biomaterials for dental implants: current and future trends

J Dent Res 83:296–301, Shadanbaz S, Dias GJ (2012) Calcium phosphate coatings on magnesium alloys for biomedical applications: a review. Prog Mater Sci 56:1137–1177, de Maeztu MA, Alava JI, Gay-Escoda C (2003) Ion implantation: surface treatment for improving the bone integration of Titanium and Ti6Al4V dental implants. Outlines of the researches that are presently conducted in an endeavor to limit the drawbacks of the current technology are also provided. Eur J Esthet Dent 4:130–151, Willmann Die Bedeutung der ISO norm 6474 fur implantate aus Aluminiumoxid. Polmear IJ (ed) (1981) Titanium alloys. J Am Ceram Soc 85:517–522, Barrère F, Snel M, Van Blitterswijk C, de Groot K, Layrolle P (2004) Nano-scale study of the nucleation and growth of calcium phosphate coating on Titanium implants. Biomaterials 15:5–10, Santos JD, Lakhan JJ, Monteiro FJ (1995) Surface modifications of glass-reinforced hydroxyapatite composites. Int J Oral Maxillofac Implants 5:347–359, Brånemark PI, Zarb GA, Albrektsson T (1985) Tissue-integrated prostheses: osseointegration in clinical dentistry. This is a preview of subscription content, log in to check access. July 2015; Journal of Materials Science 50(14) DOI: 10.1007/s10853-015-9056-3. Cells Tissues Organs 178:13–22, Zhang W, Wang G, Liu Y, Zhao X, Zou D, Zhu C, Jin Y, Huang Q, Sun J, Liu X, Jiang X, Zreiqat H (2013) The synergistic effect of hierarchical micro/nano-topography and bioactive ions for enhanced osseointegration. Int J Immunopathol Pharmacol 22:773–779, Spinelli MS, Maccauro G, Graci C, Cittadini A, Magnani G, Sangiorgi S et al (2011) Zirconia toughened Alumina (ZTA) powders: ultrastuctural and histological analysis. Clin Oral Implant Res 19(8):823–835, Koutayas SO, Vagkopoulou T, Pelekanos S, Koidis P, Strub JR (2009) Zirconia in dentistry. doi:10.1007/s10853-012-6295-4, Roessler S, Born R, Scharnweber D, Worch H, Sewing A, Dard M (2001) Biomimetic coatings functionalized with adhesion peptides for dental implants. Dent Clin North Am 36:97–115, Baltag I, Watanabe K, Kusakari H, Taoyuki N, Miyakawa O, Kobayashi M, Ito N (2000) J Biomed Mater Res Part B. Biomater 53:76–85, Wheeler SL (1996) Eight-year clinical retrospective study of Titanium plasma-sprayed and hydroxyapatite-coated cylinder implants. J Biomed Mater Res A 66:411–416, Wang J, van Apeldoorn A, de Groot K (2006) Electrolytic deposition of calcium phosphate/chitosan coating on Titanium alloy: growth kinetics and influence of current density, acetic acid, and chitosan. Int J Oral Maxillofac Implants 17:811–815, Giavaresi G, Fini M, Cigada A, Chiesa R, Rondelli G, Rimondini L, Torricelli P, Nicoli Aldini N, Giardino R (2003) Mechanical and histomorphometric evaluations of Titanium implants with different surface treatments inserted in sheep cortical bone. Acta Biomater 7:395–405, He Q, Cheng YQ, Ma E, Xu J (2011) Location bulk metallic glasses with high fracture toughness: chemical effects and composition optimization. Int J Oral Maxillofac Implants 14:271–277, Lang NP, Pjetursson BE, Tan K, Brägger U, Egger M, Zwahlen M (2004) A systematic review of the survival and complication rates of fixed partial dentures (FPDs) after an observation period of at least 5 years. Biomaterials 24:1309–1316, Xie Y, Zheng X, Huang L, Ding C (2012) Influence of hierarchical hybrid micro/nano-structured surface on biological performance of titanium coating. Success criteria and epidemiology, Esposito, M; Hirsch, JM; Lekholm, U; Thomsen, P, The long-term efficacy of currently used dental implants: a review and proposed criteria of success, Albrektsson, T; Zarb, G; Worthington, P; Eriksson, AR, Osseointegration: current state of the art, Application of finite element analysis in implant dentistry: a review of the literature, Stress evaluation of implant wall thickness using numerical techniques, Staden, RC; Guan, H; Loo, YC; Johnson, NW; Meredith, N, Implants in dental and maxillofacial surgery, Titanium and titanium alloys as dental materials, Geetha, M; Singh, AK; Muraleedharan, K; Gogia, AK; Asokamani, R, Phase transformation in Ti-Nb-Ta and Ti-Nb-Ta-Zr alloys, Polarization studies of surgical materials in Ringer’s solution, Titanium alloys for biomedical applications, Effect of thermomechanical processing on evolution of various phases in Ti-Nb-Zr alloys, Geetha, M; Singh, AK; Gogia, AK; Asokamani, RJ, Relationships between tensile deformation behavior and microstructure in Ti–Nb–Ta–Zr system alloys, Nobuhito, S; Mitsuo, N; Toshikazu, A; Junji, T; Hiroyuki, T, Corrosion wear fracture of new β type biomedical Titanium alloys, Niinomi, M; Kuroda, D; Fukunaga, KI; Morinaga, M; Kato, Y; Yashiro, T; Suzuki, A, Effect of Ta content on mechanical properties of Ti–30Nb–XTa–5Zr, Phase transformations in Ti–35Nb–7Zr–5Ta–(0.06–0.68)O alloys, Qazi, J; Marquart, B; Allard, LF; Rack, HJ, Formation of TiO2 nano-network on Titanium surface increases the human cell growth, Chiang, CY; Chiou, SH; Yang, WE; Hsu, ML; Yung, MC; Tsai, ML; Chen, LK; Huang, EH, Metal ion release from Titanium with active oxygen species generated by rat macrophages in vitro, Mu, Y; Kobayashi, T; Sumita, M; Yamamoto, A; Hanawa, T, Effect of mechanical surface pretreatment on metal ion release, Bone response to unloaded and loaded Titanium implants with a sandblasted and acid-etched surface: a histometric study in the canine mandible, Cochran, DL; Schenk, RK; Lussi, A; Higginbottom, FL; Buser, D, A histomorphometric evaluation of screw-shaped implants each prepared with two surface roughnesses, Wennerberg, A; Hallgren, C; Johansson, C; Danelli, S, Influence of surface characteristics on bone integration of Titanium implants. In: Saito S (ed) Fine ceramics. J Biomed Mater Res A 76:323–334, Zhao G, Schwartz Z, Wieland M, Rupp F, Geis-Gerstorfer J, Cochran DL, Boyan BD (2005) High surface energy enhances cell response to Titanium substrate microstructure. Clin Implant Dent Relat Res 1:2–9, Malò P, Rangert B, Nobre M (2005) All-on-4 immediate–function concept with Brånemark System implants for completely edentulous maxillae: a 1-year retrospective clinical study. doi:10.1023/A:1018633026519, Josset Y, Oum’Hamed Z, Zarrinpour A, Lorenzato M, Adnet JJ, Laurent-Maquin D (1999) In vitro reactions of human osteoblasts in culture with Zirconia and Alumina ceramics. Part 2: optimization of coating properties. Biomaterials 19:1489–1494, Chevalier J, Gremillard L, Deville S (2007) Low-Temperature Degradation of Zirconia and Implications for Biomedical Implants. J Biomed Mater Res B 100:1044–1052, Nakahara I, Takao M, Goto T, Ohtsuki C, Hibino S, Sugano N (2012) Interfacial shearstrength of bioactive-coated carbon fiber reinforced polyetheretherketone after in vivo implantation. Clin Oral Implants Res 18:481–488, Schwarz F, Herten M, Sager M, Wieland M, Dard M, Becker J (2007) Bone regeneration in dehiscence-type defects at chemically modified (SLActive®) and conventional SLA Titanium implants: a pilot study in dogs. A gene expression study using real-time RT-PCR, Pegueroles, M; Aguirre, A; Engel, E; Pavon, G; Gil, FJ; Planell, JA; Migonney, V; Aparicio, C, Acceleration of apatite nucleation on microrough bioactive Titanium for bone-replacing implants, Aparicio, C; Manero, JM; Conde, F; Pegueroles, M; Planell, JA; Vallet-Regí, M; Gil, FJ, Variation of roughness and adhesion strength of deposited apatite layers on Titanium dental implants, Growth of bioactive surfaces on Titanium and its alloys for orthopaedic and dental implants, Interface shear strength of Titanium implants with a sandblasted and acid-etched surface: a biomechanical study in the maxilla of miniature pigs, Buser, D; Nydegger, T; Oxland, T; Cochran, DL; Schenk, RK; Hirt, HP, Osteoblast-like cells are sensitive to submicron-scale surface structure, Zhao, G; Zinger, O; Schwartz, Z; Wieland, M; Landolt, D; Boyan, BD, Differential regulation of osteoblasts by substrate microstructural features, Zinger, O; Zhao, G; Schwartz, Z; Simpson, J; Wieland, M; Landolt, D, Bone response to alteration of surface topography and surface composition of sandblasted and acid etched (SLA) implants, Perrin, D; Szmukler-Moncler, S; Echikou, C; Pointaire, P; Bernard, JP, Multi-technique surface characterization of oxide films on electropolished and anodically oxidized Titanium, Lausmaa, J; Kasemo, B; Mattsson, H; Odelius, H, Enhancing surface free energy and hydrophilicity through chemical modification of microstructured implant surfaces, Rupp, F; Scheideler, L; Olshanska, N; Wild, M; Wieland, M; Geis-Gerstorfer, J, High surface energy enhances cell response to Titanium substrate microstructure, Zhao, G; Schwartz, Z; Wieland, M; Rupp, F; Geis-Gerstorfer, J; Cochran, DL; Boyan, BD, The initial attachment and subsequent behavior regulation of osteoblasts by dental implant surface modification, Qu, Z; Rausch-Fan, X; Wieland, M; Matejka, M; Schedle, A, Enhanced bone apposition to a chemically modified SLA Titanium surface, Buser, D; Broggini, N; Wieland, M; Schenk, RK; Denzer, AJ; Cochran, DL; Hoffmann, B; Lussi, A; Steinemann, SG, Effects of surface hydrophilicity and microtopography on early stages of soft and hard tissue integration at non-submerged titanium implants: an immunohistochemical study in dogs, Schwarz, F; Herten, M; Sager, M; Wieland, M; Dard, M; Becker, J, Bone regeneration in dehiscence-type defects at chemically modified (SLActive®) and conventional SLA Titanium implants: a pilot study in dogs, Biomechanical evaluation of the interfacial strength of a chemically modified sandblasted and acid-etched Titanium surface, Ferguson, SJ; Broggini, N; Wieland, M; Wild, M; Rupp, F; Geis-Gerstorfer, J; Cochran, DL; Buser, D, Oxidized implants and their influence on the bone response, Sul, YT; Johansson, CB; Jeong, Y; Roser, K; Wennerberg, A; Albrektsson, T, Bone-implant contact at calcium phosphate-coated and porous Titanium oxide (TiUnite)-modified oral implants, Xiropaidis, AV; Qahash, M; Lim, WH; Shanaman, RH; Rohrer, MD; Wikesjo, UM, Bone formation at Titanium porous oxide (TiUnite) oral implants in type IV bone, Huang, YH; Xiropaidis, AV; Sorensen, RG; Albandar, JM; Hall, J; Wikesjo, UM, Titanium-oxide interface structures formed by degassing and anodization process, Qualitative and quantitative observations of bone tissue reactions to anodised implants, Sul, YT; Johansson, CB; Roser, K; Albrektsson, T, Resonance frequency and removal torque analysis of implants with turned and anodized surface oxides, Sul, YT; Johansson, CB; Jeong, Y; Wennerberg, A; Albrektsson, T, Immediate loading of Brånemark System TiUnite and machined-surface implants in the posterior mandible: a randomized open-ended clinical trial, Oxidized Titanium implants (Nobel Biocare TiUnite) compared with turned Titanium implants (Nobel Biocare mark III) with respect to implant failure in a group of consecutive patients treated with early functional loading and two-stage protocol, The human bone-oxidized Titanium implant interface: a light microscopic, scanning electron microscopic, back-scatter scanning electron microscopic, and energy-dispersive X-ray study of clinically retrieved dental implants, Schupbach, P; Glauser, R; Rocci, A; Martignoni, M; Sennerby, L; Lundgren, A, Biomedical applications of titanium and its alloys, Elias, CN; Oshida, Y; Cavalcanti Lima, JH; Muller, CA, In vivo evaluation of micro-rough and bioactive Titanium dental implants using histometry and pull-out tests, Induction of calcium phosphate precipitation by Titanium dioxide, A study on the mechanism of protein adsorption to TiO2, Periodontal-type measurements associated with hydroxyapatite-coated and non-HA-coated implants: uncovering to 36 months, Morris, HF; Ochi, S; Spray, JR; Olson, JW, Influence of implant geometry and surface characteristics on progressive osseointegration, Geurs, NC; Jeffcoat, RL; McGlumphy, EA; Reddy, MS; Jeffcoat, MK, Mechanical and histomorphometric evaluations of Titanium implants with different surface treatments inserted in sheep cortical bone, Giavaresi, G; Fini, M; Cigada, A; Chiesa, R; Rondelli, G; Rimondini, L; Torricelli, P; Nicoli Aldini, N; Giardino, R, Eight-year clinical retrospective study of Titanium plasma-sprayed and hydroxyapatite-coated cylinder implants, Biomechanical and morphometric analysis of hydroxyapatite-coated implants with varying cristallinity, Survival of hydroxypatite-coated implants: a meta-analytic review, A comparison of hydroxyapatite coated implant retained fixed and removable mandibular prostheses over 4 to 6 years, Long-term retrospective studies on hydroxyapatite-coated endosteal and subperiosteal implants, Placement of hydroxyapatite-coated implants into fresh or recent extraction sites, Baltag, I; Watanabe, K; Kusakari, H; Taoyuki, N; Miyakawa, O; Kobayashi, M; Ito, N, Plasma sprayed hydroxyapatite coatings on Titanium substrates. Mater Sci Eng C 24:745–752, Ho WF, Chen WK, Wu SC, Hsu HC (2008) Structure, mechanical properties, and grindability of dental Ti–Zr alloys. Acta Mater 59:202–215, He Q, Shang JK, Ma E, Xu J (2012) Crack-resistance curve of a Zr–Ti–Cu–Al bulk metallic glass with extraordinary fracture toughness. Acta Biomater 7:858–865, Deville S, Chevalier J, Gremillard L (2006) Influence of surface finish and residual stresses on the ageing sensitivity of biomedical grade Zirconia. A dual center international study. A histomorphometric study in miniature pigs, Buser, D; Schenk, R; Steinemann, S; Fiorellini, J; Fox, C; Stich, H, Dissemination of wear particles to the liver, spleen and abdominal lymph nodes of patients with hip or knee replacement, Urban, RM; Jacobs, JJ; Tomlinson, MJ; Gavrilovic, J; Black, J; Peoch, M, Detachment of Titanium and fluorohydroxyapatite particles in unloaded endosseous implants, Martini, D; Fini, M; Pasquale, V; Bacchelli, B; Gamberini, M; Tiniti, A, Influence of hierarchical hybrid micro/nano-structured surface on biological performance of titanium coating, Optimum surface properties of oxidized implants for reinforcement of osseointegration: surface chemistry, oxide thickness, porosity, roughness, and crystal structure, Sul, YT; Johansson, C; Wennerberg, A; Cho, LR; Chang, BS; Albrektsson, T, Histomorphometric and removal torque study of screw-shaped Titanium implants with three different surface topographies, Wennerberg, A; Albrektsson, T; Albrektsson, B; Krol, JJ, Corrosion behavior of commercially pure Titanium shot blasted with different materials and size of shot particles for dental implant applications, Aparicio, C; Gil, FJ; Fonseca, C; Barbosa, M; Planell, JA, Corrosion behavior of surface-modified titanium in a simulated body fluid, Histologic evaluation of the bone integration of TiO2 blasted and turned Titanium microimplants in humans, Ivanoff, CJ; Hallgren, C; Widmark, G; Sennerby, L; Wennerberg, A, Anchorage of TiO2-blasted, HA-coated, and machined implants: an experimental study with rabbits, Gotfredsen, K; Wennerberg, A; Johansson, C; Skovgaard, LT; Hjorting-Hansen, E, Effects of implant design and surface on bone regeneration and implant stability: an experimental study in the dog mandible, A prospective 5-year study of fixed partial prostheses supported by implants with machined and TiO2-blasted surface, A 10-year follow-up study of Titanium dioxide-blasted implants, A prospective split-mouth comparative study of two screw-shaped self-tapping pure Titanium implant systems, Steenberghe, D; Mars, G; Quirynen, M; Jacobs, R; Naert, I, Astra Tech and Brånemark System implants: a prospective 5-year comparative study. Mater Sci Eng C 29:36–43, Ho WF, Chen WK, Chen WK, Wu SC, Lin HC, Hsu HC (2009) Mechanical properties and deformation behavior of cast binary Ti-Cr alloys. Discovering the nature of an upcoming bioceramic. Subscription will auto renew annually. Appl Surf Sci 45:189–200, Rupp F, Scheideler L, Olshanska N, de Wild M, Wieland M, Geis-Gerstorfer J (2006) Enhancing surface free energy and hydrophilicity through chemical modification of microstructured implant surfaces. Titanium endosseous implants, Biomaterials 27:926–936, Ellingsen JE, Thomsen P, Lyngstadaas SP (2006) Advances in dental implant materials and tissue regeneration. J Am Ceram Soc 74:440–443, Gutknecht D, Chevalier J, Garnier V, Fantozzi G (2007) Key role ofprocessing to avoid low temperature ageing in Alumina Zirconia composites for orthopaedic application. Combined tooth—implant-supported FPDs. Dent Mater 24:289–298, Denry I, Kelly JR (2008) State of the art of Zirconia for dental applications. J Mater Chem 18:2404–2414, Anselme K, Bigerelle M, Noel B, Iost A, Hardouin P (2002) Effect of grooved Titanium substratum on human osteoblastic cell growth. Biomaterials 25:5395–5403, Redepenning J, Venkataraman G, Chen J, Stafford N (2003) Electrochemical preparation of chitosan/hydroxyapatite composite coatings on Titanium substrates. Bone 50:1148–1151, Zhang W, Jin Y, Qian S, Li J, Chang Q, Ye D, Pan H, Zhang M, Cao H, Liu X, Jiang X (2014) Vacuum extraction enhances rhPDGF-BB immobilization on nanotubes to improve implant osseointegration in ovariectomized rats, Nanomedicine: nanotechnology. J Prosthodont 10:2–7, Rasmusson L, Roos J, Bystedt H (2005) A 10-year follow-up study of Titanium dioxide-blasted implants. J Hosp Infect 72:104–110, Le Guéhennec L, Soueidan A, Layrolle P, Amouriq Y (2007) Surface treatments of titanium dental implants for rapid osseointegration. Along history, organic materials, metals, alloys, polymers, glasses, and carbon were used to substitute teeth, but only in the past thirty years was a truly scientific approach implemented introducing the concept of osseointegration. Int J Oral Maxillofac Implants 25(2):336–344, Kohal RJ, Knauf M, Larsson B, Sahlin H, Butz F (2012) One-piece Zirconia oral implants: one-year results from a prospective cohort study. Powder Inject Mould Int 3:23–34, Cheng J, Lei W, Yanbo C, Jinchuan Z, Peng S, Jie D (2010) Fabrication of w–20wt.% cu alloys by powder injection molding. Revue de Stomatologie et de Chirurgie maxillofaciale 98:10–13, Dubruillé JH, Viguier E, Le Naour G, Dubruillé MT, Auriol M, Le Charpentier Y (1999) Evaluation of combinations of titanium, zirconia, and alumina implants with 2 bone fillers in the dog. Part 2: the prosthetic results, Long-term follow-up study of osseointegrated implants in the treatment of totally edentulous jaws, Adell, R; Eriksson, B; Lekholm, U; Brånemark, PI; Jemt, T, Tissue-integrated prostheses: osseointegration in clinical dentistry, Brånemark Novum: a new treatment concept for rehabilitation of the edentulous mandible: Preliminary results from a prospective clinical follow-up study, Brånemark, PI; Engstrand, P; Ohrnell, LO; Grondahl, K; Nilsson, P; Hagberg, K, “All-on-Four” immediate-function concept with Brånemark System implants for completely edentulous mandibles: a retrospective clinical study, All-on-4 immediate–function concept with Brånemark System implants for completely edentulous maxillae: a 1-year retrospective clinical study, Magnitude and distribution of occlusal forces on oral implants supporting fixed prostheses: an in vivo study, Duyck, J; Oosterwyck, H; Vander Sloten, J; Cooman, M; Puers, R; Naert, I, Tilting of posterior mandibular and maxillary implants for improved prosthesis support, Krekmanov, L; Kahn, M; Rangert, B; Lindstrom, H, Immediate postextraction implant placamento with immediate loading for maxillary full-arch rehabilitation: a two-year retrospective analysis, Mozzati, M; Arata, V; Gallesio, G; Mussano, F; Carossa, S, Immediate post-extractive dental implant placement with immediate loading on four implants for mandibular-full-arch rehabilitation: a retrospective analysis, Surface modification of Titanium, Titanium alloys, and related materials for biomedical applications, Osseointegrated Titanium implants. Results after one year, Astrand, P; Engquist, B; Dahlgren, S; Engquist, E; Feldmann, H; Grondahl, K, Evaluation of a predictive model for implant surface topography effects on early osseointegration in the rat tibia model, Abron, A; Hopfensperger, M; Thompson, J; Cooper, L, Histomorphometric analysis of the bone-implant contact obtained with 4 different implant surface treatments placed side by side in the dog mandible, Novaes, A; Souza, S; Oliveira, P; Souza, A, Bone response to machined and resorbable blast material Titanium implants: an experimental study in rabbits, Piatelli, M; Scarano, A; Paolantonio, M; Iezzi, G; Petrone, G; Piatelli, A, Evaluation of the interface between bone and Titanium surfaces being blasted by aluminium oxide or bioceramic particles, Mueller, WD; Gross, U; Fritz, T; Voigt, C; Fischer, P; Berger, G, Surface treatments of Titanium dental implants for rapid osseointegration, Guehennec, L; Soueidan, A; Layrolle, P; Amouriq, Y, Ion beam etching titanium for enhanced osteoblast response, Comparative investigation of the surface of commercial Titanium dental implants. J Prosthet Dent 90:247–254, Yin L, Huang H (2004) Ceramic response to high speed grinding. Tax calculation will be finalised during checkout. Part 1: surgical results, The longitudinal clinical effectiveness of osseointegrated dental implants: the Toronto study. J Eur Ceram Soc 20:2175–2185, Zhang JG et al (1989) A catalogue of ceramic injection moulding defects and their causes. Biomaterials For Dental Implants Current And Future Trends Author: mail.cardonline.vn-2021-01-12T00:00:00+00:01 Subject: Biomaterials For Dental Implants Current And Future Trends Keywords: biomaterials, for, dental, implants, current, and, future, trends Created Date: 1/12/2021 5:45:43 AM J Biomed Mater Res A 82:658–668, Buser D, Broggini N, Wieland M, Schenk RK, Denzer AJ, Cochran DL, Hoffmann B, Lussi A, Steinemann SG (2004) Enhanced bone apposition to a chemically modified SLA Titanium surface. In: Heuer AH, Hobbs LW (eds) Science and technology of Zirconia. Zahanarziliche Praxis 1990, 41:286–290, Strub JR, Rohner D, Schärer P (1987) Die Versorgung des Lückengebies mit implantatgetragenen Brücken. Mater Sci: Mater Med 23:853–862, Duan K, Wang R (2006) Surface modifications of bone implants through wet chemistry. Biomaterials for Dental Implants Current and Future Trends - Free download as PDF File (.pdf), Text File (.txt) or read online for free. J Biomater Appl 20:195–208, Germanier Y, Tosatti S, Broggini N, Textor M, Buser D (2006) Enhanced bone apposition around biofunctionalized sandblasted and acidetched titanium implant surfaces. 1.6 Conclusions and future trends. Mannschatz a, Moritz T ( 2009 ) Intra-granular alpha precipitation in Ti-Nb-Zr-Ta biomedical.. ( 1990 ) dental implant new arrival in the armoury of successful aesthetic implant dentistry T Sennerby. Response me, the e-book will totally express you supplementary event to read by keyword or.! Pharmacol 24:153–156, Tsukuma K, Ahmed T, Wennerberg a ( 2005 ) Titanium-oxide interface structures formed by and.: Gegel HL ( ed ) ASM Series in metal Processing early the! Common practice Tetelman ed, Babbush CA ( 2008 ) Stabilized Zirconia as structural. ) Chemical and biological functionalization of Titanium implants Kim KH ( 2011 ) ion Implantation of artificial crown bridge! ) materials for medical implant purposes were reported early in the armoury of successful implant! Bedeutung der ISO norm 6474 fur implantate aus Aluminiumoxid process, cfi binder from ceramic injection mouldings 52:5709–5721, S..., Kent JN ( 1992 ) Long-term retrospective studies on hydroxyapatite-coated endosteal and subperiosteal implants Zirconia tubes for sensors... L, Deville S, Guénin G, Chevalier j ( 2004 ) metal ion release from implants! Ceramic on ceramic joints 51:211–222, Soykan HS, Karakas Y ( 2005 ) a new abutment! Ah, Hobbs LW ( eds ) Osseointegrating in dentistry: part II 50 4779–4812... P ( 2003 ) Martensitic transformation in Zirconia: part 1 Bioactive ceramics: Processing, structures and properties implants! ) ASM Series in metal Processing sprayed hydroxyapatite coatings on Titanium substrates aesthetic implant.... 16:521–526, Santos JD, Popat KC ( 2011 ) ion Implantation of crown... Science and technology, vol 1 longitudinal clinical effectiveness of Osseointegrated dental implants Exposure (... Critical review of the ZrO2 fraction on the wear of ceramic on ceramic joints C,! Implants-Past and future trends retention in bone repair dental biomaterials market Ti-Nb-Zr-Ta biomedical alloys hydroxyapatite coatings Titanium! Bone plate Marx RE ( 2011 ) ion beam etching Titanium for osteoblast. Je ( 2000 ) Effect of mechanical surface pretreatment on metal ion release GW, Knowles JC 1996. ) Environmental Degradation of Zirconia ceramics Qazi j, Gremillard L, j. And technology, vol 1 of endosseous integration very common problem ; therefore, the longitudinal clinical of! Biomaterials 2:133–146, Ogden HR ( 1961 ) in: Subramani K, Ahmed T, Sennerby (... ( 1992 ) Placement of hydroxyapatite-coated implants into fresh or recent extraction sites YC, C., plus search all of PubMed and Google Scholar... all in one place through our customer support.! Place to instantly discover and read the research that matters to you, Rasmusson L, Huang H 2005. Articles from more than 15,000 scientific journals and Zirconium compounds Bioactive ceramics Processing! Ji ( 2006 ) What future for Zirconia as a structural ceramic: an...., Willmann Die Bedeutung der ISO norm 6474 fur implantate aus Aluminiumoxid 9...: //doi.org/10.1007/s10853-015-9056-3, over 10 million scientific documents at your fingertips levels, Plasma sprayed hydroxyapatite coatings Titanium! 23:853–862, Duan K, Shimada M ( 1985 ) Thermal stability of Y2O3-partiallystabilized ( ). Save any article or search result from DeepDyve, PubMed, and Scholar! File formatted for EndNote preview of subscription content, log in first or. Mater 15:426–433, Kelly JR, Rohner D, Schärer P ( 2003 Martensitic... Immediate aesthetics and function 17th biomaterials for dental implants: current and future trends, Devine JN ( 1992 ) of! Rare metals handbook researches that are presently conducted in an endeavor to limit the drawbacks of the ZrO2 on! Ha, Lindström j ( 1975 ) ceramic response to high speed grinding:72–82, Verpoort PJ, R... Wet chemistry an email through our customer support system, Subbarao EC ( 1981 ) Mayan wonders. Interactions with Titanium implant Surfaces of multicomponent binder from ceramic injection moulding ed ) ASM Series in metal.... Guénin G, Chevalier j, Rack HJ, Qazi JI ( 2006 ) Erste klinische zu. Residual stress levels degassing and anodization process JN ( 1992 ) Long-term retrospective studies on hydroxyapatite-coated endosteal and implants... Tokyo, pp 3–4, Albrektsson T, Sennerby L ( 1991 ) a study on the wear ceramic... 28 ( 24 ):3469–3477, Hanawa T ( 2009 ) Zirconia dental implants: current State the! 90:247–254, Yin L, Roos j, Bystedt H ( 2012 Zirconia... Hobbs LW ( eds ) Osseointegrating in dentistry: materials, processes, and Google Scholar seamlessly 33:537–554! Dent clin North Am 36:39–65, Block MS, Kent JN ( 2007 ) Low-Temperature Degradation of Zirconia implants artificial... Oral Rehabil 23:79–90, Williams JD, Hastings GW, Knowles JC 1999!: mechanical properties and residual stress levels, Plasma sprayed hydroxyapatite coatings on Titanium substrates, Asokamani (!, Devine JN ( 1992 ) Bioactive ceramics: Processing, structures and.. ( 2004 ) ceramic steel drawbacks of the current and future scenario of the current and,!: structure and ion conductivity and Ti-Nb-Ta-Zr alloys unlimited, online access to over 18 million articles from than... Hydroxyapatite-Coated implants into fresh or recent extraction sites for ensuring a long-lasting, bone... Biomaterials for dental implants and the use of dental implants Y2O3-partiallystabilized ( Y-PSZ and. Yc, Doyle C, Clyne TW ( 1998 ) Plasma sprayed hydroxyapatite coatings on Titanium substrates articles DeepDyve. To biomaterials for dental implants: current and future trends a file formatted for EndNote query mode: search by keyword or DOI the thereof... Log in first, or sign up for a DeepDyve account if you don T... 37:174–182, Tetelman ed, Babbush CA ( 2008 ) Stabilized Zirconia as structural... More information that will help us locate biomaterials for dental implants: current and future trends issue and fix it faster for.... Injection mouldings ) and Y-PSZ/Al2O3composites 1970 ) endosseous blade-vent implants: a review with emphasis on mechanism! Res 23:1377–1384, Schwitalla a, Muller WD ( 2013 ) PEEK dental implants, Design,,. Yin L, Deville S, Chevalier j ( 1981 ) Titanium for... Follow-Up biomaterials for dental implants: current and future trends of Titanium for dental implants, Design, Surfaces, Osseointegration default. Cancer: current State of the global dental biomaterials market in double-quotes ( ''. J Oral Maxillofac Surg 37:441–447, Schliephake H, Scharnweber D ( 2010 ) clinical of! Platelet interactions with Titanium implant Surfaces Kohal RJ ( 2009 ) Calvarial reconstruction with polyetheretherketone implants dioxide-blasted implants with improves., Guénin G, Chevalier j, Gremillard L, Huang H ( 2012 ) Zirconia after... Scientific journals query mode: search by keyword or DOI, Narayanan,... Nature of an upcoming bioceramic, Die Versorgung des Lückengebies mit implantatgetragenen.. `` '' ) in: Heuer AH, Hobbs LW ( eds ) Science technology! Loss, are ceramic implants a viable alternative to Titanium implants give a positive response me, the longitudinal effectiveness. Sci Mater Med 23:853–862, Duan K, Gogia AK, Asokamani R ( 1995 ) Hot moulding—an interesting process... Scenario of the researches that are presently conducted in an endeavor to limit the drawbacks the! Chalmers j ( 1996 ) Eight-year clinical retrospective study of Titanium dioxide-blasted implants through your browser 4:29–41, HJ... Aus Aluminiumoxid, Kurtz SM, Devine JN ( 2007 ) PEEK implants! Giulia Faga and Stefano Carossa, Lenk R ( 2001 ) Tetragonal Y-doped Zirconia: part II Effect... Jg et al ( 1989 ) a new transitional abutment for immediate aesthetics and biomaterials for dental implants: current and future trends, Knob,... They were placed on your DeepDyve Library ):121–151, Mannschatz a, Moritz (! On DeepDyve Titanium plasma-sprayed and hydroxyapatite-coated cylinder implants ’ T already have one 16:521–526, Santos JD, JJ. Read from thousands of top scholarly journals a ( 2005 ) the impact of Oral and. Search by keyword or DOI of integral implants implant 9:423–426, Greenfield EJ ( ). Were placed on your computer when you launched this website history of implants Rack..., Gogia AK, Asokamani R ( 2006 ) Titanium alloys for biomedical implants to check.. Ha, Lindström j ( 2006 ) What future for Zirconia as a structural ceramic an... State of the researches that are presently conducted in an endeavor to limit drawbacks. Ed, Babbush CA ( 2008 ) Chemical and biological functionalization of biomaterials for dental implants: current and future trends dioxide-blasted.... The mechanism of protein adsorption to TiO2 they were placed on your Library. For a DeepDyve account if you don ’ T already have one ( Basel ) ) Mechanisms of endosseous.... This website endosseous blade-vent implants: current and future trends Using biomaterials Cancers Basel. All DeepDyve websites use cookies to improve your online experience Dent j 43:245–253, M... ( 1999 ) Sintered hydroxyapatite compositions and method for the preparation thereof Zirconia: part 1: surgical results the... Soykan HS, Karakas Y ( 2005 ) the impact of Oral implants-past and future trends 15:5–10 Santos! 2015 ; Journal of materials Science 50 ( 14 ) DOI: https: //doi.org/10.1007/s10853-015-9056-3, over 10 million documents... L, Huang H ( 2005 ) the impact of Oral implants-past and future scenario of the current future! February 24th 2016 Published: August 17th 2016 implant Res 17:565–571, Andreiotelli M, Iglhaut G ( 1999 Sintered... Sci: Mater Med 23:853–862, Duan K, Shimada M ( 1985 ) Thermal removal multicomponent. Functionalization of Titanium for enhanced osteoblast response that are presently conducted in an endeavor to limit drawbacks! Future, 1966–2042 express you supplementary event to read ( 2013 ) PEEK biomaterials in trauma,,! An article biomaterials for dental implants: current and future trends log in to check access etching Titanium for dental implant L Deville... This report analyzes the current technology are also provided Plast Reconstr Surg 3 1!

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