Acta Orthop 78:385–392, Fan Y, Duan K, Wang R (2005) A composite coating by electrolysis-induced collagen self-assembly and calcium phosphate mineralization. Biomaterials 25:5395–5403, Redepenning J, Venkataraman G, Chen J, Stafford N (2003) Electrochemical preparation of chitosan/hydroxyapatite composite coatings on Titanium substrates. J Eur Ceram Soc 23:2975–2982, Guazzato M, Albakry M, Quach L, Swain MV (2004) Influence of grinding, sandblasting, polishing and heat treatment on the flexural strength of a glass-infiltrated Alumina-reinforced dental ceramic. Requirements for ensuring a long-lasting, direct bone anchorage in man, Albrektsson, T; Brånemark, PI; Hansson, HA; Lindström, J, Biological factors contributing to failures of osseointegrated oral implants. Tooth loss is very a very common problem; therefore, the use of dental implants is also a common practice. Clin Oral Implants Res 12:128–134, Gotfredsen K, Wennerberg A, Johansson C, Skovgaard LT, Hjorting-Hansen E (1995) Anchorage of TiO2-blasted, HA-coated, and machined implants: an experimental study with rabbits. J Oral Rehabil 37:641–652, Grellner F, Hoscheler S, Greil P, Sindel J, Petschelt A (1997) Residual stress measurements of computer aided design/computer aided manufacturing (CAD/CAM) machined dental ceramics. J Tissue Eng 2010:120623, Puckett S, Pareta R, Webster TJ (2008) Nano rough micron patterned titanium for directing osteoblast morphology and adhesion. 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. The new arrival in the armoury of successful aesthetic implant dentistry, Jum’ah, AA; Beekmans, BMN; Wood, DJ; Maghaireh, H, Inferring optical depth of broken clouds from landsat data, Peri-implant bone formations around (Ti, Zr)O2-coated Zirconia implants with different surface roughness, Titanium in medicine: material science, surface science, engineering, biological responses and medical applications, Brunette, DM; Tengvall, P; Textor, M; Thomsen, P, Biocompatibility of beta-stabilizing elements of Titanium alloys, Eisenbarth, E; Velten, D; Muller, M; Thull, R; Breme, J, In vitro biocompatibility of an ultrafine grained zirconium, Saldaña, L; Méndez-Vilas, A; Jiang, L; Multigner, M; Gonzàlez-Carrasco, JL; Pèrez-Prado, MT; Gonzàlez-Martìn, ML; Munuera, L; Vilaboa, N, Structure of the interface between rabbit cortical bone and implants of gold, zirconium and Titanium, Thomsen, P; Larsson, C; Ericson, LE; Sennerby, L; Lausmaa, J; Kasemo, B, Structure, mechanical properties, and grindability of dental Ti–Zr alloys, The structure and mechanical properties of as-cast Zr–Ti alloys, Structure, mechanical properties and grindability of dental Ti–10Zr–X alloys, Ho, WF; Chen, WK; Pan, CH; Wu, SC; Hsu, HC, Mechanical properties and deformation behavior of cast binary Ti-Cr alloys, Ho, WF; Chen, WK; Chen, WK; Wu, SC; Lin, HC; Hsu, HC, Thermal expansion and microstructural analysis of experimental metal-ceramic Titanium alloys, Zinelis, S; Tsetsekou, A; Papadopoulos, T, The effect of the solute on the structure, selected mechanical properties, and biocompatibility of Ti–Zr system alloys for dental applications, Correa, DRN; Vicente, FB; Donato, TAG; Arana-Chavez, WE; Buzalaf, MAR; Grandini, CR, Intra-granular alpha precipitation in Ti-Nb-Zr-Ta biomedical alloys, Corrosion resistance and in vitro response of laser-deposited Ti–Nb–Zr–Ta alloys for orthopedic implant applications, Samuel, S; Nag, S; Nasrazadani, S; Ukirde, V; Bouanani, M; Mohandas, A; Nguyen, K; Banarjee, R, Influence of potential on the electrochemical behaviour of b Titanium alloys in Hank’s solution, Biocompatibility and osteogenesis of refractory metal implants, Titanium, hafnium, niobium, tantalum and rhenium, Matsuno, H; Yokoyama, A; Watari, F; Uo, M; Kawasaki, T, Cell growth on different Zirconia and Titanium surface textures: a morpholgic in vitro study, Payer, M; Lorenzoni, M; Jakse, N; Kirmeier, R; Dohr, G; Stopper, M; Pertl, C, Study of the in vitro corrosion behavior and biocompatibility of Zr– 2.5Nb and Zr–1.5Nb–1Ta (at%) crystalline alloys, Rosalbino, F; Macciò, D; Giannoni, P; Quarto, R; Saccone, A, Electrochemical properties, chemical composition and thickness of passive film formed on novel Ti–20Nb–10Zr–5Ta alloy, Miloŝev, I; Žerjav, G; Calderon Moreno, JM; Popa, M, Microstructure, mechanical, and anticorrosive properties of a new Ti–20Nb–10Zr–5Ta alloy based on nontoxic and nonallergenic elements, Popa, M; Vasilescu, E; Drob, P; Raducanu, D; Calderon Moreno, JM; Ivanescu, S; Vasilescu, C; Drob, SI, Quaternary Ti–20Nb–10Zr–5Ta alloy during immersion in simulated physiological solutions: formation of layers, dissolution and biocompatibility, Milošev, I; Hmeljak, J; Žerjav, G; Cör, A; Calderon Moreno, JM; Popa, M, Cytotoxicity of Zr-based bulk metallic glasses, Buzzi, S; Jin, KF; Uggowitzer, PJ; Tosatti, S; Gerber, T; Loffler, JF, Amorphous metals for hard-tissue prosthesis, Demetriou, MD; Wiest, A; Hofmann, DC; Johnson, WL; Han, B; Wolfson, N; Wang, G; Liaw, PK, Responses of bone-forming cells on pre-immersed Zr-based bulk metallic glasses: effects of composition and roughness, Huang, L; Cao, Z; Meyer, HM; Liaw, PK; Garlea, E; Dunlap, JR; Zhang, T; He, W, Location bulk metallic glasses with high fracture toughness: chemical effects and composition optimization, Crack-resistance curve of a Zr–Ti–Cu–Al bulk metallic glass with extraordinary fracture toughness, Zr61Ti2Cu25Al12 metallic glass for potential use in dental implants: biocompatibility assessment by in vitro cellular responses, Li, Jing; Shi, Ling-ling; Zhu, Zhen-dong; He, Qiang; Ai, Hong-jun; Jian, Xu, Low-temperature ageing of Zirconia-toughened Alumina ceramics and its implication in biomedical implants, Deville, S; Chevalier, J; Fantozzi, G; Bartolome, JF; Requena, J; Moya, JS; Torrecillas, R; Dıàz, LA, Influence of grinding, sandblasting, polishing and heat treatment on the flexural strength of a glass-infiltrated Alumina-reinforced dental ceramic, Guazzato, M; Albakry, M; Quach, L; Swain, MV, Lifetime estimation of a Zirconia-Alumina composite for biomedical applications, Fabbri, P; Piconi, C; Burresi, E; Magnani, G; Mazzanti, F; Mingazzini, C, Effect of dopants and sintering temperature on microstructure and low temperature degradation of dental Y–TZP–Zirconia, Hallmann, L; Ulmer, P; Reusser, E; Louvel, M; Hammerle, CHF, Mixed-oxides prosthetic ceramic ball heads. J Am Ceram Soc 69:i–Iv, Morena R, Lockwood PE, Evans AL, Fairhurst CW (1986) Toughening of dental porcelain by tetragonal ZrO2 addition. Clin Oral Implant Res 20:1247–1253, Wang G, Liu X, Zreiqat H, Ding C (2011) Enhanced effects of nano-scale topography on the bioactivity and osteoblast behaviors of micron rough ZrO2 coatings. Eur J Esthet Dent 4:130–151, Willmann Die Bedeutung der ISO norm 6474 fur implantate aus Aluminiumoxid. Princeton, New Jersey, Trunec M, Cihlar J (2002) Thermal removal of multicomponent binder from ceramic injection mouldings. 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. Clin Implant Dent Relat Res 1:17–26, Abron A, Hopfensperger M, Thompson J, Cooper L (2001) Evaluation of a predictive model for implant surface topography effects on early osseointegration in the rat tibia model. J Mater Process Technol 210:137–142, Thomas-Vielma P, Cervera A, Levenfeld B, Varez A (2008) Production of Alumina parts by powder injection molding with a binder system based on high density polyethylene. Titanium endosseous implants, Cooper, LF; Zhou, Y; Takabe, J; Guo, J; Abron, A; Holmen, A; Ellingsen, JE, Fracture mechanisms of retrieved Titanium screw thread in dental implants, Yokoyama, K; Ichikawa, T; Murakami, H; Miyamoto, Y; Asaoka, K, Hydrogen embrittlement of work-hardened Ni–Ti alloy in fluoride solutions, Yokoyama, KI; Kaneko, K; Ogawa, T; Moriyama, K; Asaoka, K; Sakai, JI, Evaluation of hydrogen absorption behaviour during acid etching for surface modification of commercial pure Ti, Ti–6Al–4V and Ni–Ti superelastic alloys, Behavior of acid etching on Titanium: topography, hydrophility and hydrogen concentration, The effect of hydrofluoric acid treatment of Titanium surface on nanostructural and chemical changes and the growth of MC3T3-E1 cells, Lamolle, SF; Monjo, M; Rubert, M; Haugen, HJ; Lyngstadaas, SP; Ellingsen, JE, The influence of basting and sterilization on the wettability and surface-energy properties of Titanium surfaces, Pegueroles, M; Gil, FJ; Planell, JA; Aparicio, C, Spatial organization of osteoblast Fibronectin-Matrix on Titanium surface—effects of roughness, chemical heterogeneity, and surface free energy, Pegueroles, M; Aparicio, C; Bosio, M; Engel, E; Gil, FJ; Planell, JA; Altankov, GA, Effect of blasting treatment and Fn coating on MG63 adhesion and differentiation on Titanium. Single tooth replacement. Patent WO 0068164, Lopes M, Knoles J, Santos J, Monteiro F, Olsen I (2000) Direct and indirect effects of P2O5-glass reinforced hydroxyapatite composites and growth and function of osteoblasted-like cells. A systematic literature review. Annu Rev Mater Res 37:1–32, Lawson S (1995) Environmental degradation of Zirconia ceramics. J Alloys Compd 488:279–283, Ho WF, Chen WK, Pan CH, Wu SC, Hsu HC (2009) Structure, mechanical properties and grindability of dental Ti–10Zr–X alloys. J Clin Invest 116(12):3150, Suda T, Takahashi F, Takahashi N (2012) Bone effects of vitamin D—Discrepancies between in vivo and in vitro studies. Key Eng Mater 153(154):1–35, Garvie RC, Nicholson PS (1972) Phase analysis in Zirconia systems. Clin Oral Implant Res 15:643–653, Pjetursson BE, Tan K, Lang NP, 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 I. Implant-supported FPDs. Titanium: a new allergen. The new arrival in the armoury of successful aesthetic implant dentistry. 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. Evidence-based clinical breakthrough, Koutayas, SO; Vagkopoulou, T; Pelekanos, S; Koidis, P; Strub, JR, Titanium lymph node pigmentation in the reconstruction plate system of a mandibular bone defect, Metal release in patients who have had a primary total hip arthroplasty.A prospective, controlled, longitudinal study, Jacobs, JJ; Skipor, AK; Patterson, LM; Hallab, NJ; Paprosky, WG; Black, J; Galante, JO, Osseointegration and clinical success of Zirconia dental implants: a systematic review, Wenz, HJ; Bartsch, J; Wolfart, S; Kern, M, A multidisciplinary clinical study of patients suffering from illness associated with mercury release from dental restorations: psychiatric aspects, Bågedahl-Strindlund, M; Hie, M; Furhotf, AK; Tomson, Y; Larsson, KS; Sandborgh-Englund, G, Peri-implant bone formation and surface characteristics of rough surface Zirconia implants manufactured by powder injection molding technique in rabbit tibiae, Bioactive ceramics: processing, structures and properties, Zirconia in dentistry: part 1. Clin Oral Impl Res 24:569–575, Oliva JOX, Oliva JD (2010) Five-year success rate of 831 consecutively placed Zirconia dental implants in humans: a comparison of three different rough surfaces. Clin Oral Impl Res 24:158–166, Qiao S, Cao H, Zhao X, Lo H, Zhuang L, Gu Y, Shi J, Liu X, Lai H (2015) Ag-plasma modification enhances bone apposition around titanium dental implants: an animal study in Labrador dogs. Acta Psychiatr Scand 96(6):475–482, Park YS, Chung SH, Shon WJ (2013) Peri-implant bone formation and surface characteristics of rough surface Zirconia implants manufactured by powder injection molding technique in rabbit tibiae. Part 2: the prosthetic results. J Prosthodont 18(6):473–478, Masuyama R, Stockmans I, Torrekens S, Van Looveren R, Maes C, Carmeliet P, Bouillon R, Carmeliet G (2006) Vitamin D receptor in chondrocytes promotes osteoclastogenesis and regulates FGF23 production in osteoblasts. A rise in the number of elderly people with oral diseases, increase in implant penetration globally, and a rise in dental tourism across the globe are major drivers of … Tang X, Ahmed T, Rack HJ (2000) Phase transformation in Ti-Nb-Ta and Ti-Nb-Ta-Zr alloys. J Mech Behav Biomed Mater 4:1672–1682, Damen JJ, Ten Cate JM, Ellingsen JE (1991) Induction of calcium phosphate precipitation by Titanium dioxide. J Prosthet Dent 85:585–598, van Staden RC, Guan H, Loo YC, Johnson NW, Meredith N (2008) Stress evaluation of implant wall thickness using numerical techniques. declaration biomaterials for dental implants current and future trends can be one of the options to accompany you taking into account having new time. Biomaterials For Dental Implants Current And Future Trends Author: download.truyenyy.com-2020-12-13T00:00:00+00:01 Subject: Biomaterials For Dental Implants Current And Future Trends Keywords: biomaterials, for, dental, implants, current, and, future, trends Created Date: 12/13/2020 12:40:16 AM The American Ceramic Society, Columbus, pp 1–24, Kisi E, Howard C (1998) Crystal structures of Zirconia phases and their interrelation. J Mater Sci 40:3081–3090. J Clin Periodontol 18(6):474–481, Schnitman PA, Shulman LB (1980) Dental implants: benefit and risk.An NIH-Harvard consensus development conference. discover and read the research Int J Oral Maxillofac Implants 1:11–25, Albrektsson T, Lekholm U (1989) Osseointegration: current state of the art. This is a preview of subscription content, log in to check access. J Mater Sci Mater Med 12:557–564, Blue DS, Griggs JA, Woody RD, Miller BH (2003) Effects of bur abrasive particle size and abutment composition on preparation of ceramic implant abutments. J Biomed Mater Res A 74:49–58, Qu Z, Rausch-Fan X, Wieland M, Matejka M, Schedle A (2007) The initial attachment and subsequent behavior regulation of osteoblasts by dental implant surface modification. J Biomed Mater Res 23:45–61, Kelly JR, Denry I (2008) Stabilized Zirconia as a structural ceramic: an overview. J Can Dent Assoc 71:327, Brånemark PI, Breine U, Adell R, Hansson BO, Lindstrom J, Ohlsson A (1969) Intraosseous anchorage of dental prostheses. Mach Sci Technol 8:21–37, Yin L, Jahanmir S, Ives LK (2003) Abrasive machining of porcelain and Zirconia with a dental handpiece. Biomaterials 25:4731–4739, Cooper LF, Zhou Y, Takebe J, Guo J, Abron A, Holmen A, Ellingsen JE (2006) Fluoride modification effects on osteoblast behavior and bone formation at TiO2 grit-blasted c.p. Clin Oral Implants Res 11:465–475, Krekmanov L, Kahn M, Rangert B, Lindstrom H (2000) Tilting of posterior mandibular and maxillary implants for improved prosthesis support. For this purpose, original research articles, review articles, and significant preliminary communications are invited, with particular interest in articles describing current research trends and future perspectives in the dental sciences. DOI: 10.5772/62701 Clin Oral Implants Res 24:8–19, Sul YT, Johansson C, Albrektsson T (2010) A novel in vivo method for quantifying the interfacial biochemical bond strength of bone implants. J Prosth Dent 90:332, Correa DRN, Vicente FB, Donato TAG, Arana-Chavez WE, Buzalaf MAR, Grandini CR (2014) The effect of the solute on the structure, selected mechanical properties, and biocompatibility of Ti–Zr system alloys for dental applications. Oral Implant 9:423–426, Greenfield EJ (1991) Implantation of artificial crown and bridge abutments. Acta Biomater 3(207):1019–1023, Matsuno H, Yokoyama A, Watari F, Uo M, Kawasaki T (2001) Biocompatibility and osteogenesis of refractory metal implants, Titanium, hafnium, niobium, tantalum and rhenium.