Tin Silver Alloy as a Biomaterial: Corrosion Characteristics and Cellular Behavior.

Charley M Goodwin, Annsley O Mace, Jeremy L Gilbert
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Abstract

Tin-silver (Sn-Ag) has been used as a permanently implanted biomaterial within the Essure female sterilization device and in dental amalgams; however, little data exist for Sn-Ag's corrosion characteristics and/or cellular interactions. In this study, to assess its suitability as a degradable metallic biomaterial, 95-5 wt% Sn-Ag solder was subjected to corrosion testing including open circuit potential (OCP), electrochemical impedance spectroscopy (EIS), and anodic potentiodynamic polarization in phosphate-buffered saline (PBS) and cell culture media (with serum proteins) at room temperature (25°C) and body temperature (37°C). Cell culture studies were also performed. Mouse pre-osteoblast cells (MC3T3-E1) were cultured in media on Sn-Ag discs and monitored over 24 h at potentials below, around, or above Sn-Ag's breakdown potential, fixed, and then viewed using SEM. Separately, cells on tissue culture plastic were subjected to increasing concentrations of SnCl2 in media for 24 h before a live-dead imaging at each concentration to determine cell viability and area fraction covered when compared with a control well. The results show both passive (in PBS), with a breakdown potential of -250 mV versus Ag/AgCl and active polarization behavior (in AMEM with proteins). EIS results showed polarization resistance (Rp) in the 105 Ωcm2 range but decreased generally with increasing temperature (p < 0.05). Cells were well attached on Sn-Ag surfaces at OCP and below the breakdown potential, but when anodically polarized, cells reduced their spread area and became more spherical, indicating less viability. SnCl2 exhibited a dose-dependent killing effect on MC3T3 cells with a lethal dose for 50% of about 0.5 mM. The results of these experiments show that Sn-Ag alloys can be considered as degradable metallic biomaterials.

作为生物材料的锡银合金:腐蚀特性与细胞行为
锡银(Sn-Ag)已被用作 Essure 女性绝育装置和牙科汞合金中永久植入的生物材料;然而,有关锡银的腐蚀特性和/或细胞相互作用的数据却很少。在本研究中,为了评估其作为可降解金属生物材料的适用性,对 95-5 wt% 锡-银焊料进行了腐蚀测试,包括在室温(25°C)和体温(37°C)下,在磷酸盐缓冲盐水(PBS)和细胞培养基(含血清蛋白)中进行开路电位(OCP)、电化学阻抗光谱(EIS)和阳极电位极化。还进行了细胞培养研究。在培养基中将小鼠前成骨细胞(MC3T3-E1)培养在锡银圆盘上,在低于、接近或高于锡银击穿电位的情况下进行 24 小时的监测,固定细胞,然后用扫描电镜观察。另外,将组织培养塑料上的细胞置于介质中浓度不断增加的 SnCl2 中培养 24 小时,然后在每种浓度下进行活体死亡成像,以确定细胞存活率以及与对照孔相比的覆盖面积。结果显示了被动极化行为(在 PBS 中)和主动极化行为(在含有蛋白质的 AMEM 中),前者对 Ag/AgCl 的击穿电位为 -250 mV。EIS 结果显示,极化电阻(Rp)在 105 Ωcm2 范围内,但随着温度的升高,极化电阻普遍下降(p 2 对 MC3T3 细胞有剂量依赖性杀伤作用,50% 的致死剂量约为 0.5 mM)。这些实验结果表明,锡银合金可被视为可降解的金属生物材料。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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