[1] [1] MAJZOUB J, BAROOTCHI S, TAVELLI L, et al. Guided tissue regeneration combined with bone allograft in infrabony defects: clinical outcomes and assessment of prognostic factors[J]. Journal of Periodontology, 2020, 91(6): 746-755.

[2] [2] HU J, ZENG Y, SHEN C, et al. Mechanism of platelet-rich plasma in promoting bone defect repair[J]. Journal of Biological Regulators and Homeostatic Agents, 2019, 33(1): 97-103.

[6] [6] ZAMARIOLI A, MARANHO D A C, BATTAGLINO R A, et al. Mechanical-loading through passive weigh-bearing and artificial electrical stimulation prevent and even revert sci-induced bone loss quality[J]. Journal of Clinical Densitometry, 2014, 17(3): 403.

[7] [7] TIGUNTA S, PISITPIPATHSIN N, KANTHA P, et al. Electrical properties of calcium phosphate/BZT bioglass-ceramics prepared by incorporation method[J]. Ferroelectrics, 2014, 459(1): 188-194.

[8] [8] TKACHENKO S S, MUSSA M, RUTSKII V V. Electrical stimulation of artificial ossification of a muscle flap during plastic repair of a bone defect[J]. Bulletin of Experimental Biology and Medicine, 1978, 85(3): 384-386.

[9] [9] KUMAR V, SARKAR K, BAVYA DEVI K, et al. Quantitative assessment of degradation, cytocompatibility, and in vivo bone regeneration of silicon-incorporated magnesium phosphate bioceramics[J]. Journal of Materials Research, 2019, 34(24): 4024-4036.

[12] [12] CHEN F Y, WANG M L, WANG J, et al. Effects of hydroxyapatite surface nano/micro-structure on osteoclast formation and activity[J]. Journal of Materials Chemistry B, 2019, 7(47): 7574-7587.

[13] [13] BAXTER F R, TURNER I G, BOWEN C R, et al. An in vitro study of electrically active hydroxyapatite-barium titanate ceramics using Saos-2 cells[J]. Journal of Materials Science Materials in Medicine, 2009, 20(8): 1697-1708.

[14] [14] FENG J Q. Promotion of osteogenesis by a piezoelectric biological ceramic[J]. Biomaterials, 1997, 18(23): 1531-1534.

[15] [15] LU D Y, GAO X L, WANG S. Abnormal Curie-temperature shift in Ho-doped BaTiO3 ceramics with the self-compensation mode[J]. Results in Physics, 2019, 12: 585-591.

[16] [16] WANG D K, DONG S M, ZHOU H J, et al. Effect of pyrolytic carbon interface on the properties of 3D C/ZrC-SiC composites fabricated by reactive melt infiltration[J]. Ceramics International, 2016, 42(8): 10272-10278.

[19] [19] RUAN S L, WEI S Y, GONG W Z, et al. Strengthening, toughening, and self-healing for carbon fiber/epoxy composites based on PPESK electrospun coaxial nanofibers[J]. Journal of Applied Polymer Science, 2021, 138(12): 50063.

[20] [20] CLABEL H J L, AWAN I T, RIVERA V A G, et al. Growth process and grain boundary defects in Er doped BaTiO3 processed by EB-PVD: a study by XRD, FTIR, SEM and AFM[J]. Applied Surface Science, 2019, 493: 982-993.

[22] [22] BAI H, LI J, HONG Y, et al. Enhanced ferroelectricity and magnetism of quenched (1-x)BiFeO3-xBaTiO3 ceramics[J]. Journal of Advanced Ceramics, 2020, 9(4): 511-516.

[23] [23] MINOMURA S, KAWAKUBO T, NAKAGAWA T, et al. Pressure dependence of curie point and tetragonal-orthorhombic transition point of BaTiO3[J]. Japanese Journal of Applied Physics, 1964, 3(9): 562-563.

[25] [25] WANG H X, ZHANG H, GOTO K, et al. Stress mapping reveals extrinsic toughening of brittle carbon fiber in polymer matrix[J]. Science and Technology of Advanced Materials, 2020, 21(1): 267-277.

[26] [26] YIN H, ZHANG M J, AN R F, et al. Diosgenin derivatives as potential antitumor agents: synthesis, cytotoxicity, and mechanism of action[J]. Journal of Natural Products, 2021, 84(3): 616-629.

[27] [27] ARAB-AHMADI S, IRANI S, BAKHSHI H, et al. Immobilization of carboxymethyl chitosan/laponite on polycaprolactone nanofibers as osteoinductive bone scaffolds[J]. Polymers for Advanced Technologies, 2021, 32(2): 755-765.