In this work, three widely used commercial Zn alloys (ZA4-1, ZA4-3, ZA6-1) were purchased and prepared by hot extrusion at 200?°C. The microstructure, mechanical properties, corrosion behaviors, biocompatibility and hemocompatibility of Zn alloys were studied with pure Zn as control. Commercial Zn alloys demonstrated increased strength and superb elongation compared with pure Zn. Accelerated corrosion rates and uniform corrosion morphologies were observed in terms of commercial Zn alloys due to galvanic effects between Zn matrix and α-Al phases. 100% extracts of ZA4-1 and ZA6-1 alloys showed mild cytotoxicity while 50% extracts of all samples displayed good biocompatibility. Retardant cell cycle and inhibited stress fibers expression were observed induced by high concentration of Zn2+ releasing during corrosion. The hemolysis ratios of Zn alloys were lower than 1% while the adhered platelets showed slightly activated morphologies. In general, commercial Zn alloys possess promising mechanical properties, appropriate corrosion rates, significantly improved biocompatibility and good hemocompatibility in comparison to pure Zn. It is feasible to develop biodegradable metals based on commercial Zn alloys.
参考文献
| [1] | Y.F. Zheng, X.N. Gu, F. Witte. Mater.Sci. Eng. R Rep, 77(2014), pp. 1-34 |
| [2] | X.N. Gu, Y.F. Zheng.Front China, 4(2010), pp. 111-115 |
| [3] | F. Witte, N. Hort, C. Vogt, S. Cohen, K.U. Kainer, R. Willumeit, F. Feyerabend. Curr.Opin. Solid State Mater. Sci, 12(2008), pp. 63-72 |
| [4] | M.P. Staiger, A.M. Pietak, J. Huadmai, G. Dias.Biomaterials, 27(2006), pp. 1728-1734 |
| [5] | X. Gu, Y. Zheng, Y. Cheng, S. Zhong, T. Xi.Biomaterials, 30(2009), pp. 484-498 |
| [6] | T. Kraus, S.F. Fischerauer, A.C. H?nzi, P.J. Uggowitzer, J.F. L?ffler, A.M. Weinberg.Acta Biomater, 8(2012), pp. 1230-1238 |
| [7] | P.K. Bowen, J. Drelich, R.E. Buxbaum, R.M. Rajachar, J. Goldman. Emerg.Mater. Res, 1(2012), pp. 237-255 |
| [8] | H. Hermawan, A. Purnama, D. Dube, J. Couet, D. Mantovani.Acta Biomater, 6(2010), pp. 1852-1860 |
| [9] | T. Huang, J. Cheng, Y.F. Zheng.Mater. Sci. Eng. C Mater. Biol. Appl, 35(2014), pp. 43-53 |
| [10] | W.J. Lin, D.Y. Zhang, G. Zhang, H.T. Sun, H.P. Qi, L.P. Chen, Z.Q. Liu, R.L. Gao, W. Zheng. Mater.Des, 91(2016), pp. 72-79 |
| [11] | S. Zhang, X. Zhang, C. Zhao, J. Li, Y. Song, C. Xie, H. Tao, Y. Zhang, Y. He, Y. Jiang.Acta Biomater, 6(2010), pp. 626-640 |
| [12] | Z. Li, X. Gu, S. Lou, Y. Zheng.Biomaterials, 29(2008), pp. 1329-1344 |
| [13] | B. Zberg, P.J. Uggowitzer, J.F. L?ffler.Nat. Mater, 8(2009), pp. 887-891 |
| [14] | P.K. Bowen, J. Drelich, J. Goldman. Adv.Mater, 25(2013), pp. 2577-2582 |
| [15] | P.K. Bowen, R.J. Guillory, E.R. Shearier, J.-M. Seitz, J. Drelich, M. Bocks, F. Zhao, J. Goldman. Mater. Sci. Eng. C Mater. Biol. Appl, 56(2015), pp. 467-472 |
| [16] | D. Vojtěch, J. Kubásek, J. ?erák, P. Novák.Acta Biomater, 7(2011), pp. 3515-3522 |
| [17] | J. Kubásek, D. Vojtěch, E. Jablonská, I. Pospí?ilová, J. Lipov, T. Ruml. Mater.Sci. Eng. C Mater. Biol. Appl, 58(2016), pp. 24-35 |
| [18] | H.F. Li, X.H. Xie, Y.F. Zheng, Y. Cong, F.Y. Zhou, K.J. Qiu, X. Wang, S.H. Chen, L. Huang, L. Tian, L. Qin. Sci.Rep, 5(2015), p. 10719 |
| [19] | H. Li, H. Yang, Y. Zheng, F. Zhou, K. Qiu, X. Wang. Mater.Des, 83(2015), pp. 95-102 |
| [20] | X. Liu, J. Sun, F. Zhou, Y. Yang, R. Chang, K. Qiu, Z. Pu, L. Li, Y. Zheng. Mater.Des, 94(2016), pp. 95-104 |
| [21] | X. Liu, J. Sun, Y. Yang, F. Zhou, Z. Pu, L. Li, Y. Zheng. Mater.Lett, 162(2016), pp. 242-245 |
| [22] | E.M. da Costa, C.E. da Costa, F.D. Vecchia, C. Rick, M. Scherer, C.A. dos Santos, B.A. Dedavid. J. Alloy. Compd, 488(2009), pp. 89-99 |
| [23] | M. Al-Maharbi, I. Karaman, G. Purcek. Mater.Sci. Eng. A Struct. Mater, 527(2010), pp. 518-525 |
| [24] | G. Purcek, O. Saray, I. Karaman, T. Kucukomeroglu. Mater.Sci. Eng. A Struct. Mater, 490(2008), pp. 403-410 |
| [25] | Z. Wu, S. Sandl?bes, L. Wu, W. Hu, G. Gottstein, S. Korte-Kerzel.Mater. Sci. Eng. A Struct. Mater, 651(2016), pp. 675-687 |
| [26] | T.K. Ha, J.R. Son, W.B. Lee, C.G. Park, Y.W. Chang.Mater. Sci. Eng. A, 307(2001), pp. 98-106 |
| [27] | G. Pür?ek. J.Mater. Process. Technol, 169(2005), pp. 242-248 |
| [28] | D.I.Mario Carlo, G. Huw, G. Omer, P. Nicolas, V. Jan, B. Marc, D. Koen, H. Bernhard, R. Roland, K. Victor, I. Charles, E. Raimund. J. Interv. Cardiol, 17(2004), pp. 391-395 |
| [29] | H. Tapiero, K.D. Tew.Biomed. Pharmacother, 57(2003), pp. 399-411 |
| [30] | K. Kaur, R. Gupta, S.A. Saraf, S.K. Saraf.Compr. Rev. Food Sci. Food Saf, 13(2014), pp. 358-376 |
| [31] | M. Dermience, G. Lognay, F. Mathieu, P. Goyens. J.Trace Elem. Med. Biol, 32(2015), pp. 86-106 |
| [32] | M.C. Linder, M. Hazeghazam. Am. J. Clin.Nutr, 63(1996), pp. 797S-811S |
| [33] | M. Shike.Gastroenterology, 137(2009), pp. S13-S17 |
| [34] | S. El-Rahman.Pharmacol. Res, 47(2003), pp. 189-194 |
| [35] | J.P. Landsberg, B. McDonald, F. Watt.Nature, 360(1992), pp. 65-68 |
| [36] | N.T. Kirkland, N. Birbilis, M.P. Staiger.Acta Biomater, 8(2012), pp. 925-936 |
| [37] | A.E. Brandes.Smithells Metals Reference Book. Butterworths, Oxford(1992), p. 983 |
| [38] | M. Demirtas, G. Purcek, H. Yanar, Z. Zhang, Z. Zhang. J.Alloy. Compd, 623(2015), pp. 213-218 |
| [39] | F. Rosalbino, E. Angelini, D. Macciò, A. Saccone, S. Delfino. Electrochim.Acta, 54(2009), pp. 1204-1209 |
| [40] | P. Vanysek.Electrochemical Series, CRC Handbook of Chemistry and Physics. New York, (1998), p. 87 |
| [41] | L.J. Yang, X.D. Zeng, Y.M. Zhang, J. He, Z.L. Song.Mater. Corros, 66(2015), pp. 1169-1180 |
| [42] | L. Yang, Y. Zhang, X. Zeng, Z. Song. Corros.Sci, 59(2012), pp. 229-237 |
| [43] | W.R. Osório, C. Brito, L.C. Peixoto, A. Garcia. Electrochim.Acta, 76(2012), pp. 218-228 |
| [44] | Standard F756-08 A. Standard Practice for Assessment of Hemolytic Properties of Materials. ASTM International, West Conshohocken (2013), pp. 1-5 |
| [45] | J. Cheng, B. Liu, Y.H. Wu, Y.F. Zheng. J. Mater. Sci.Technol, 29(2013), pp. 619-627 |
| [46] | G.R. Eagle, R.R. Zombola, R.H. Himes.Biochemistry, 22(1983), pp. 221-228 |
| [47] | G. Marx, J. Krugliak, M. Shaklai. Am.J. Hematol, 38(1991), pp. 161-165 |
| [48] | J. Wu, L. Wang, J. He, C. Zhu.Contraception, 85(2012), pp. 509-518 |
| [49] | N.S. Murni, M.S. Dambatta, S.K. Yeap, G.R. Froemming, H. Hermawan. Mater.Sci. Eng. C Mater. Biol. Appl, 49(2015), pp. 560-566 |
| [50] | J. Ma, N. Zhao, D. Zhu.ACS Biomater. Sci. Eng, 1(2015), pp. 1174-1182 |
| [51] | V.V. Goncharuk, K.A. Nezheradze, E.V. Datskevich. J. Water Chem.Technol, 32(2010), pp. 50-55 |
| [52] | N. Zhao, D.H. Zhu.Metallomics, 7(2015), pp. 113-123 |
| [53] | P. Dolara. Int. J. Food Sci.Nutr, 65(2014), pp. 911-924 |
| [54] | P.C. Ferreira, A. Piai Kde, A.M. Takayanagui, S.I.Segura-Munoz. Rev. Lat. Am. Enfermagem, 16(2008), pp. 151-157 |
| [55] | M.A.Burnatowska-Hledin, G.H. Mayor, K. Lau. Am. J. Physiol, 249(1985), pp. F192-F197 |
| [56] | E. Rokhsat, O. Akhavan. Appl.Surf. Sci, 371(2016), pp. 590-595 |
| [57] | A. Nourmohammadi, R. Rahighi, O. Akhavan, A. Moshfegh. J.Alloy. Compd, 612(2014), pp. 380-385 |
| [58] | O. Akhavan, R. Azimirad, S. Safa. Mater.Chem. Phys, 130(2011), pp. 598-602 |
| [59] | Y.H. Wang, K.J. Li, L. Mao, X. Hu, W.J. Zhao, A. Hu, H.Z. Lian, W.J. Zheng.Biol. Trace Elem. Res, 154(2013), pp. 418-426 |
| [60] | S.H. Wong, R.S. Shih, N.W. Schoene, K.Y. Lei.Am. J. Physiol. Cell Physiol, 294(2008), pp. C1342-C1349 |
| [61] | C. Cayrol, M. Knibiehler, B. Ducommun.Oncogene, 16(1998), pp. 311-320 |
| [62] | D.A. Fletcher, R.D. Mullins.Nature, 463(2010), pp. 485-492 |
上一张
下一张
上一张
下一张
计量
- 下载量()
- 访问量()
文章评分
- 您的评分:
-
10%
-
20%
-
30%
-
40%
-
50%