Abstract
Recently, zinc (Zn) alloy has been considered as a promising biodegradable material due to its excellent physiological degradable behavior and acceptable biocompatibility. However, poor mechanical performance limits its application as vascular stents. In this study, novel biodegradable Zn-2.2Cu-xMn (x = 0.4, 0.7, and 1.0 wt%) alloys with suitable mechanical performance were investigated. The effects of Mn addition on microstructure, mechanical properties, and in vitro degradation of Zn-2.2Cu-xMn alloys were systematically investigated. After adding Mn, dynamic recrystallization (DRX) during hot extrusion was promoted, resulting in slightly finer grain size, higher DRXed regions ratio, and weaker texture. And volume fraction and number density of second phase precipitates (micron, submicron, and nano-sized ε and MnZn13 phase) and the concentration of (Cu, Mn) in the matrix were increased. Therefore, Zn-2.2Cu-xMn alloys exhibited suitable mechanical performances (strength >310 MPa, elongation >30%) mainly due to the combination effects of grain refinement, solid solution strengthening, second phase precipitation hardening, and texture weakening. Moreover, the alloys maintained good stability of mechanical properties within 18 months and good elongation over 15% even at a high strain rate of 0.1 s−1. In addition, the alloys presented appropriate in vitro degradation rates in a basically uniform degradation mode and acceptable in vitro cytocompatibility. The above results indicated that the newly designed biodegradable Zn-2.2Cu-0.4Mn alloy with suitable comprehensive mechanical properties, appropriate degradation behavior, and acceptable cytocompatibility is a promising candidate for vascular stents.
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