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Literature DB >> 15348504

Bone cements and fillers: a review.

Abstract

Charnley [1] developed the first bone cement in the 1960s using poly(methyl methacrylate) (PMMA), which remains the most widely used material for fixation of orthopaedic joint replacements. In the field of dentistry, zinc polycarboxylate and glass polyalkenoate cements received major research interest from the 1970s to the present day. The discovery of a well-integrated intermediate layer between bone and many bioactive ceramic phases from the calcium-phosphate system, such as hydroxyapatite (HA), resulted in the development of new cements incorporating such phases. These investigations ranged from the development of castable bioactive materials to modified bioactive composites. This paper attempts to give a broad overview of the many different types of cements that have being developed in the past and those which are being researched at the present time. It has lead to a set of fundamental design criteria that should be considered prior to the development of a cement for use as a bone cement or in applications requiring a bone substitute.

Entities: Chemical

Year: 2003 PMID： 15348504 DOI： 10.1023/a:1026394530192

Source DB: PubMed Journal: J Mater Sci Mater Med ISSN： 0957-4530 Impact factor: 3.896

94 in total

1. Long-term in vivo bioactivity and degradability of bulk sol-gel bioactive glasses.

Authors: M Hamadouche; A Meunier; D C Greenspan; C Blanchat; J P Zhong; G P La Torre; L Sedel
Journal: J Biomed Mater Res Date: 2001-03-15

2. Bone-bonding behavior of plasma-sprayed coatings of BioglassR, AW-glass ceramic, and tricalcium phosphate on titanium alloy.

Authors: T Kitsugi; T Nakamura; M Oka; Y Senaha; T Goto; T Shibuya
Journal: J Biomed Mater Res Date: 1996-02

3. Glass-ionomer cements in orthopaedic surgery: design of laboratory tests.

Authors: E A Wasson; J W Nicholson
Journal: Clin Mater Date: 1991

4. A new bioactive bone cement consisting of BIS-GMA resin and bioactive glass powder.

Authors: K Kawanabe; J Tamura; T Yamamuro; T Nakamura; T Kokubo; S Yoshihara
Journal: J Appl Biomater Date: 1993

5. In vivo study of calcium phosphate cements: implantation of an alpha-tricalcium phosphate/dicalcium phosphate dibasic/tetracalcium phosphate monoxide cement paste.

Authors: K Kurashina; H Kurita; M Hirano; A Kotani; C P Klein; K de Groot
Journal: Biomaterials Date: 1997-04 Impact factor: 12.479

6. Reactions in glass ionomer cements: II. An infrared spectroscopic study.

Authors: S Crisp; M A Pringuer; D Wardleworth; A D Wilson
Journal: J Dent Res Date: 1974 Nov-Dec Impact factor: 6.116

7. Bone bonding behavior of MgO-CaO-SiO2-P2O5-CaF2 glass (mother glass of A.W-glass-ceramics).

Authors: T Kitsugi; T Yamamuro; T Nakamura; T Kokubo
Journal: J Biomed Mater Res Date: 1989-06

8. Load-bearing behavior of a simulated craniofacial structure fabricated from a hydroxyapatite cement and bioresorbable fiber-mesh.

Authors: A S Von Gonten; J R Kelly; J M Antonucci
Journal: J Mater Sci Mater Med Date: 2000-02 Impact factor: 3.896

9. Alternative interpretations of water sorption values of composite resins.

Authors: P L Fan; A Edahl; R L Leung; J W Stanford
Journal: J Dent Res Date: 1985-01 Impact factor: 6.116

10. Apatite crystallites: effects of carbonate on morphology.

Authors: R Z Legeros; O R Trautz; J P Legeros; E Klein; W P Shirra
Journal: Science Date: 1967-03-17 Impact factor: 47.728

43 in total

1. Tailor-made tricalcium phosphate bone implant directly fabricated by a three-dimensional ink-jet printer.

Authors: Kazuyo Igawa; Manabu Mochizuki; Osamu Sugimori; Koutaro Shimizu; Kenji Yamazawa; Hiroshi Kawaguchi; Kozo Nakamura; Tsuyoshi Takato; Ryouhei Nishimura; Shigeki Suzuki; Masahiro Anzai; Ung-il Chung; Nobuo Sasaki
Journal: J Artif Organs Date: 2006-12-21 Impact factor: 1.731

2. New biocomposite [biphasic calcium phosphate/ poly-DL-lactide-co-glycolide/biostimulative agent] filler for reconstruction of bone tissue changed by osteoporosis.

Authors: N Ignjatovic; Z Ajdukovic; D Uskokovic
Journal: J Mater Sci Mater Med Date: 2005-07 Impact factor: 3.896

3. PLD bioactive ceramic films: the influence of CaO-P2O5 glass additions to hydroxyapatite on the proliferation and morphology of osteblastic like-cells.

Authors: Gisela Marta Oliveira; Maria P Ferraz; Pío G González; Julia Serra; Betty Leon; Mariano Pèrez-Amor; Fernando J Monteiro
Journal: J Mater Sci Mater Med Date: 2007-12-06 Impact factor: 3.896

Bone cements and fillers: a review.

1. Long-term in vivo bioactivity and degradability of bulk sol-gel bioactive glasses.

2. Bone-bonding behavior of plasma-sprayed coatings of BioglassR, AW-glass ceramic, and tricalcium phosphate on titanium alloy.

3. Glass-ionomer cements in orthopaedic surgery: design of laboratory tests.

4. A new bioactive bone cement consisting of BIS-GMA resin and bioactive glass powder.

5. In vivo study of calcium phosphate cements: implantation of an alpha-tricalcium phosphate/dicalcium phosphate dibasic/tetracalcium phosphate monoxide cement paste.

6. Reactions in glass ionomer cements: II. An infrared spectroscopic study.

7. Bone bonding behavior of MgO-CaO-SiO2-P2O5-CaF2 glass (mother glass of A.W-glass-ceramics).

8. Load-bearing behavior of a simulated craniofacial structure fabricated from a hydroxyapatite cement and bioresorbable fiber-mesh.

9. Alternative interpretations of water sorption values of composite resins.

10. Apatite crystallites: effects of carbonate on morphology.

1. Tailor-made tricalcium phosphate bone implant directly fabricated by a three-dimensional ink-jet printer.

2. New biocomposite [biphasic calcium phosphate/ poly-DL-lactide-co-glycolide/biostimulative agent] filler for reconstruction of bone tissue changed by osteoporosis.

3. PLD bioactive ceramic films: the influence of CaO-P2O5 glass additions to hydroxyapatite on the proliferation and morphology of osteblastic like-cells.

4. Self-setting calcium orthophosphate formulations.

5. Improved mechanical properties of acrylic bone cement with short titanium fiber reinforcement.

6. Micropatterned methacrylate polymers direct spiral ganglion neurite and Schwann cell growth.

7. Application of Materials as Medical Devices with Localized Drug Delivery Capabilities for Enhanced Wound Repair.

8. [Biocompatibility of polymer-bioglass cement Cortoss®: in vitro test with the MG63 cell model].

9. Fabrication of calcium phosphate-calcium sulfate injectable bone substitute using chitosan and citric acid.

10. Tailored sequential drug release from bilayered calcium sulfate composites.