[1] Avakian P, Gardner KH, Matheson RR. A comment on crystallization in PEKK and PEEK resins [J] . Polymer Sci Part C: Polym Lett, 1990, 28(8)∶243-246 [2] Kurtz SM. PEEK Biomaterials Handbook [M] .UK: Elsevier Inc, 2012.49-60 [3] Urwyler P, Zhao X, Pascual A, et al. Tailoring surface nanostructures on polyaryletherketones for load-bearing implants [J] . Eur J Nanomed, 2014, 6(1)∶37-46 [4] 孙永周.开展我国聚醚酮酮研究的建议[J] .塑料工业,1990,(2)∶25-31 [5] Cortés LQ, Caussé N, Dantras E, et al. Morphology and dynamical mechanical properties of poly ether ketone ketone (PEKK) with meta phenyl links [J] . J Appl Polym Sci, 2016, 133(19)∶1-10 [6] 李云龙,孙丰春,贾远超,等.高性能材料聚醚酮酮的生产、应用[J] .塑料工业,2012,40(5)∶11-12 [7] MatWeb, Overview of materials for PEKK, Unreinforced [DB/OL] . http://www.matweb.com/ [8] MatWeb, Overview of materials for PEKK, Reinforced [DB/OL] . http://www.matweb.com/ [9] 赵信义.口腔材料学[M] .第5版.北京: 人民卫生出版社,2012.44-46,93 [10] Currey JD. The structure and mechanics of bone [J] . J Mater Sci, 2012, 47(1)∶41-54 [11] Chang IY. PEKK as a new thermoplastic matrix for high-performance composites [J] . SAMPE Q, 1988, 19:4(4)∶29-34 [12] Kewekordes T, Wille S, Kern M. Wear of polyetherketoneketone (PEKK) caused by different antagonists [J] . Dent Mater, 2014, 30∶e77-e77 [13] Guenther J, Wong M, Sue HJ, et al. High-temperature steam-treatment of PBI, PEKK, and a PEKK-PBI Blend: A solid-state NMR and IR spectroscopic study [J] . J Appl Polym Sci, 2013, 128(6)∶4395-4404 [14] Pope JC, Sue HJ, Bremner T, et al. High-temperature steam-treatment of PBI, PEEK, and PEKK polymers with H2O and D2O: A solid-state NMR study [J] . Polymer, 2014, 55(18)∶4577- 4585 [15] Damestani Y, Galan-Hoffman DE, Ortiz D, et al. Inflammatory response to implantation of transparent nanocrystalline yttria-stabilized zirconia using a dorsal window chamber model [J] . Nanomed: Nanotechnol Biol Med, 2016, 12(7)∶1757-1763 [16] Moore R,Beredjiklian P,Rhoad R,et al. A comparison of the inflammatory potential of particulates derived from two composite materials [J] . J Biomed Mater Res,1997,34(2)∶137-147 [17] Wang M, Bhardwaj G, Webster TJ. Antibacterial properties of PEKK for orthopedic applications [J] . Int J Nanomed, 2017, 12∶6471-6476 [18] Alsadon O. Evaluating PolyEtherKetoneKetone (PEKK) Polymer used for fabricating Fixed Prosthodontics [D] . University of Sheffield, 2017 [19] Alsadon O, Wood D, Patrick D, et al. Structural integrity of poly-ether-ketone-ketone (PEKK) based bi-layered molar crowns [C] . British Society for Oral & Dental Research, 2015 [20] Bae SY, Park JY, Jeong ID, et al. Three-dimensional analysis of marginal and internal fit of copings fabricated with polyetherketoneketone (PEKK) and zirconia [J] . J Prosthet Dent, 2016, 61(2)∶106-112 [21] Alsadon O, Wood D, Patrick D, et al. Evaluation of the optical properties of PEKK based restorations[C] . IADR/AADR/CADR General Session & Exhibition-Boston, Massachusetts, USA, 2015 [22] Lee KS, Shin JH, Kim JE, et al. Biomechanical evaluation of a tooth restored with high performance polymer PEKK post-core system: a 3D finite element analysis [J] . BioMed Res Int, 2017, 2017(2)∶1373127 [23] Han KH, Lee JY, Shin SW. Implant- and tooth-supported fixed prostheses using a high-performance polymer (pekkton) framework [J] . Int J Prosthodont, 2016, 29(5)∶451-454 [24] Passia N, Ghazal M, Kern M. Long-term retention behaviour of resin matrix attachment systems for overdentures [J] . J Mech Behav Biomed Mater, 2016, 57∶88-94 [25] Tannous F, Steiner M, Shahin R, et al. Retentive forces and fatigue resistance of thermoplastic resin clasps [J] . Dent Mater, 2012, 28(3)∶273-278 [26] Fuhrmann G, Steiner M, Freitag-Wolf S, et al. Resin bonding to three types of polyaryletherketones (PAEKs)-durability and influence of surface conditioning [J] . Dent Mater, 2014, 30(3)∶357-363 [27] Michael Molitch-Hou. Putting PEKK in the 3D Printing Spotlight with Oxford Performance Materials [EB/OL] .http://www.engineering.com/3DPrinting/3DPrintingArticles/ArticleID/14762/Putting-PEKK-in-the-3D-printing-spotlight-with-oxford-performance-materials.aspx [28] Yuan B, Chen Y, Lin H, et al. Processing and properties of bioactive surface-porous PEKK [J] . ACS Biomater Sci Eng, 2016, 2(6)∶977-986 [29] Converse GL, Conrad TL, Roeder RK. Mechanical properties of hydroxyapatite whisker reinforced polyetherketoneketone composite scaffolds [J] . J Mech Behav Biomed Mater, 2009, 2(6)∶627-635 [30] Adamzyk C, Kachel P, Hoss M, et al. Bone tissue engineering using polyetherketoneketone scaffolds combined with autologous mesenchymal stem cells in a sheep calvarial defect model [J] . J Craniomaxillofac Surg, 2016, 44(8)∶985-994 [31] Lyons FG, Almunajjed AA, Kieran SM, et al. The healing of bony defects by cell-free collagen-based scaffolds compared to stem cell-seeded tissue engineered constructs [J] . Biomaterials, 2010, 31(35)∶9232-9243 [32] Roskies MG, Fang D, Abdallah M, et al. Three-dimensionally printed polyetherketoneketone scaffolds with mesenchymal stem cells for the reconstruction of critical-sized mandibular defects [J] . Laryngoscope, 2017,127(11):E392-E398 [33] Van der Stok J, Van der Jagt OP, Amin Yavari S, et al. Selective laser melting-produced porous titanium scaffolds regenerate bone in critical size cortical bone defects [J] . J Orthop Res, 2013, 31(5)∶792-799 [34] Bose S, Vahabzadeh S, Bandyopadhyay A. Bone tissue engineering using 3D printing [J] . Materials Today, 2013, 16(12)∶496-504 [35] Landy BC, Vangordon SB, Mcfetridge PS, et al. Mechanical and in vitro investigation of a porous PEEK foam for medical device implants [J] . J Appl Biomater Funct Mater, 2013, 11(1)∶35-44 [36] Baino F, Vitale-Brovarone C. Mechanical properties and reliability of glass-ceramic foam scaffolds for bone repair [J] . Mater Lett, 2014, 118(3)∶27-30 |