Influence of hot rolling parameters on microstructure and biodegradability of Mg–1Ca alloy in simulated body fluid

“…The white particles, which are negatively charged apatite nuclei, absorb Ca 2+ cations from the environment 23 . The resulted calcium-rich positively charged surface consumes PD 4 3-anion of the fluid. The process continues sequentially to form bone-like and needle-shaped bone-like apatite which can be observed in the alloys containing 3 and 4% calcium, respectively (Figures 6d and f).…”

“…However, pH value of the solution decreased for the alloys containing 3 and 4% calcium. These samples produced more Ca 2+ cation which consumes PD 4 3-anion during the formation of bone-like apatite. The preferential growth of the process product formed needle-shaped bone-like apatite.…”

“…In recent years, there has been an indisputable tendency to use magnesium and its alloys in implants or bone grafts as they have mechanical properties similar to human bone and are biocompatible and biodegradable both in-vivo and in-vitro [2][3][4] . Furthermore, in comparison with polymeric biodegradable implants, tensile yield strength and Young's modulus are higher in magnesium and its alloys 5 .…”

Effect of calcium content on the microstructure, hardness and in-vitro corrosion behavior of biodegradable Mg-Ca binary alloy

“…The white particles, which are negatively charged apatite nuclei, absorb Ca 2+ cations from the environment 23 . The resulted calcium-rich positively charged surface consumes PD 4 3-anion of the fluid. The process continues sequentially to form bone-like and needle-shaped bone-like apatite which can be observed in the alloys containing 3 and 4% calcium, respectively (Figures 6d and f).…”

“…However, pH value of the solution decreased for the alloys containing 3 and 4% calcium. These samples produced more Ca 2+ cation which consumes PD 4 3-anion during the formation of bone-like apatite. The preferential growth of the process product formed needle-shaped bone-like apatite.…”

“…In recent years, there has been an indisputable tendency to use magnesium and its alloys in implants or bone grafts as they have mechanical properties similar to human bone and are biocompatible and biodegradable both in-vivo and in-vitro [2][3][4] . Furthermore, in comparison with polymeric biodegradable implants, tensile yield strength and Young's modulus are higher in magnesium and its alloys 5 .…”

Effect of calcium content on the microstructure, hardness and in-vitro corrosion behavior of biodegradable Mg-Ca binary alloy

“…They found significant improvement in that pitting corrosion resistance of calcium-containing magnesium alloys was significantly improved. Koleini et al [7] studied the influence of hot rolling parameters on microstructure and biodegradability of MgCa1.0 alloy. They expressed that more thickness reduction caused less corrosion and high preheated temperature of the MgCa implant increases the corrosion.…”

Influence of Manufacturing Parameters on Performance of Biodegradable Mg-Ca1.0 Implant

“…Corrosion resistant coating on Mg-Ca alloys has been shown to effectively delay the initiation of biodegradation [16], but there is a challenge to create a coating on Mg-Ca alloys, which has sufficient adhesion on substrate, high hardness, high toughness and high wear resistance [17]. Several studies showed that the corrosion resistance of MgCa alloys with Ca contents of ≥1% can be improved by refining their cast microstructures using thermomechanical processes such as extrusion, forging and rolling [11,14,18,19]. In a previous study [14], we reported that the break-up of the coarse or continuous Mg 2 Ca phase and refinement of grains in Mg-(1-3%)Ca alloys by indirect extrusion considerably improved the corrosion resistance of the alloys.…”

Mg-Ca binary alloy sheets with Ca contents of ≤1 wt.% with high corrosion resistance and high toughness