Fabrication of freeform bone-filling calcium phosphate ceramics by gypsum 3D printing method

Journal of Biomedical Materials Research - Part B Applied Biomaterials

Volumn 90 B, Issue 2, 2009, Pages 531-539

  Lowmunkong, Rungnapa ^a   Sohmura, Taiji ^a   Suzuki, Yumiko ^b   Matsuya, Shigeki ^c   Ishikawa, Kunio ^b  

^a OSAKA UNIVERSITY   (Japan)

^b KYUSHU UNIVERSITY   (Japan)

^c FUKUOKA DENTAL COLLEGE   (Japan)

Author keywords

Bioceramic; Calcium phosphate; Freeform fabrication; Gypsum; Hydroxyapatite; Rapid prototyping; TCP

Indexed keywords

AMMONIUM COMPOUNDS; APATITE; BIOLOGICAL MATERIALS; BIOMATERIALS; BONE; CALCIUM; CALCIUM ALLOYS; COMPRESSIVE STRENGTH; CONCURRENT ENGINEERING; CRYSTAL STRUCTURE; DEFECTS; DYNAMIC POSITIONING; FABRICATION; GYPSUM; HYDROXYAPATITE; HYDROXYLATION; JOB ANALYSIS; PERCOLATION (SOLID STATE); POWDERS; PRINTING; RAPID PROTOTYPING; SCAFFOLDS; SINTERING; THREE DIMENSIONAL; TRANSMISSION CONTROL PROTOCOL;

3-D PRINTING; BONE DEFECT; BONE FILLING; CALCIUM PHOSPHATE CERAMICS; CALCIUM SULFATE DIHYDRATE; CALCIUM SULFATE HEMIHYDRATE; FREEFORM; FREEFORM FABRICATION; MACROPOROUS STRUCTURES; OPTIMAL CONDITIONS; OSSEOUS DEFECTS; PHOSPHATE SOLUTIONS; PLASTER OF PARIS; SINTERING TEMPERATURES; THREE-DIMENSIONAL PRINTING (3DP);

CALCIUM PHOSPHATE;

AMMONIUM PHOSPHATE; BIOCERAMICS; CALCIUM PHOSPHATE; CALCIUM SULFATE; HYDROXYAPATITE; PHOSPHATE; UNCLASSIFIED DRUG;

ARTICLE; BONE DEFECT; BONE PROSTHESIS; CERAMICS; CHEMICAL REACTION; COMPRESSIVE STRENGTH; CRYSTAL STRUCTURE; HEATING; IMMERSION; JAW; PLASTER CAST; POWDER; PRINTING; SOLUTION AND SOLUBILITY; TEMPERATURE;

EID: 67749118491     PISSN: 15524973     EISSN: 15524981     Source Type: Journal    
DOI: 10.1002/jbm.b.31314     Document Type: Article

References (20)

1. Gu YW, Khor KA, Cheang P. Bone-like apatite layer formation on hydroxyapatite prepared by spark plasma sintering (SPS). Biomaterials 2004;25:4127-4134. (Pubitemid 38396763)
2. Damien CJ, Parsons JR. Bone graft substitutes: A review of current technology and applications. J Appl Biomater 1991;2: 187-208.
3. Tieliewuhan Y, Hirata I, Sasaki A, Minagi H, Okazaki M. Osteoblast proliferation behavior and bone formation on and in Co3 apatite-collagen sponges with a porous hydroxyapatite frame. Dent Mater J 2004;23:258-264. (Pubitemid 39611138)
4. Mimura K, Watanabe K, Okawa S, Kobayashi M, Miyakawa O. Morphological and chemical characterizations of the interface of a hydroxyapatite-coated implant. Dent Mater J 2004;23:353-360. (Pubitemid 39611151)
5. Doi Y, Shibutani T, Moriwaki Y, Kajimoto T, Iwayama Y. Sintered carbonate apatites as bioresorbable bone substitutes. J Biomed Mater Res 1998;39:603-610. (Pubitemid 28079724)
6. Seitz H, Rieder W, Irsen S, Leukers B, Tille C. Three-dimensional printing of porous ceramic scaffolds for bone tissue engineering. J BiomedMater Res B Appl Biomater 2005;74:782-788. (Pubitemid 41076949)
7. Leukers B, Gülkan H, Irsen SH, Milz S, Tille C, Schieker M, Seitz H. Hydroxyapatite scaffolds for bone tissue engineering made by 3D printing. JMater Sci Mater Med 2005;16:1121-1124. (Pubitemid 41803736)
8. Khalyfa A, Vogt S, Weisser J, Grimm G, Rechtenbach A, Meyer W, Schnabelrauch M. Development of a new calcium phosphate powder-binder system for the 3D printing of patient specific implants. J Mater Sci Mater Med 2007;18:909-916. (Pubitemid 46764024)
9. Giordano RA, Wu BM, Borland SW, Cima LG, Sachs EM, Cima MJ. Mechanical properties of dense polylactic acid structures fabricated by three dimensional printing. J Biomater Sci Polym Ed 1996;8:63-75.
10. Levy RA, Chu TM, Halloran JW, Feinberg SE, Hollister S. CT-generated porous hydroxyapatite orbital floor prosthesis as a prototype bioimplant. J Neuroradiol 1997;18:1522-1525. (Pubitemid 30413968)
11. Gbureck U, Hölzel T, Biermann I, Barralet JE, Grover LM. Preparation of tricalcium phosphate/calcium pyrophosphate structures via rapid prototyping. J Mater Sci Mater Med 2008; 19:1559-1563.
12. Habibovic P, Gbureck U, Doillon CJ, Bassett DC, van Blitterswijk CA, Barralet JE. Osteoconduction and osteoinduction of low-temperature 3D printed bioceramic implants. Biomaterials 2008;29:944-953. (Pubitemid 350284589)
13. Lowmunkong R, Sohmura T, Takahashi J, Suzuki Y, Matsuya S, Ishikawa K. Transformation of 3DP gypsum model to HA by treating in ammonium phosphate solution. J Biomed Mater Res B Appl Biomater 2007;80:386-393. (Pubitemid 46245590)
14. Aoki H. Marvelous Biomaterial Apatite. Tokyo: ISHIYAKU; 1999. pp 80-81.
15. Peltier LF. The use of plaster of Paris to fill defects in bone. Clin Orthop 1961;21:1-31.
16. Oh CW, Kim PT, Ihn JC. The use of calcium sulfate as a bone substitute. J Orthop Surg 1998;6:1-10.
17. Frame JW. Porous calcium sulfate dihydrate as biodegradable implant in bone. J Dent 1975;3:77-87.
18. Kato T. Preparation and evaluation of bioactive porous hydroxyapatite. Master thesis of Faculty of Engineering, Tokushima University; 2003.
19. Ruys AJ, Wei M, Sorrell CC, Dickson MR, Brandwood A, Milthorpe BK. Sintering effects on the strength of hydroxyapatite. Biomaterials 1995;16:409-415.
20. Juang HY, Hon MH. Effect of calcination on sintering of hydroxyapatite. Biomaterials 1996;17:2059-2064.