[87] LI T, ZHAI D, MA B et al. 3D printing of hot dog-like biomaterials with hierarchical architecture and distinct bioactivity[J]. Advanced Science, 6, 1901146-8(2019).

[88] SONG J-J, CHEN B, LIN K-L. Core-shell structured hydroxyapatite/mesoporous silica nanoparticle: preparation and application in drug delivery[J]. Journal of Inorganic Materials, 33, 623-628(2018).

[89] CHEN G, ROY I, YANG C et al. Nanochemistry and nanomedicine for nanoparticle-based diagnostics and therapy[J]. Chemical Reviews, 116, 2826-2885(2016).

[90] ZHEN F, YAN C, CUI C et al. Near infrared fluorescent peptide nanoparticles for enhancing esophageal cancer therapeutic efficacy[J]. Nature Communications, 9, 2605-1-11(2018).

[91] WANG S, CHEN Y, LI X et al. Injectable 2D MoS₂-integrated drug delivering implant for highly efficient NIR-triggered synergistic tumor hyperthermia[J]. Advanced Materials, 27, 7117-7122(2015).

[92] CHANDRAWATI D R, CHANG D J Y H, REINATORRES D E et al. Localized and controlled delivery of nitric oxide to the conventional outflow pathway via enzyme biocatalysis: toward therapy for glaucoma[J]. Advanced Materials, 29, 1604932-1-7(2017).

[93] BADGWELL B, BLUM M, ESTRELLA J et al. Personalised therapy for localised gastric and gastro-oesophageal adenocarcinoma[J]. Lancet Oncology, 17, 1628-1629(2016).

[94] YANG B W, GU Z, CHEN Y. Nanomedicine-augmented cancer-localized treatment by 3D theranostic implants[J]. Journal of Biomedical Nanotechnology, 13, 871-890(2017).

[95] MA H, JIANG C, ZHAI D et al. A bifunctional biomaterial with photothermal effect for tumor therapy and bone regeneration[J]. Advanced Functional Materials, 26, 1197-1208(2016).

[96] WU P, GRAINGER D W. Drug/device combinations for local drug therapies and infection prophylaxis[J]. Biomaterials, 27, 2450-2467(2006).

[97] ARIJIT KUMAR C, RUCHIRA C, TARAKDAS B. Mechanism of antibacterial activity of copper nanoparticles[J]. Nanotechnology, 25, 135101-1-13(2014).

[98] SCHRAND A M, RAHMAN M F, HUSSAIN S M et al. Metal-based nanoparticles and their toxicity assessment[J]. Wiley Interdisciplinary Reviews: Nanomedicine and Nanobiotechnology, 2, 544-568(2010).

[99] LIAO F, MA J Q, GE H G. Preparation, characterization and antimicrobial activity of core-satellite Ag/PDA@SiO₂@CoFe₂O₄ magnetic composites[J]. Journal of Inorganic Materials, 32, 523-528(2017).

[100] LIU Y L, WANG R L, LI N et al. Preparation of zinc oxide mesocrystal filler and the properties of dental composite resins[J]. Journal of Inorganic Materials, 34, 1077-1084(2019).

[101] WANG Q, TANG P F, GE X et al. Experimental and simulation studies of strontium/zinc-codoped hydroxyapatite porous scaffolds with excellent osteoinductivity and antibacterial activity[J]. Applied Surface Science, 462, 118-126(2018).

[102] VALAPPIL S P, COOMBES M, WRIGHT L et al. Role of gallium and silver from phosphate-based glasses on in vitro dual species oral biofilm models of porphyromonas gingivalis and Streptococcus gordonii[J]. Acta Biomaterialia, 8, 1957-1965(2012).

[103] GOH Y F, ALSHEMARY A Z, AKRAM M et al. In-vitro characterization of antibacterial bioactive glass containing ceria[J]. Ceramics International, 40, 729-737(2014).

[104] CHATZISTAVROU X, FENNO J C, FAULK D et al. Fabrication and characterization of bioactive and antibacterial composites for dental applications[J]. Acta Biomaterialia, 10, 3723-3732(2014).

[105] BRAUER D S, KARPUKHINA N, KEDIA G et al. Bactericidal strontium-releasing injectable bone cements based on bioactive glasses[J]. Journal of the Royal Society Interface, 10, 20120647-1-8(2013).

[106] WU Y, XIA L, ZHOU Y et al. Evaluation of osteogenesis and angiogenesis of icariin loaded on micro/nano hybrid structured hydroxyapatite granules as a local drug delivery system for femoral defect repair[J]. Journal of Materials Chemistry B, 3, 4871-4883(2015).

[107] ZHOU Y, WU Y, MA W et al. The effect of quercetin delivery system on osteogenesis and angiogenesis under osteoporotic conditions[J]. Journal of Materials Chemistry B, 5, 612-625(2017).

[108] ZHANG F M, CHANG J, LIN K L et al. Preparation, mechanical properties and in vitro degradability of wollastonite/tricalcium phosphate macroporous scaffolds from nanocomposite powders. Journal of Materials Science-Materials in[J]. Medicine, 19, 167-173(2008).

[109] ZHANG F, LIN K, CHANG J et al. Spark plasma sintering of macroporous calcium phosphate scaffolds from nanocrystalline powders[J]. Journal of The European Ceramic Society, 28, 539-545(2008).