Bio-Adaption between Magnesium Alloy Stent and the Blood Vessel: A Review

doi:10.1016/j.jmst.2015.12.018

Abstract

Abstract:

Biodegradable magnesium (Mg) alloy stents are the most promising next generation of bio-absorbable stents. In this article, we summarized the progresses on the in vitro studies, animal testing and clinical trials of biodegradable Mg alloy stents in the past decades. These exciting findings led us to propose the importance of the concept “bio-adaption” between the Mg alloy stent and the local tissue microenvironment after implantation. The healing responses of stented blood vessel can be generally described in three overlapping phases: inflammation, granulation and remodeling. The ideal bio-adaption of the Mg alloy stent, once implanted into the blood vessel, needs to be a reasonable function of the time and the space/dimension. First, a very slow degeneration of mechanical support is expected in the initial four months in order to provide sufficient mechanical support to the injured vessels. Although it is still arguable whether full mechanical support in stented lesions is mandatory during the first four months after implantation, it would certainly be a safety design parameter and a benchmark for regulatory evaluations based on the fact that there is insufficient human in vivo data available, especially the vessel wall mechanical properties during the healing/remodeling phase. Second, once the Mg alloy stent being degraded, the void space will be filled by the regenerated blood vessel tissues. The degradation of the Mg alloy stent should be 100% completed with no residues, and the degradation products (e.g., ions and hydrogen) will be helpful for the tissue reconstruction of the blood vessel. Toward this target, some future research perspectives are also discussed.

Key words: Mg stent, Bio-adaptation, Vessel, Wound healing

Ma Jun,Zhao Nan,Betts Lexxus,Zhu Donghui. Bio-Adaption between Magnesium Alloy Stent and the Blood Vessel: A Review[J]. J. Mater. Sci. Technol., 2016, 32(9): 815-826.

Figures/Tables 8

References

[1]	N. Zhao, N. Watson, Z. Xu, Y. Chen, J. Waterman, J. Sankar, D. Zhu.PLoS ONE, 9(2014), p. e98674
[2]	H. Gong, K. Wang, R. Strich, J.G. Zhou. J. Biomed. Mater.Res. Part B Appl. Biomater, 103(2015), pp. 1632-1640
[3]	R. Erbel, C. Di Mario, J. Bartunek, J. Bonnier, B. de Bruyne, F.R. Eberli, P. Erne, M. Haude, B. Heublein, M. Horrigan. Lancet, 369(2007), pp. 1869-1875
[4]	M. Haude, R. Erbel, P. Erne, S. Verheye, H. Degen, D. B?se, P. Vermeersch, I. Wijnbergen, N. Weissman, F. Prati.Lancet, 381(2013), pp. 836-844
[5]	Y. Zheng, X. Gu, F. Witte. Mater.Sci. Eng. R, 77(2014), pp. 1-34
[6]	A. Drynda, T. Hassel, R. Hoehn, A. Perz, F.W. Bach, M. Peuster. J.Biomed. Mater. Res. A, 93(2010), pp. 763-775
[7]	L. Mao, G. Yuan, J. Niu, Y. Zong, W. Ding. Mater.Sci. Eng. C, 33(2013), pp. 242-250
[8]	W. Zhou, Y. Zheng, M. Leeflang, J. Zhou.Acta Biomater, 9(2013), pp. 8488-8498
[9]	M. Guo, L. Cao, P. Lu, Y. Liu, X. Xu. J.Mater. Sci. Mater. Med, 22(2011), pp. 1735-1740
[10]	M. Bornapour, N. Muja, D. Shum-Tim, M. Cerruti, M. Pekguleryuz.Acta Biomater, 9(2013), pp. 5319-5330
[11]	L. Mao, L. Shen, J. Niu, J. Zhang, W. Ding, Y. Wu, R. Fan, G. Yuan.Nanoscale, 5(2013), pp. 9517-9522
[12]	P. Pérez, E. Onofre, S. Cabeza, I. Llorente, J. Del Valle, M. García-Alonso, P. Adeva, M. Escudero. Corros.Sci, 69(2013), pp. 226-235
[13]	X. Gu, W. Zhou, Y. Zheng, Y. Cheng, S. Wei, S. Zhong, T. Xi, L. Chen.Acta Biomater, 6(2010), pp. 4605-4613
[14]	J. Wiebe, H.M. Nef, C.W. Hamm. J. Am. Coll.Cardiol, 64(2014), pp. 2541-2551
[15]	A.C. H?nzi, A.S. Sologubenko, P.J. Uggowitzer.Mater. Sci. Forum, 618(2009), pp. 75-82
[16]	A.C. H?nzi, I. Gerber, M. Schinhammer, J.F. L?ffler, P.J. Uggowitzer.Acta Biomater, 6(2010), pp. 1824-1833
[17]	A. Loos, R. Rohde, A. Haverich, S. Barlach. Macromol.Symp, 253(2007), pp. 103-108
[18]	P. Lu, L. Cao, Y. Liu, X. Xu, X. Wu. J.Biomed. Mater. Res. Part B Appl. Biomater, 96(2011), pp. 101-109
[19]	P. Lu, H. Fan, Y. Liu, L. Cao, X. Wu, X. Xu.Colloids Surf. B Biointerfaces, 83(2011), pp. 23-28
[20]	N. Li, Y. Zheng. J.Mater. Sci. Technol, 29(2013), pp. 489-502
[21]	B. Heublein, R. Rohde, V. Kaese, M. Niemeyer, W. Hartung, A. Haverich.Heart, 89(2003), pp. 651-656
[22]	C. Di Mario, H. Griffiths, O. Goktekin, N. Peeters, J. Verbist, M. Bosiers, K. Deloose, B. Heublein, R. Rohde, V. Kasese. J.Interv. Cardiol, 17(2004), pp. 391-395
[23]	H. Li, H. Zhong, K. Xu, K. Yang, J. Liu, B. Zhang, F. Zheng, Y. Xia, L. Tan, D. Hong. J.Endovasc. Ther, 18(2011), pp. 407-415
[24]	R. Waksman, R. Pakala, P.K. Kuchulakanti, R. Baffour, D. Hellinga, R. Seabron, F.O. Tio, E. Wittchow, S. Hartwig, C. Harder. Catheter.Cardiovasc. Interv, 68(2006), pp. 607-617
[25]	T. L.P.Slottow, R. Pakala, T. Okabe, D. Hellinga, R.J. Lovec, F. O. Tio, A.B. Bui, R. Waksman. Cardiovasc. Revasculariz. Med, 9(2008), pp. 248-254
[26]	A. Drynda, J. Seibt, T. Hassel, F.W. Bach, M. Peuster. J.Biomed. Mater. Res. A, 101(2013), pp. 33-43
[27]	P. Peeters, M. Bosiers, J. Verbist, K. Deloose, B. Heublein. J.Endovasc. Ther, 12(2005), pp. 1-5
[28]	M. Bosiers, A.I. Investigators.Cardiovasc. Intervent. Radiol, 32(2009), pp. 424-435
[29]	P. Zartner, R. Cesnjevar, H. Singer, M. Weyand. Catheter.Cardiovasc. Interv, 66(2005), pp. 590-594
[30]	D. Schranz, P. Zartner, I. Michel-Behnke, H. Akintürk. Catheter.Cardiovasc. Interv, 67(2006), pp. 671-673
[31]	C. J.McMahon, P. Oslizlok, K.P. Walsh. Catheter. Cardiovasc. Interv, 69(2007), pp. 735-738
[32]	R. Waksman, R. Erbel, C. Di Mario, J. Bartunek, B. de Bruyne, F.R. Eberli, P. Erne, M. Haude, M. Horrigan, C. Ilsley. JACC Cardiovasc. Interv, 2(2009), pp. 312-320
[33]	P.A. Corning.J. Bioecon, 2(2000), pp. 41-86
[34]	R.W. Ogden, G.A. Holzapfel. Mechanics of Biological Tyear. Springer (2006)
[35]	A. Pries, B. Reglin, T. Secomb. Am. J. Physiol.Heart Circ. Physiol, 281(2001), pp. H1015-H1025
[36]	A. Pries, T. Secomb, P. Gaehtgens. Am. J. Physiol.Heart Circ. Physiol, 275(1998), pp. H349-H360
[37]	A.R. Pries, B. Reglin, T.W. Secomb.Hypertension, 46(2005), pp. 725-731
[38]	A.R. Pries, T.W. Secomb, P. Gaehtgens.Hypertension, 33(1999), pp. 153-161
[39]	T. Seo, L.G. Schachter, A.I. Barakat.Ann. Biomed. Eng, 33(2005), pp. 444-456
[40]	D.C. Warltier, J.R. Kersten, P.S. Pagel.Biomed. Eng. Online, 5(2006), p. 40
[41]	F.J. Gijsen, F. Migliavacca, S. Schievano, L. Socci, L. Petrini, A. Thury, J.J. Wentzel, A. van der Steen, P. Serruys, G. Dubini. Biomed. Eng. Online, 7(2008), p. 23
[42]	J. Grogan, B. O'Brien, S. Leen, P. McHugh. Acta Biomater, 7(2011), pp. 3523-3533
[43]	H. Wang, S. Guan, X. Wang, C. Ren, L. Wang.Acta Biomater, 6(2010), pp. 1743-1748
[44]	J. Kuhlmann, I. Bartsch, E. Willbold, S. Schuchardt, O. Holz, N. Hort, D. H?che, W.R. Heineman, F. Witte.Acta Biomater, 9(2013), pp. 8714-8721
[45]	F. Witte, H. Ulrich, M. Rudert, E. Willbold. J.Biomed. Mater. Res. A, 81(2007), pp. 748-756
[46]	F. Witte, V. Kaese, H. Haferkamp, E. Switzer, A. Meyer-Lindenberg, C.J. Wirth, H. Windhagen.Biomaterials, 26(2005), pp. 3557-3563
[47]	R. Zeng, W. Dietzel, F. Witte, N. Hort, C. Blawert. Adv.Eng. Mater, 10(2008), pp. B3-B14
[48]	S. De Bock, F. Iannaccone, G. De Santis, M. De Beule, P. Mortier, B. Verhegghe, P. Segers. J.Biomech, 45(2012), pp. 1353-1359
[49]	J. Gomez-Lara, H.M.Garcia-Garcia, Y. Onuma, S. Garg, E. Regar, B. De Bruyne, S. Windecker, D. McClean, L. Thuesen, D. Dudek. JACC Cardiovasc. Interv, 3(2010), pp. 1190-1198
[50]	M.V. e Silva, J.R. Costa, A. Abizaid, R. Staico, D. Taiguara, T.C. Borghi, R. Costa, D. Chamié, A.G. Sousa, J.E. Sousa. Rev. Bras. Cardiol. Invas. Eng. Vers, 21(2013), pp. 332-337
[51]	M. Conti, D. Van Loo, F. Auricchio, M. De Beule, G. De Santis, B. Verhegghe, S. Pirrelli, A. Odero. J.Endovasc. Ther, 18(2011), pp. 397-406
[52]	G. Sangiorgi, G. Melzi, P. Agostoni, C. Cola, F. Clementi, P. Romitelli, R. Virmani, A. Colombo. Ann.Ist. Super. Sanita, 43(2006), pp. 89-100
[53]	D. Ma, G.F. Dargush, S.K. Natarajan, E.I. Levy, A.H. Siddiqui, H. Meng. J.Biomech, 45(2012), pp. 2256-2263
[54]	C.C. Phatouros, R.T. Higashida, A.M. Malek, P.M. Meyers, T.E. Lempert, C.F. Dowd, V.V. Halbach.AJNR Am. J. Neuroradiol, 21(2000), pp. 732-738
[55]	R. Rieu, P. Barragan, V. Garitey, P.O. Roquebert, J. Fuseri, P. Commeau, J. Sainsous. Catheter.Cardiovasc. Interv, 59(2003), pp. 496-503
[56]	G.A. Holzapfel, M. Stadler, T.C. Gasser. J. Biomech.Eng, 127(2005), pp. 166-180
[57]	J.F. LaDisa, D.A. Hettrick, L.E. Olson, I. Guler, E.R. Gross, T.T. Kress, J.R. Kersten, D.C. Warltier, P.S. Pagel. J. Appl. Physiol, 93(2002), pp. 1939-1946
[58]	J.F. LaDisa, L.E. Olson, D.A. Hettrick, D.C. Warltier, J.R. Kersten, P.S. Pagel. Biomed. Eng. Online, 4(2005), p. 59
[59]	J. Lévesque, H. Hermawan, D. Dubé, D. Mantovani.Acta Biomater, 4(2008), pp. 284-295
[60]	J. Wang, V. Giridharan, V. Shanov, Z. Xu, B. Collins, L. White, Y. Jang, J. Sankar, N. Huang, Y. Yun.Acta Biomater, 10(2014), pp. 5213-5223
[61]	C. Liu, Y. Xin, X. Tian, P.K. Chu. J. Mater.Res, 22(2007), pp. 1806-1814
[62]	C. Liu, Y. Wang, R. Zeng, X. Zhang, W. Huang, P. Chu. Corros.Sci, 52(2010), pp. 3341-3347
[63]	A. Yamamoto, S. Hiromoto. Mater.Sci. Eng. C, 29(2009), pp. 1559-1568
[64]	D. Pierson, J. Edick, A. Tauscher, E. Pokorney, P. Bowen, J. Gelbaugh, J. Stinson, H. Getty, C.H. Lee, J. Drelich. J.Biomed. Mater. Res. Part B Appl. Biomater, 100(2012), pp. 58-67
[65]	L. Tang, J.W. Eaton. J. Exp.Med, 178(1993), pp. 2147-2156
[66]	D.T. Luttikhuizen, M.C. Harmsen, M.J.V.Luyn. Tyear Eng, 12(2006), pp. 1955-1970
[67]	B. Dahlb?ck.Lancet, 355(2000), pp. 1627-1632
[68]	J.M. Anderson, A. Rodriguez, D.T. Chang.Semin. Immunol, 20(2008), pp. 86-100
[69]	S.T. Smiley, J.A. King, W.W. Hancock.J. Immunol, 167(2001), pp. 2887-2894
[70]	M. Mosesson. J.Thromb. Haemost, 3(2005), pp. 1894-1904
[71]	J. Zdolsek, J.W. Eaton, L. Tang. J.Transl. Med, 5(2007), pp. 31-36
[72]	C.A. Feghali, T.M. Wright.Front. Biosci, 2(1997), pp. d12-d26
[73]	J.M. Anderson.Ann. Rev. Mater. Res, 31(2001), pp. 81-110
[74]	J. Li, J. Chen, R. Kirsner. Clin.Dermatol, 25(2007), pp. 9-18
[75]	J.E. Babensee, J.M. Anderson, L.V.xMcIntire, A.G. Mikos. Adv. Drug Deliv. Rev, 33(1998), pp. 111-139
[76]	R.G. Huntsman, B.A.L.Hurn, H. Lehmann. J. Clin. Pathol, 13(1960), pp. 99-101
[77]	L. Mussoni, L. Sironi, L. Tedeschi, A.M. Calvio, S. Colli, E. Tremoli. Thromb.Haemost, 86(2001), pp. 1292-1295
[78]	F. Sekiya, T. Yamashita, H. Atoda, Y. Komiyama, T. Morita. J.Biol. Chem, 270(1995), pp. 14325-14331
[79]	F. Sekiya, M. Yoshida, T. Yamashita, T. Morita. J.Biol. Chem, 271(1996), pp. 8541-8544
[80]	E. Gueux, E. Rock, A. Mazur, Y. Rayssiguier. Eur.J. Nutr, 41(2002), pp. 197-202
[81]	C. Malpuech-Brugère, E. Rock, C. Astier, W. Nowacki, A. Mazur, Y. Rayssiguier.Life Sci, 63(1998), pp. 1815-1822
[82]	F. Bussiere, A. Mazur, J. Fauquert, A. Labbe, Y. Rayssiguier, A. Tridon. Magnes.Res, 15(2002), pp. 43-48
[83]	Y. Chen, Z. Xu, C. Smith, J. Sankar.Acta Biomater, 10(2014), pp. 4561-4573
[84]	D. Persaud-Sharma, A. McGoron. J. Biomim. Biomater.Biomed. Eng, 12(2012), pp. 25-39
[85]	G.E.J .Poinern, S. Brundavanam, D. Fawcett. Am. J. Biomed. Eng, 2(2012), pp. 218-240
[86]	F. Witte.Acta Biomater, 6(2010), pp. 1680-1692
[87]	A. Meyer-Lindenberg, H. Windhugen, F. Witte. Google Patents, (2002)
[88]	B. Zberg, P.J. Uggowitzer, J.F. L?ffler.Nat. Mater, 8(2009), pp. 887-891
[89]	G. Song. Corros.Sci, 49(2007), pp. 1696-1701
[90]	K. Xie, Y. Yu, Z. Zhang, W. Liu, Y. Pei, L. Xiong, L. Hou, G. Wang.Shock, 34(2010), pp. 495-501
[91]	M. Kajiya, M.J. Silva, K. Sato, K. Ouhara, T. Kawai. Biochem.Biophys. Res. Commun, 386(2009), pp. 11-15
[92]	Y. Huang, K. Xie, J. Li, N. Xu, G. Gong, G. Wang, Y. Yu, H. Dong, L. Xiong.Brain Res, 1378(2011), pp. 125-136
[93]	C. Janning, E. Willbold, C. Vogt, J. Nellesen, A. Meyer-Lindenberg, H. Windhagen, F. Thorey, F. Witte.Acta Biomater, 6(2010), pp. 1861-1868
[94]	V. Menkin. Am.J. Pathol, 10(1934), pp. 193-210
[95]	T.R. de Nadai, M.N. de Nadai, A.A.S. Albuquerque, M.T.M. de Carvalho, A.C. Celotto, P.R.B. Evora. Int. J. Inflam, 2013 (2013), p. 601424
[96]	T.A. Heming, S.K. Dave, D.M. Tuazon, A.K. Chopra, J.W. Peterson, A. Bidani. Clin.Sci.(Lond.), 101(2001), pp. 267-274
[97]	Y. Kato, S. Ozawa, C. Miyamoto, Y. Maehata, A. Suzuki, T. Maeda, Y. Baba.Cancer Cell Int, 13(2013), p. 89
[98]	B. King, S. Wildman, L. Ziganshina, J. Pintor, G. Burnstock. Br.J. Pharmacol, 121(1997), pp. 1445-1453
[99]	V. Menkin. Br.Med. J., 1(1960), pp. 1521-1528
[100]	K.H. Steen, A.E. Steen, P.W. Reeh.J. Neurosci, 15(1995), pp. 3982-3989
[101]	A.S. Trevani, G. Andonegui, M. Giordano, D.H. López, R. Gamberale, F. Minucci, J.R. Geffner.J. Immunol, 162(1999), pp. 4849-4857
[102]	L.A. Schneider, A. Korber, S. Grabbe, J. Dissemond. Arch.Dermatol. Res, 298(2007), pp. 413-420
[103]	T.A. Heming, N.N. Bulayeva, A. Bidani. Clin.Sci, 105(2003), pp. 21-28
[104]	F. Witte, J. Fischer, J. Nellesen, H.A. Crostack, V. Kaese, A. Pisch, F. Beckmann, H. Windhagen.Biomaterials, 27(2006), pp. 1013-1018
[105]	B. Leblebicioglu, J.S. Lim, A.C. Cario, F.M. Beck, J.D. Walters.J. Periodontol, 67(1996), pp. 472-477
[106]	M. Corbel, C. Belleguic, E. Boichot, V. Lagente.Cell Biol. Toxicol, 18(2002), pp. 51-61
[107]	J. Han, Y. Jiang, Z. Li, V. Kravchenko, R. Ulevitch.Nature, 386(1997), pp. 296-299
[108]	K. Stathopoulou, C. Gaitanaki, I. Beis. J.Exp. Biol, 209(2006), pp. 1344-1354
[109]	D. Rouse, W.N. Suki.Kidney Int, 38(1990), pp. 700-708
[110]	F. Feyerabend, J. Fischer, J. Holtz, F. Witte, R. Willumeit, H. Drücker, C. Vogt, N. Hort.Acta Biomater, 6(2010), pp. 1834-1842
[111]	A. Drynda, N. Deinet, N. Braun, M. Peuster. J.Biomed. Mater. Res. A, 91(2009), pp. 360-369
[112]	S.M. Hirst, A.S. Karakoti, R.D. Tyler, N. Sriranganathan, S. Seal, C.M. Reilly.Small, 5(2009), pp. 2848-2856
[113]	M.B. Kolli, N.D. Manne, R. Para, S.K. Nalabotu, G. Nandyala, T. Shokuhfar, K. He, A. Hamlekhan, J.Y. Ma, P.S. Wehner.Biomaterials, 35(2014), pp. 9951-9962
[114]	P. Zartner, M. Buettner, H. Singer, M. Sigler. Catheter.Cardiovasc. Interv, 69(2007), pp. 443-446
[115]	T. Velnar, T. Bailey, V. Smrkolj. J.Int. Med. Res, 37(2009), pp. 1528-1542
[116]	P. Teller, T.K. White.Perioper. Nurs. Clin, 6(2011), pp. 159-170
[117]	O. Maltseva, P. Folger, D. Zekaria, S. Petridou, S.K. Masur.Invest. Ophthalmol. Vis. Sci, 42(2001), pp. 2490-2495
[118]	S. Meran, D. Thomas, P. Stephens, J. Martin, T. Bowen, A. Phillips, R. Steadman. J.Biol. Chem, 282(2007), pp. 25687-25697
[119]	M.A. Costa, D.I. Simon.Circulation, 111(2005), pp. 2257-2273
[120]	E.R. Edelman, C. Rogers. Am.J. Cardiol, 81(1998), pp. 4E-6E
[121]	J.S. Forrester, M. Fishbein, R. Helfant, J. Fagin. J.Am. Coll. Cardiol, 17(1991), pp. 758-769
[122]	M. Flanagan. J.Wound Care, 9(2000), pp. 299-300
[123]	B.D. Ratner. J. Control.Release, 78(2002), pp. 211-218
[124]	J.J. Grzesiak, G.E. Davis, D. Kirchhofer, M.D. Pierschbacher.J. Cell Biol, 117(1992), pp. 1109-1117
[125]	J.J. Grzesiak, M.D. Pierschbacher. J. Clin.Invest, 95(1995), pp. 227-233
[126]	E.C. Breen, K. Tang. J.Cell. Biochem, 88(2003), pp. 848-854
[127]	A. Lengheden, L. Jansson. Eur.J. Oral Sci, 103(1995), pp. 148-155
[128]	C.L. Lowry, G. McGeehan, H. Le Vine.Proteins Struct. Funct. Genet, 12(1992), pp. 42-48
[129]	H. Birkedal-Hansen, C.M. Cobb, R.E. Taylor, H. Fullmer. J.Biol. Chem, 251(1976), pp. 3162-3168
[130]	N. Zhao, D. Zhu.Metallomics, 7(2015), pp. 113-123
[131]	J.A. Maier, D. Bernardini, Y. Rayssiguier, A. Mazur. Biochim.Biophys. Acta, 1689(2004), pp. 6-12
[132]	K.A. Lapidos, E.C. Woodhouse, E.C. Kohn, L. Masiero.Angiogenesis, 4(2001), pp. 21-28
[133]	M. Badar, H. Lünsdorf, F. Evertz, M.I. Rahim, B. Glasmacher, H. Hauser, P.P. Mueller.Acta Biomater, 9(2013), pp. 7580-7589
[134]	E. Willbold, K. Kalla, I. Bartsch, K. Bobe, M. Brauneis, S. Remennik, D. Shechtman, J. Nellesen, W. Tillmann, C. Vogt.Acta Biomater, 9(2013), pp. 8509-8517
[135]	E. Willbold, X. Gu, D. Albert, K. Kalla, K. Bobe, M. Brauneis, C. Janning, J. Nellesen, W. Czayka, W. Tillmann.Acta Biomater, 11(2015), pp. 554-562
[136]	E. Zhang, L. Xu, G. Yu, F. Pan, K. Yang. J.Biomed. Mater. Res. A, 90(2009), pp. 882-893
[137]	A.F. Drew, H. Liu, J.M. Davidson, C.C. Daugherty, J.L. Degen.Blood, 97(2001), pp. 3691-3698
[138]	H.C. Grillo.Ann. Thorac. Surg, 73(2002), pp. 1995-2004
[139]	A. Young, C.E.McNaught. Surgery (Oxford), 29(2011), pp. 475-479
[140]	M.B. Witte, A. Barbul. Surg.Clin. North Am, 77(1997), pp. 509-528
[141]	M. Madlener, W.C. Parks, S. Werner. Exp.Cell Res, 242(1998), pp. 201-210
[142]	G.S. Schultz, A. Wysocki.Wound Repair Regen, 17(2009), pp. 153-162
[143]	N. Pages, B. Gogly, G. Godeau, S. Igondjo-Tchen, P. Maurois, J. Durlach, P. Bac. Magnes.Res, 16(2003), pp. 43-48
[144]	S. Razaq, R.J. Wilkins, J.P. Urban.Eur. Spine J., 12(2003), pp. 341-349
[145]	Y. Okada, K. Naka, K. Kawamura, T. Matsumoto, I. Nakanishi, N. Fujimoto, H. Sato, M. Seiki. Lab.Invest, 72(1995), pp. 311-322
[146]	M.R. Ward, G. Pasterkamp, A.C. Yeung, C. Borst.Circulation, 102(2000), pp. 1186-1191
[147]	A. Sch?mig, A. Kastrati, H. Mudra, R. Blasini, H. Schühlen, V. Klauss, G. Richardt, F.J. Neumann.Circulation, 90(1994), pp. 2716-2724
[148]	H. Hermawan, D. Dubé, D. Mantovani.Acta Biomater, 6(2010), pp. 1693-1697
[149]	G.G. Stefanini, D.R.Holmes Jr. N. Engl. J. Med, 368(2013), pp. 254-265
[150]	M. Haude, R. Erbel, P. Erne, S. Verheye, P. Vermeersch, H. Degen, D. Boese, R. Waksman, N. Weissman, F. Prati. J.Am. Coll. Cardiol, 62(2013), p. B13

Alloy	Cell type	Viability	Hemocompatibility	Culture time (day)	Authors and references
MgCa 0.4%	HUVEC; HUVSMC	<5%; ~90%	-	10	Drynda et?al.[6]
MgCa 0.6%		<5%; ~80%
MgCa 0.8%		<5%; ~90%
MgCa 1.2%		<5%; ~70%
MgCa 2.0%		<5%; ~70%
Mg-Nd-Zn-Zr	HUVEC cell line EA.hy926	10% Extract: ~95%50% Extract: ~85%	Hemolysis ratio: 52%	1	Mao et?al.[7]
		10% Extract: ~110%50% Extract: ~110%		3
		10% Extract: ~?15%50% Extract: ~120%		5
Mg3.5Li	HUVEC cell line ECV304; rodent VSMC	~85%; ~135%	Hemolysis ratio: ~3.8%Adhered platelets: ~9000	1	Zhou et?al.[8]
		~90%; ~80%		3
		~87%; ~80%		5
Mg8.5Li	HUVEC cell line ECV304; rodent VSMC	~95%; ~200%	Hemolysis ratio: ~3%Adhered platelets: ~9000	1	Zhou et?al.[8]
		~80%; ~110%		3
		~80%; ~105%		5
Mg8.5Li1Al	HUVEC cell line ECV304; rodent VSMC	~93%; ~198%	Hemolysis ratio: ~4%Adhered platelets: ~5000	1	Zhou et?al.[8]
		~75%; ~100%		3
		~90%; ~90%		5
Mg3.5Li2Al2RE	HUVEC cell line ECV304; rodent VSMC	~80%; ~125%	Hemolysis ratio: ~4.2%Adhered platelets: ~5000	1	Zhou et?al.[8]
		~80%; ~75%		3
		~90%; ~70%		5
Mg3.5Li4Al2RE	HUVEC cell line ECV304; rodent VSMC	~80%; ~125%	Hemolysis ratio: ~4.2%Adhered platelets: ~13?000	1	Zhou et?al.[8]
		~80%; ~90%		3
		~70%; ~90%		5
Mg8.5Li2Al2RE	HUVEC cell line ECV304; rodent VSMC	~40%; ~105%	Hemolysis ratio:~7.5%Adhered platelets: ~3000	1	Zhou et?al.[8]
		~75%; ~75%		3
		~70%; ~70%		5
WE42	HUVEC	~75%	-	1	Guo et?al.[9]
Mg-0.5Sr	HUVEC	~98%	-	1	Bornapour et?al.[10]
		~102%		4
		~112%		7
WE43	HUVEC	~104%	-	1	Bornapour et?al.[10]
		~110%		4
		~104%		7
Mg-2.5Nd-0.2Zn-0.4Zr	HUVEC	10% Extract: ~95%50% Extract: ~90%	-	1	Mao et?al.[11]
		10% Extract: ~110%50% Extract: ~110%		3
		10% Extract: ~110%50% Extract: ~120%		5

Alloy	Cell type	Viability	Hemocompatibility	Culture time (day)	Authors and references
MgCa 0.4%	HUVEC; HUVSMC	<5%; ~90%	-	10	Drynda et?al.[6]
MgCa 0.6%		<5%; ~80%
MgCa 0.8%		<5%; ~90%
MgCa 1.2%		<5%; ~70%
MgCa 2.0%		<5%; ~70%
Mg-Nd-Zn-Zr	HUVEC cell line EA.hy926	10% Extract: ~95%50% Extract: ~85%	Hemolysis ratio: 52%	1	Mao et?al.[7]
		10% Extract: ~110%50% Extract: ~110%		3
		10% Extract: ~?15%50% Extract: ~120%		5
Mg3.5Li	HUVEC cell line ECV304; rodent VSMC	~85%; ~135%	Hemolysis ratio: ~3.8%Adhered platelets: ~9000	1	Zhou et?al.[8]
		~90%; ~80%		3
		~87%; ~80%		5
Mg8.5Li	HUVEC cell line ECV304; rodent VSMC	~95%; ~200%	Hemolysis ratio: ~3%Adhered platelets: ~9000	1	Zhou et?al.[8]
		~80%; ~110%		3
		~80%; ~105%		5
Mg8.5Li1Al	HUVEC cell line ECV304; rodent VSMC	~93%; ~198%	Hemolysis ratio: ~4%Adhered platelets: ~5000	1	Zhou et?al.[8]
		~75%; ~100%		3
		~90%; ~90%		5
Mg3.5Li2Al2RE	HUVEC cell line ECV304; rodent VSMC	~80%; ~125%	Hemolysis ratio: ~4.2%Adhered platelets: ~5000	1	Zhou et?al.[8]
		~80%; ~75%		3
		~90%; ~70%		5
Mg3.5Li4Al2RE	HUVEC cell line ECV304; rodent VSMC	~80%; ~125%	Hemolysis ratio: ~4.2%Adhered platelets: ~13?000	1	Zhou et?al.[8]
		~80%; ~90%		3
		~70%; ~90%		5
Mg8.5Li2Al2RE	HUVEC cell line ECV304; rodent VSMC	~40%; ~105%	Hemolysis ratio:~7.5%Adhered platelets: ~3000	1	Zhou et?al.[8]
		~75%; ~75%		3
		~70%; ~70%		5
WE42	HUVEC	~75%	-	1	Guo et?al.[9]
Mg-0.5Sr	HUVEC	~98%	-	1	Bornapour et?al.[10]
		~102%		4
		~112%		7
WE43	HUVEC	~104%	-	1	Bornapour et?al.[10]
		~110%		4
		~104%		7
Mg-2.5Nd-0.2Zn-0.4Zr	HUVEC	10% Extract: ~95%50% Extract: ~90%	-	1	Mao et?al.[11]
		10% Extract: ~110%50% Extract: ~110%		3
		10% Extract: ~110%50% Extract: ~120%		5

Alloy	Animal type	Implantation time (day)	Inflammation score	Injury score	Neointimal area (mm²)	Minimal luminal diameter VS benchmark control (mm)	Authors and references
AE21	Domestic pigs, left anterior descending artery	10	-	-	-	3.46 vs 3.36	Heublein et?al.[21]
		35	-	-	1.41	1.63 vs 2.59
		56	-	-	2.71	2.48 vs 2.81
WE43	Minipigs, coronary artery	30	-	-	-	1.49 vs 1.34	Di Mario et?al.[22]
WE43	Minipigs, coronary artery	90	-	-	-	1.68 vs 1.33	Di Mario et?al.[22]
AZ31B	New Zealand white rabbits, distal and proximal infrarenal abdominal aorta	30	1.89?±?0.76	1.32?±?0.12	1.44?±?0.04	-	Li et?al.[23]
		60	1.45?±?0.35	1.54?±?0.31	1.41?±?0.08	-
		90	1.16?±?0.19	1.68?±?0.65	1.43?±?0.02	-
		120	1.26?±?0.34	0.79?±?0.54	1.47?±?0.03	-
Sirolimus-eluting AZ31B	-	30	2.26?±?0.34	1.25?±?0.13	0.60?±?0.22	-
		60	1.65?±?0.48	1.48?±?0.26	0.63?±?0.27	-
		90	1.35?±?0.37	1.49?±?0.35	0.57?±?0.14	-
		120	1.31?±?0.42	1.38?±?0.35	0.58?±?0.10	-
AMS (WE43)	Gottingen minipigs, coronary artery	28	-	0.37?±?0.72	1.14?±?0.92	1.51?±?0.46 vs 1.26?±?0.41	Loos et?al.[17]
AMS (WE43)	Gottingen minipigs, coronary artery	56	-	0.12?±?0.24	1.23?±?0.55	1.55?±?0.51 vs 1.09?±?0.25	Loos et?al.[17]
Magic stent (WE43)	Juvenile domestic crossbred swine	3	-	-	-	-	Waksman et?al.[24]
		28	1.89?±?1.07	1.67?±?1.13	34?±?27.8	2.89?±?0.26 vs 3.06?±?0.22
		90	-	0.47?±?0.33	-	1.58?±?0.37 vs 1.42?±?0.56

Alloy	Animal type	Implantation time (day)	Inflammation score	Injury score	Neointimal area (mm²)	Minimal luminal diameter VS benchmark control (mm)	Authors and references
AE21	Domestic pigs, left anterior descending artery	10	-	-	-	3.46 vs 3.36	Heublein et?al.[21]
		35	-	-	1.41	1.63 vs 2.59
		56	-	-	2.71	2.48 vs 2.81
WE43	Minipigs, coronary artery	30	-	-	-	1.49 vs 1.34	Di Mario et?al.[22]
WE43	Minipigs, coronary artery	90	-	-	-	1.68 vs 1.33	Di Mario et?al.[22]
AZ31B	New Zealand white rabbits, distal and proximal infrarenal abdominal aorta	30	1.89?±?0.76	1.32?±?0.12	1.44?±?0.04	-	Li et?al.[23]
		60	1.45?±?0.35	1.54?±?0.31	1.41?±?0.08	-
		90	1.16?±?0.19	1.68?±?0.65	1.43?±?0.02	-
		120	1.26?±?0.34	0.79?±?0.54	1.47?±?0.03	-
Sirolimus-eluting AZ31B	-	30	2.26?±?0.34	1.25?±?0.13	0.60?±?0.22	-
		60	1.65?±?0.48	1.48?±?0.26	0.63?±?0.27	-
		90	1.35?±?0.37	1.49?±?0.35	0.57?±?0.14	-
		120	1.31?±?0.42	1.38?±?0.35	0.58?±?0.10	-
AMS (WE43)	Gottingen minipigs, coronary artery	28	-	0.37?±?0.72	1.14?±?0.92	1.51?±?0.46 vs 1.26?±?0.41	Loos et?al.[17]
AMS (WE43)	Gottingen minipigs, coronary artery	56	-	0.12?±?0.24	1.23?±?0.55	1.55?±?0.51 vs 1.09?±?0.25	Loos et?al.[17]
Magic stent (WE43)	Juvenile domestic crossbred swine	3	-	-	-	-	Waksman et?al.[24]
		28	1.89?±?1.07	1.67?±?1.13	34?±?27.8	2.89?±?0.26 vs 3.06?±?0.22
		90	-	0.47?±?0.33	-	1.58?±?0.37 vs 1.42?±?0.56

Trial name	Stent/Alloy	Number of subjects	Symptoms	Summarized outcomes	Authors and references
-	AMS (WE43)	20 (M10, F10)	Critical limb ischemia	One patient died; primary clinical patency 89.5%	Peeters et?al.[27]
AMS INSIGHT	AMS (WE43)	117	Critical limb ischemia; de novo stenotic or occlusive atherosclerotic disease	Within 30 days, the amputation or death rate was 5.3% vs 5.0% in control group; the 6-month angiographic patency rate was 31.8% vs 58% in control group; no efficacy in the long-term patency compared to percutaneous transluminal angioplasty (PTA)	Bosiers and Investigators[28]
-	AMS (WE43)	1 female preterm baby	Ligation of the left pulmonary artery	On 7th day, reperfusion of the left lung as complete as vascular system allowed and thrombus distal to the stent was dissolved; after 6 weeks, the patient was extubated; 5 months later, the left lung perfusion persisted with a slight difference in size between left and right pulmonary artery	Zartner et?al.[29]
-	AMS (WE43)	A three-week-old male baby	Critical aortic coarctation	At the age of 3 months, ventricular septal defect (VSD) closure had to be performed because of left to right shunting	Schranz et?al.[30]
-	Magic stent (WE43)	A two-month old girl	Pulmonary atresia, VSD, and multiple aortopulmonary collaterals with severely hypoplastic pulmonary arteries	Initial significant increase in vessel diameter at first, but significant restenosis occurred at 4 months	McMahon et?al.[31]
PROGRESS-AMS	AMS (WE43)	63 (M 44, F19)	Ischemic heart disease or silent ischemia and a discrete de novo lesion in coronary artery	Diameter stenosis reduced from 61.5%?±?13.1% to 12.6?±?5.6%; in segment acute gain of 1.41?±?0.46?mm and late loss of 1.08?±?0.49?mm; 4 months later, ischemia-driven target lesion revascularization rate was 23.8%, the overall target lesion revascularization rate was 45% after 1 year	Erbel et?al.[3]
BIOSOLVE-I	Drug-eluting absorbable metal scaffold (DREAMS, WE43)	46	-	2 patients had target lesion failure after 6 months, and at 12 months another patient had same problem; overall target lesion revascularization was 26.7% after 12 months; at 6 months and 12 months, the lumen loss were reduced (0.65?±?0.50?mm and 0.52?±?0.39?mm, respectively) compared to 1.08?±?0.49?mm at 4 months of PROGRESS trial	Haude et?al.[4]