Bio-inspired low elastic biodegradable Mg-Zn-Mn-Si-HA alloy fabricated by spark plasma sintering

“…The high value of sintering pressure induces the high driving force, which helps in densifying or compacting the powder particles. Reportedly elevated sintering temperature assists the coalescence of the powder and reduces the porosity [ 30 , 31 ]. Figure 4 a presents the sintering of powder particles during the SPS process.…”

“…Therefore, the possible reaction behind the appearance of O element in the as-fabricated alloys resulted from handling of powder sample after milling and before sintering. The uniformly distributed HA in the composite leads to increase in the corrosion resistance [ 29 , 30 , 31 ]. On the other hand, when Si was used as an alloying element instead of HA, the typical change in the structure has been witnessed.…”

“…Then, the blended powder was consolidated by the SPS process (SPS-5000 machine; model: Dr. Sinter SPS-625, Fuji Electronic Industrial Co. Ltd., Tsurugashima, Japan). The SPS was carried out at a heating rate of 50 °C /min (for a holding time of 5 min), under vacuum, and at different sintering temperatures and pressure conditions as illustrated in Table 2 , as per the procedure reported elsewhere [ 29 , 30 , 31 ]. Figure 1 presents the fabrication route for the synthesis of Mg–Zn–Mn–(HA–Si) alloy.…”

“…The simulated body fluid (SBF) test was conducted to find out the degradation rate of the specimens after 3, 7, and 14 days. The samples were well polished and dipped into the SBF solution in sterilized vials as per the ASTM-G31-72 standard, as reported in [ 31 , 37 ]. After a predetermined time period of immersion, the samples were retrieved from the glass vial, cleaned by water, and dehydrated into the desiccators for 24 h. The degradation rate was determined by the weight loss due to Mg 2+ ion release in the SBF solution.…”

“…The alloying of HA (5 wt %) improves the corrosion resistance of Mg [ 29 , 30 ]. Further, Prakash et al [ 31 ] investigated the effect of mechanical alloying-assisted SPS process (MA-SPS) parameters on structural porosity, elastic modulus, and hardness of the composite. Multi-objective particle swarm optimization (MO-PSO) has been utilized to determine the optimal setting of MA-SPS to sinter mechanically tuned biocompatible composites with improved corrosion properties.…”

Synthesis, Characterization, Corrosion Resistance and In-Vitro Bioactivity Behavior of Biodegradable Mg–Zn–Mn–(Si–HA) Composite for Orthopaedic Applications

“…The high value of sintering pressure induces the high driving force, which helps in densifying or compacting the powder particles. Reportedly elevated sintering temperature assists the coalescence of the powder and reduces the porosity [ 30 , 31 ]. Figure 4 a presents the sintering of powder particles during the SPS process.…”

“…Therefore, the possible reaction behind the appearance of O element in the as-fabricated alloys resulted from handling of powder sample after milling and before sintering. The uniformly distributed HA in the composite leads to increase in the corrosion resistance [ 29 , 30 , 31 ]. On the other hand, when Si was used as an alloying element instead of HA, the typical change in the structure has been witnessed.…”

“…Then, the blended powder was consolidated by the SPS process (SPS-5000 machine; model: Dr. Sinter SPS-625, Fuji Electronic Industrial Co. Ltd., Tsurugashima, Japan). The SPS was carried out at a heating rate of 50 °C /min (for a holding time of 5 min), under vacuum, and at different sintering temperatures and pressure conditions as illustrated in Table 2 , as per the procedure reported elsewhere [ 29 , 30 , 31 ]. Figure 1 presents the fabrication route for the synthesis of Mg–Zn–Mn–(HA–Si) alloy.…”

“…The simulated body fluid (SBF) test was conducted to find out the degradation rate of the specimens after 3, 7, and 14 days. The samples were well polished and dipped into the SBF solution in sterilized vials as per the ASTM-G31-72 standard, as reported in [ 31 , 37 ]. After a predetermined time period of immersion, the samples were retrieved from the glass vial, cleaned by water, and dehydrated into the desiccators for 24 h. The degradation rate was determined by the weight loss due to Mg 2+ ion release in the SBF solution.…”

“…The alloying of HA (5 wt %) improves the corrosion resistance of Mg [ 29 , 30 ]. Further, Prakash et al [ 31 ] investigated the effect of mechanical alloying-assisted SPS process (MA-SPS) parameters on structural porosity, elastic modulus, and hardness of the composite. Multi-objective particle swarm optimization (MO-PSO) has been utilized to determine the optimal setting of MA-SPS to sinter mechanically tuned biocompatible composites with improved corrosion properties.…”

Synthesis, Characterization, Corrosion Resistance and In-Vitro Bioactivity Behavior of Biodegradable Mg–Zn–Mn–(Si–HA) Composite for Orthopaedic Applications

Enhancing Microstructural, Thermal, Mechanical, and Corrosion Response of a Bio/Eco‐Compatible Mg–2Zn–1Ca–0.3Mn Alloy Using Two Types of Cryogenic Treatments

Effect of multi‐axial hot forging process on mechanical, and corrosion resistance behavior of Mg‐3Zn alloy for temporary orthopedic implants