Bone regeneration performance of surface-treated porous titanium

Biomaterials

Volumn 35, Issue 24, 2014, Pages 6172-6181

  Amin Yavari, Saber ^a,b   van der Stok, Johan ^c   Chai, Yoke Chin ^d,e,f   Wauthle, Ruben ^d,g   Tahmasebi Birgani, Zeinab ^h   Habibovic, Pamela ^h   Mulier, Michiel ^d   Schrooten, Jan ^d   Weinans, Harrie ^a,c,i   Zadpoor, Amir Abbas ^a  

^a DELFT UNIVERSITY OF TECHNOLOGY   (Netherlands)

^b FT Innovations BV   (Netherlands)

^c ERASMUS UNIVERSITY ROTTERDAM   (Netherlands)

^d UNIVERSITY OF LEUVEN   (Belgium)

^e SKELETAL BIOLOGY AND ENGINEERING RESEARCH CENTER   (Belgium)

^f UNIVERSITY OF MALAYA   (Malaysia)

^g Layerwise NV   (Belgium)

^h UNIVERSITY OF TWENTE   (Netherlands)

ⁱ UNIVERSITY MEDICAL CENTER UTRECHT   (Netherlands)

Author keywords

Bone grafting; Bone regeneration; Nanotopography; Selective laser melting; Surface chemistry; Surface cell interaction

Indexed keywords

3D PRINTERS; ANIMAL CELL CULTURE; BIOMATERIALS; BIOMECHANICS; CELL PROLIFERATION; CELLS; CYTOLOGY; GENE EXPRESSION; HEAT TREATMENT; NANOTECHNOLOGY; SURFACE CHEMISTRY; SURFACE TREATMENT; TITANIUM;

BONE GRAFTING; BONE REGENERATION; NANOTOPOGRAPHIES; SELECTIVE LASER MELTING; SURFACE-CELL INTERACTION;

BONE;

APATITE; BONE PROSTHESIS; HYDROCHLORIC ACID; SODIUM HYDROXIDE; SOLUTION AND SOLUBILITY; SULFURIC ACID; TITANIUM;

ADOLESCENT; ANIMAL; BONE PROSTHESIS; BONE REGENERATION; CELL ADHESION; CELL CULTURE; CELL PROLIFERATION; CELL SHAPE; CHEMISTRY; CYTOLOGY; DRUG EFFECTS; HEAT; HUMAN; MALE; MICRO-COMPUTED TOMOGRAPHY; ORGAN SIZE; PERIOSTEUM; PHARMACOLOGY; POROSITY; SOLUTION AND SOLUBILITY; SPECTROMETRY; SURFACE PROPERTY; TISSUE SCAFFOLD; ULTRASTRUCTURE; WISTAR RAT;

ADOLESCENT; ANIMALS; APATITES; BONE REGENERATION; BONE SUBSTITUTES; CELL ADHESION; CELL PROLIFERATION; CELL SHAPE; CELLS, CULTURED; HOT TEMPERATURE; HUMANS; HYDROCHLORIC ACID; MALE; ORGAN SIZE; PERIOSTEUM; POROSITY; RATS, WISTAR; SODIUM HYDROXIDE; SOLUTIONS; SPECTROMETRY, X-RAY EMISSION; SULFURIC ACIDS; SURFACE PROPERTIES; TISSUE SCAFFOLDS; TITANIUM; X-RAY MICROTOMOGRAPHY;

EID: 84901439779     PISSN: 01429612     EISSN: 18785905     Source Type: Journal    
DOI: 10.1016/j.biomaterials.2014.04.054     Document Type: Article

References (50)

1. Sen M., Miclau T. Autologous iliac crest bone graft: should it still be the gold standard for treating nonunions?. Injury 2007, 38:S75-S80.
2. Dimitriou R., Mataliotakis G.I., Angoules A.G., Kanakaris N.K., Giannoudis P.V. Complications following autologous bone graft harvesting from the iliac crest and using the RIA: a systematic review. Injury 2011, 42:S3-S15.
3. Pelissier P., Masquelet A., Bareille R., Pelissier S.M., Amedee J. Induced membranes secrete growth factors including vascular and osteoinductive factors and could stimulate bone regeneration. JOrthop Res 2004, 22:73-79.
4. Kokubo S., Mochizuki M., Fukushima S., Ito T., Nozaki K., Iwai T., et al. Long-term stability of bone tissues induced by an osteoinductive biomaterial, recombinant human bone morphogenetic protein-2 and a biodegradable carrier. Biomaterials 2004, 25:1795-1803.
5. Duan B., Wang M., Zhou W.Y., Cheung W.L., Li Z.Y., Lu W.W. Three-dimensional nanocomposite scaffolds fabricated via selective laser sintering for bone tissue engineering. Acta Biomater 2010, 6:4495-4505.
6. Goodridge R., Dalgarno K., Wood D. Indirect selective laser sintering of an apatite-mullite glass-ceramic for potential use in bone replacement applications. Proc Inst Mech Eng H 2006, 220:57-68.
7. Simpson R.L., Wiria F.E., Amis A.A., Chua C.K., Leong K.F., Hansen U.N., et al. Development of a 95/5 poly (L-lactide-co-glycolide)/hydroxylapatite and β-tricalcium phosphate scaffold as bone replacement material via selective laser sintering. JBiomed Mater Res B Appl Biomater 2008, 84:17-25.
8. Williams J.M., Adewunmi A., Schek R.M., Flanagan C.L., Krebsbach P.H., Feinberg S.E., et al. Bone tissue engineering using polycaprolactone scaffolds fabricated via selective laser sintering. Biomaterials 2005, 26:4817-4827.
9. Mullen L., Stamp R.C., Brooks W.K., Jones E., Sutcliffe C.J. Selective laser melting: a regular unit cell approach for the manufacture of porous, titanium, bone in-growth constructs, suitable for orthopedic applications. JBiomed Mater Res B Appl Biomater 2009, 89:325-334.
10. Pattanayak D.K., Fukuda A., Matsushita T., Takemoto M., Fujibayashi S., Sasaki K., et al. Bioactive Ti metal analogous to human cancellous bone: fabrication by selective laser melting and chemical treatments. Acta Biomater 2011, 7:1398-1406.
11. Vandenbroucke B., Kruth J.-P. Selective laser melting of biocompatible metals for rapid manufacturing of medical parts. Rapid Prototyp J 2007, 13:196-203.
12. Warnke P.H., Douglas T., Wollny P., Sherry E., Steiner M., Galonska S., et al. Rapid prototyping: porous titanium alloy scaffolds produced by selective laser melting for bone tissue engineering. Tissue Eng Part C Methods 2008, 15:115-124.
13. Lin C.Y., Wirtz T., LaMarca F., Hollister S.J. Structural and mechanical evaluations of a topology optimized titanium interbody fusion cage fabricated by selective laser melting process. JBiomed Mater Res A 2007, 83:272-279.
14. Murphy C.M., Haugh M.G., O'Brien F.J. The effect of mean pore size on cell attachment, proliferation and migration in collagen-glycosaminoglycan scaffolds for bone tissue engineering. Biomaterials 2010, 31:461-466.
15. Campoli G., Borleffs M.S., Amin Yavari S., Wauthle R., Weinans H., Zadpoor A.A. Mechanical properties of open-cell metallic biomaterials manufactured using additive manufacturing. Mater Des 2013, 49:957-965.
16. van der Stok J., Wang H., Amin Yavari S., Siebelt M., Sandker M., Waarsing J.H., et al. Enhanced bone regeneration of cortical segmental bone defects using porous titanium scaffolds incorporated with colloidal gelatin gels for time and dose controlled delivery of dual growth factors. Tissue Eng Part A 2013, 19:2605-2614.
17. Jonášová L., Müller F.A., Helebrant A., Strnad J., Greil P. Biomimetic apatite formation on chemically treated titanium. Biomaterials 2004, 25:1187-1194.
18. Nebe J.B., Müller L., Lüthen F., Ewald A., Bergemann C., Conforto E., et al. Osteoblast response to biomimetically altered titanium surfaces. Acta Biomater 2008, 4:1985-1995.
19. Amin Yavari S., Wauthle R., Böttger A.J., Schrooten J., Weinans H., Zadpoor A.A. Crystal structure and nanotopographical features on the surface of heat-treated and anodized porous titanium biomaterials produced using selective laser melting. Appl Surf Sci 2014, 290:287-294.
20. Arima Y., Iwata H. Effect of wettability and surface functional groups on protein adsorption and cell adhesion using well-defined mixed self-assembled monolayers. Biomaterials 2007, 28:3074-3082.
21. Kokubo T. Surface chemistry of bioactive glass-ceramics. JNon-cryst Solids 1990, 120:138-151.
22. Zreiqat H., Valenzuela S.M., Nissan B.B., Roest R., Knabe C., Radlanski R.J., et al. The effect of surface chemistry modification of titanium alloy on signalling pathways in human osteoblasts. Biomaterials 2005, 26:7579-7586.
23. Beşkardeş I.G., Gümüşderelioǧlu M. Biomimetic apatite-coated PCL scaffolds: effect of surface nanotopography on cellular functions. JBioact Compat Polym 2009, 24:507-524.
24. Kim M.-J., Lee B., Yang K., Park J., Jeon S., Um S.H., et al. BMP-2 peptide-functionalized nanopatterned substrates for enhanced osteogenic differentiation of human mesenchymal stem cells. Biomaterials 2013, 34:7236-7246.
25. Neoh K.G., Hu X., Zheng D., Kang E.T. Balancing osteoblast functions and bacterial adhesion on functionalized titanium surfaces. Biomaterials 2012, 33:2813-2822.
26. Patel S., Kurpinski K., Quigley R., Gao H., Hsiao B.S., Poo M.-M., et al. Bioactive nanofibers: synergistic effects of nanotopography and chemical signaling on cell guidance. Nano Lett 2007, 7:2122-2128.
27. Zhang W., Wang G., Liu Y., Zhao X., Zou D., Zhu C., et al. The synergistic effect of hierarchical micro/nano-topography and bioactive ions for enhanced osseointegration. Biomaterials 2013, 34:3184-3195.
28. Nishiguchi S., Kato H., Neo M., Oka M., Kim H.-M., Kokubo T., et al. Alkali- and heat-treated porous titanium for orthopedic implants. JBiomed Mater Res 2001, 54:198-208.
29. Fukuda A., Takemoto M., Saito T., Fujibayashi S., Neo M., Pattanayak D.K., et al. Osteoinduction of porous Ti implants with a channel structure fabricated by selective laser melting. Acta Biomater 2011, 7:2327-2336.
30. 2 layer formed on Ti metal by NaOH, acid and heat treatments. JMater Sci Mater Med 2011, 22:1803-1812.
31. Li X., Wang C., Wang L., Zhang W., Li Y. Fabrication of bioactive titanium with controlled porous structure and cell culture invitro. Rare Metal Mat Eng 2010, 39:1697-1701.
32. Takemoto M., Fujibayashi S., Neo M., Suzuki J., Matsushita T., Kokubo T., et al. Osteoinductive porous titanium implants: effect of sodium removal by dilute HCl treatment. Biomaterials 2006, 27:2682-2691.
33. Chen Y., Feng B., Zhu Y., Weng J., Wang J., Lu X. Preparation and characterization of a novel porous titanium scaffold with 3D hierarchical porous structures. JMater Sci Mater Med 2011, 22:839-844.
34. Zhang Q., Leng Y., Xin R. Acomparative study of electrochemical deposition and biomimetic deposition of calcium phosphate on porous titanium. Biomaterials 2005, 26:2857-2865.
35. Zhao C., Zhu X., Liang K., Ding J., Xiang Z., Fan H., et al. Osteoinduction of porous titanium: a comparative study between acid-alkali and chemical-thermal treatments. JBiomed Mater Res B Appl Biomater 2010, 95B:387-396.
36. Das K., Bose S., Bandyopadhyay A. Surface modifications and cell-materials interactions with anodized Ti. Acta Biomater 2007, 3:573-585.
37. George E., Yao C., Webster T.J. Enhanced osteoblast adhesion to drug-coated anodized nanotubular titanium surfaces. Int J Nanomed 2008, 3:257-264.
38. Minagar S., Wang J., Berndt C.C., Ivanova E.P., Wen C. Cell response of anodized nanotubes on titanium and titanium alloys. JBiomed Mater Res A 2013, 101:2726-2739.
39. Yao C., Slamovich E.B., Webster T.J. Enhanced osteoblast functions on anodized titanium with nanotube-like structures. JBiomed Mater Res A 2008, 85A:157-166.
40. Amin Yavari S., Wauthle R., van der Stok J., Riemslag A.C., Janssen M., Mulier M., et al. Fatigue behavior of porous biomaterials manufactured using selective laser melting. Mater Sci Eng C Mater Biol Appl 2013, 33:4849-4858.
41. Kokubo T., Takadama H. How useful is SBF in predicting invivo bone bioactivity?. Biomaterials 2006, 27:2907-2915.
42. Chai Y.C., Roberts S.J., Van Bael S., Chen Y., Luyten F.P., Schrooten J. Multi-level factorial analysis of Ca2+/Pi supplementation as bio-instructive media for invitro biomimetic engineering of three-dimensional osteogenic hybrids. Tissue Eng Part C Methods 2011, 18:90-103.
43. Van der Stok J., Van der Jagt O., Amin Yavari S., De Haas M., Waarsing J., Jahr H., et al. Selective laser melting-produced porous titanium scaffolds regenerate bone in critical size cortical bone defects. JOrthop Res 2013, 31:792-799.
44. Ducheyne P., Qiu Q. Bioactive ceramics: the effect of surface reactivity on bone formation and bone cell function. Biomaterials 1999, 20:2287-2303.
45. Kim H.N., Jiao A., Hwang N.S., Kim M.S., Kang D.H., Kim D.-H., et al. Nanotopography-guided tissue engineering and regenerative medicine. Adv Drug Deliv Rev 2013, 65:536-558.
46. Kulangara K., Yang Y., Yang J., Leong K.W. Nanotopography as modulator of human mesenchymal stem cell function. Biomaterials 2012, 33:4998-5003.
47. McNamara L.E., McMurray R.J., Biggs M.J., Kantawong F., Oreffo R.O., Dalby M.J. Nanotopographical control of stem cell differentiation. JTissue Eng 2010, 1:120623.
48. Sun Y., Chen C.S., Fu J. Forcing stem cells to behave: a biophysical perspective of the cellular microenvironment. Annu Rev Biophys 2012, 41:519-542.
49. Campoli G., Weinans H., Zadpoor A.A. Computational load estimation of the femur. JMech Behav Biomed Mater 2012, 10:108-119.
50. Zadpoor A.A., Campoli G., Weinans H. Neural network prediction of load from the morphology of trabecular bone. Appl Math Model 2013, 37:5260-5276.