Original Research Report
Novel biodegradable calcium phosphate/polymer composite coating with adjustable mechanical properties formed by hydrothermal process for corrosion protection of magnesium substrate
Sara Kaabi Falahieh Asl,
Sandor Nemeth,
Ming Jen Tan,
Corresponding Author
Sara Kaabi Falahieh Asl
School of Mechanical & Aerospace Engineering, Nanyang Technological University, 639708 Singapore
Singapore Institute Of Manufacturing Technology, 638075 Singapore
Correspondence to: S. Kaabi Falahieh Asl; E-mail address: [email protected]Search for more papers by this authorSandor Nemeth
Singapore Institute Of Manufacturing Technology, 638075 Singapore
Search for more papers by this authorMing Jen Tan
School of Mechanical & Aerospace Engineering, Nanyang Technological University, 639708 Singapore
Search for more papers by this authorSara Kaabi Falahieh Asl,
Sandor Nemeth,
Ming Jen Tan,
Corresponding Author
Sara Kaabi Falahieh Asl
School of Mechanical & Aerospace Engineering, Nanyang Technological University, 639708 Singapore
Singapore Institute Of Manufacturing Technology, 638075 Singapore
Correspondence to: S. Kaabi Falahieh Asl; E-mail address: [email protected]Search for more papers by this authorSandor Nemeth
Singapore Institute Of Manufacturing Technology, 638075 Singapore
Search for more papers by this authorMing Jen Tan
School of Mechanical & Aerospace Engineering, Nanyang Technological University, 639708 Singapore
Search for more papers by this authorAbstract
Ceramic type coatings on metallic implants, such as calcium phosphate (Ca-P), are generally stiff and brittle, potentially leading to the early failure of the bone–implant interface. To reduce material brittleness, polyacrylic acid and carboxymethyl cellulose were used in this study to deposit two types of novel Ca-P/polymer composite coatings on AZ31 magnesium alloy using a one-step hydrothermal process. X-ray diffraction and scanning electron microscopy showed that the deposited Ca-P crystal phase and morphology could be controlled by the type and concentration of polymer used. Incorporation of polymer in the Ca-P coatings reduced the coating elastic modulus bringing it close to that of magnesium and that of human bone. Nanoindentation test results revealed significantly decreased cracking tendency with the incorporation of polymer in the Ca-P coating. Apart from mechanical improvements, the protective composite layers had also enhanced the corrosion resistance of the substrate by a factor of 1000 which is sufficient for implant application. Cell proliferation studies indicated that the composite coatings induced better cell attachment compared with the purely inorganic Ca-P coating, confirming that the obtained composite materials could be promising candidates for surface protection of magnesium for implant application with the multiple functions of corrosion protection, interfacial stress reduction, and cell attachment/cell growth promotion. © 2015 Wiley Periodicals, Inc. J Biomed Mater Res Part B: Appl Biomater, 104B: 1643–1657, 2016.
REFERENCES
- 1Guangling S. Control of biodegradation of biocompatible magnesium alloys. Corrosion Sci 2007; 49: 1696–1701.
- 2Frank W. The history of biodegradable magnesium implants: A review. Acta Biomater 2010; 6: 1680–1692.
- 3Shadanbaz S, Dias GJ. Calcium phosphate coatings on magnesium alloys for biomedical applications: A review. Acta Biomater 2012; 8: 20–30.
- 4Witte F, Fischer J, Nellesen J, Crostack HA, Kaese V, Pisch A, Beckmann F, Windhagen H. In vitro and in vivo corrosion measurements of magnesium alloys. Biomaterials 2006; 27: 1013–1018.
- 5Song G, Song S. A possible biodegradable magnesium implant material. Adv Eng Mater 2007; 9: 298–302.
- 6Tomozawa M, Hiromoto S. Microstructure of hydroxyapatite- and octacalcium phosphate-coatings formed on magnesium by a hydrothermal treatment at various pH values. Acta Mater 2011; 59: 355–363.
- 7Kirkland NT, Birbilis N, Staiger MP. Assessing the corrosion of biodegradable magnesium implants: A critical review of current methodologies and their limitations. Acta Biomater 2012; 8: 925–936.
- 8Xin Y, Hu T, Chu PK. In vitro studies of biomedical magnesium alloys in a simulated physiological environment: A review. Acta Biomater 2011; 7: 1452–1459.
- 9Wang J, Tang J, Zhang P, Li Y, Wang J, Lai Y, Qin L. Surface modification of magnesium alloys developed for bioabsorbable orthopedic implants: A general review. J Biomed Mater Res Part B: Appl Biomater 2012; 100: 1691–1701.
- 10Zhang Y, Zhang G, Wei M. Controlling the biodegradation rate of magnesium using biomimetic apatite coating. J Biomed Mater Res Part B: Appl Biomater 2009; 89: 408–414.
- 11Hornberger H, Virtanen S, Boccaccini AR. Biomedical coatings on magnesium alloys - A review. Acta Biomater 2012; 8: 2442–2455.
- 12Song YW, Shan DY, Han EH. Electrodeposition of hydroxyapatite coating on AZ91D magnesium alloy for biomaterial application. Mater Lett 2008; 62: 3276–3279.
- 13Onoki T, Yamamoto S-Y. Hydroxyapatite ceramics coating on magnesium alloy via a double layered capsule hydrothermal hot-pressing. J Ceram Soc Jpn 2010; 118: 749–752.
- 14Chen Y, Mak AF, Wang M, Li J. Composite coating of bonelike apatite particles and collagen fibers on poly l-lactic acid formed through an accelerated biomimetic coprecipitation process. J Biomed Mater Res Part B: Appl Biomater 2006; 77: 315–322.
- 15Fan Y, Duan K, Wang R. A composite coating by electrolysis-induced collagen self-assembly and calcium phosphate mineralization. Biomaterials 2005; 26: 1623–1632.
- 16Gu XN, Wang X, Li N, Li L, Zheng YF, Miao X. Microstructure and characteristics of the metal-ceramic composite (MgCa-HA/TCP) fabricated by liquid metal infiltration. J Biomed Mater Res Part B: Appl Biomater 2011; 99: 127–134.
- 17Kuroda K, Moriyama M, Ichino R, Okido M, Seki A. Formation and osteoconductivity of hydroxyapatite/collagen composite films using a thermal substrate method in aqueous solutions. Mater Trans 2009; 50: 1190–1195.
- 18Li W, Guan S, Chen J, Hu J, Chen S, Wang L, Zhu S. Preparation and in vitro degradation of the composite coating with high adhesion strength on biodegradable Mg–Zn–Ca alloy. Mater Character 2011; 62: 1158–1165.
- 19Sun L, Berndt CC, Gross KA. Hydroxyapatite/polymer composite flame-sprayed coatings for orthopedic applications. J Biomater Sci Polym Ed 2002; 13: 977–990.
- 20Miao S, Weng W, Li Z, Cheng K, Du P, Shen G, Han G. Electrolytic deposition of octacalcium phosphate/collagen composite coating on titanium alloy. J Mater Sci Mater Med 2009; 20: 131–134.
- 21Amjad Z. The inhibition of dicalcium phosphate dihydrate crystal growth by polycarboxylic acids. Journal of Colloid and Interface Science 1987; 117: 98–103.
- 22He J, Huang T, Gan L, Zhou Z, Jiang B, Wu Y, Gu Z. Collagen-infiltrated porous hydroxyapatite coating and its osteogenic properties: In vitro and in vivo study. J Biomed Mater Res Part A 2012; 100: 1706–1715.
- 23Zhao X, Hu T, Li H, Chen M, Cao S, Zhang L, Hou X. Electrochemically assisted co-deposition of calcium phosphate/collagen coatings on carbon/carbon composites. Appl Surf Sci 2011; 257: 3612–3619.
- 24Zhang XX, Li Q, Li LQ, Zhang P, Wang ZW, Chen FN. Fabrication of hydroxyapatite/stearic acid composite coating and corrosion behavior of coated magnesium alloy. Mater Lett 2012; 88: 76–78.
- 25Bai K, Zhang Y, Fu Z, Zhang C, Cui X, Meng E, Guan S, Hu J. Fabrication of chitosan/magnesium phosphate composite coating and the in vitro degradation properties of coated magnesium alloy. Mater Lett 2012; 73: 59–61.
- 26Liu P, Pan X, Yang W, Cai K, Chen Y. Improved anticorrosion of magnesium alloy via layer-by-layer self-assembly technique combined with micro-arc oxidation. Mater Lett 2012; 75: 118–121.
- 27Hahn B-D, Park D-S, Choi J-J, Ryu J, Yoon W-H, Choi J-H, Ryu J, Yoon WH, Cohi JH, Kim HE, Kim SG. Aerosol deposition of hydroxyapatite–chitosan composite coatings on biodegradable magnesium alloy. Surf Coat Technol 2011; 205: 3112–3118.
- 28Song G, Atrens A. Understanding magnesium corrosion—A framework for improved alloy performance. Adv Eng Mater 2003; 5: 837–858.
- 29De Giglio E, Cafagna D, Ricci MA, Sabbatini L, Cometa S, Ferretti C, et al. Biocompatibility of poly(acrylic acid) thin coatings electro-synthesized onto TiAlV-based implants. J Bioactive Compatible Polym 2010; 25: 374–391.
- 30De Giglio E, Cometa S, Cioffi N, Torsi L, Sabbatini L. Analytical investigations of poly(acrylic acid) coatings electrodeposited on titanium-based implants: A versatile approach to biocompatibility enhancement. Anal Bioanal Chem 2007; 389: 2055–2063.
- 31Ke Y. Preparation of carboxymethyl cellulose based microgels for cell encapsulation. Exp Polym Lett 2014; 8: 841–849.
- 32Shah N, Patel K. Formulation and development of hydrogel for poly acrylamide-co-acrylic acid. J Pharm Sci Biosci Res 2014; 4: 114–120.
- 33Butun S, Ince FG, Erdugan H, Sahiner N. One-step fabrication of biocompatible carboxymethyl cellulose polymeric particles for drug delivery systems. Carbohydr Polym 2011; 86: 636–643.
- 34Uda H, Sugawara Y, Nakasu M. Experimental studies on hydroxyapatite powder-carboxymethyl chitin composite: Injectable material for bone augmentation. J Plast Reconstr Aesthet Surg 2006; 59: 188–196.
- 35Kaabi Falahieh Asl S, Nemeth S, Tan MJ. Hydrothermally deposited protective and bioactive coating for magnesium alloys for implant application. Surf Coat Technol 2014; 258: 931–937.
- 36Yokoi T, Kawashita M, Ohtsuki C. Effects of monocarboxylic acid addition on crystallization of calcium phosphate in a hydrogel matrix. IOP Conf Ser: Mater Sci Eng 2011; 18: 192012.
10.1088/1757-899X/18/19/192012 Google Scholar
- 37Tortet L, Gavarri JR, Nihoul G, Dianoux AJ. Study of protonic mobility in CaHPO4·2H2O (brushite) and CaHPO4 (monetite) by infrared spectroscopy and neutron scattering. J Solid State Chem 1997; 132: 6–16.
- 38Xu J, Butler IS, Gilson DFR. FT-Raman and high-pressure infrared spectroscopic studies of dicalcium phosphate dihydrate (CaHPO4·2H2O) and anhydrous dicalcium phosphate (CaHPO4). Spectrochim Acta Part A: Mol Biomol Spectrosc 1999; 55: 2801–2809.
- 39Chen J, Wang Y, Chen X, Ren L, Lai C, He W, Zhang Q. A simple sol-gel technique for synthesis of nanostructured hydroxyapatite, tricalcium phosphate and biphasic powders. Mater Lett 2011; 65: 1923–1926.
- 40Tonković M, Sikirić M, Babić-Ivančić V. Controversy about β-tricalcium phosphate. Colloids Surf A: Physicochem Eng Aspects 2000; 170: 107–112.
- 41Xie L, Wang L, Jia X, Kuang G, Yang S, Feng H. Effects of glutamic acid shelled PAMAM dendrimers on the crystallization of calcium phosphate in diffusion systems. Polym Bull 2010; 66: 119–132.
- 42Chiu KY, Wong MH, Cheng FT, Man HC. Characterization and corrosion studies of fluoride conversion coating on degradable Mg implants. Surf Coat Technol 2007; 202: 590–598.
- 43Ren M, Cai S, Liu T, Huang K, Wang X, Zhao H, Niu S, Zhang R, Wu X. Calcium phosphate glass/MgF2 double layered composite coating for improving the corrosion resistance of magnesium alloy. J Alloy Compounds 2014; 591: 34–40.
- 44Yokoi T, Kawashita M, Ohtsuki C. Biomimetic mineralization of calcium phosphates in polymeric hydrogels containing carboxyl groups. J Asian Ceram Soc 2013; 1: 155–162.
10.1016/j.jascer.2013.04.003 Google Scholar
- 45Van Phuong N, Moon S. Comparative corrosion study of zinc phosphate and magnesium phosphate conversion coatings on AZ31 Mg alloy. Mater Lett 2014; 122: 341–344.
- 46Kaabi Falahieh Asl S, Nemeth S, Tan MJ. Mechanism of calcium phosphate deposition in a hydrothermal coating process. Surf and Coat Technol 2015; 270: 197–205.
- 47Liu Z-X, Wang X-M, Wang Q, Shen X-C, Liang H, Cui F-Z. Evolution of calcium phosphate crystallization on three functional group surfaces with the same surface density. Cryst Eng Comm 2012; 14: 6695.
- 48McNeill IC, Sadeghi SMT. Thermal stability and degradation mechanisms of poly(acrylic acid) and its salts: Part 1—Poly(acrylic acid). Polym Degrad Stab 1990; 29: 233–246.
- 49Ahmad N, Wahab R, Al-Omar SY. Thermal decomposition kinetics of sodium carboxymethyl cellulose: Model-free methods. Eur J Chem 2014; 5: 247–251.
- 50Zhang J, Liu W, Schnitzler V, Tancret F, Bouler J-M. Calcium phosphate cements for bone substitution: Chemistry, handling and mechanical properties. Acta Biomater 2014; 10: 1035–1049.
- 51Pereda MD, Alonso C, Gamero M, del Valle JA, Fernández Lorenzo de Mele M. Comparative study of fluoride conversion coatings formed on biodegradable powder metallurgy Mg: The effect of chlorides at physiological level. Mater Sci Eng C 2011; 31: 858–865.
- 52Bhushan B, Gupta BK, Azarian MH. Nanoindentation, microscratch, friction and wear studies of coatings for contact recording applications. Wear 1995; 181–183, Part 2:743–758.
- 53Wang HX, Guan SK, Wang X, Ren CX, Wang LG. In vitro degradation and mechanical integrity of Mg-Zn-Ca alloy coated with Ca-deficient hydroxyapatite by the pulse electrodeposition process. Acta Biomater 2010; 6: 1743–1748.
- 54Zhang S, Cao F, Chang L, Zheng J, Zhang Z, Zhang J, Cao C. Electrodeposition of high corrosion resistance Cu/Ni–P coating on AZ91D magnesium alloy. Appl Surf Sci 2011; 257: 9213–9220.
- 55Fan J, Qiu X, Niu X, Tian Z, Sun W, Liu X, Li Y, Li W, Meng J. Microstructure, mechanical properties, in vitro degradation and cytotoxicity evaluations of Mg-1.5Y-1.2Zn-0.44Zr alloys for biodegradable metallic implants. Mater Sci Eng C Mater Biol Appl 2013; 33: 2345–2352.
- 56Yan T, Tan L, Xiong D, Liu X, Zhang B, Yang K. Fluoride treatment and in vitro corrosion behavior of an AZ31B magnesium alloy. Mater Sci Eng C 2010; 30: 740–748.
- 57Chang HI, Wang Y. Cell responses to surface and architecture of tissue engineering scaffolds. In: Eberli D, editor. Regenerative Medicine and Tissue Engineering-Cells and Biomaterials, InTech. 2011. pp 569–588.
- 58Keselowsky BG, Collard DM, García AJ. Surface chemistry modulates fibronectin conformation and directs integrin binding and specificity to control cell adhesion. J Biomed Mater Res Part A 2003; 66A: 247–259.
