Compressibility of porous magnesium foam: dependency on porosity and pore size

“…This behavior indicates the bulk deformation of scaffolds under the compression load, however, porous magnesium specimens produced by metal foaming method [82] and powder sintering method [48] show local collapse of pores with shortened elastic deformation. Following the linear elastic deformation ending at the yield strength, normally magnesium samples exhibit a long plateau of constant stress [82].…”

“…Changing the pore size, pore shape, porosity, and pore distribution can affect the mechanical properties [48,83,84]. Increasing porosity results in the decrease of compression strength, yield strength, and Young's modulus [48,83,84].…”

“…Increasing porosity results in the decrease of compression strength, yield strength, and Young's modulus [48,83,84]. The mechanical properties of porous magnesium prepared by the green compacts method using carbamide particles as the space holder and under 100 MP uniaxial pressure were studied to demonstrate the dependence of mechanical properties on pore size and porosity [48]. Scaffolds with pore size of 70-400 µm and porosity of 35-55%…”

“…On the other hand, in the untreated osteocartilage defect with the highest accessibility to bone marrow cavity, no reproduction of subchondral bone in the central part was observed [118]. Magnesium scaffolds with optimal porosity should provide appropriate mechanical support [47,48], osteoinductive properties, excellent biocompatibility [121], biodegradability and bioresorbability [122]. Thus, such scaffolds can be designed to be suitable candidates for subchondral bone plate replacement.…”

“…The presence of porosity adversely affects the corrosion resistance by enhancing the surface area exposed to the corrosive media [48]. In order to control the degradability of Mg scaffolds produced by powder metallurgy method, a multilayer polymeric matrix composed of polycaprolactone (PCL) and gelatin (Gel) reinforced with bioactive glass (BaG) particles has been coated on the surface of Mg scaffolds by freeze drying process [49].…”

Porous magnesium-based scaffolds for tissue engineering

“…This behavior indicates the bulk deformation of scaffolds under the compression load, however, porous magnesium specimens produced by metal foaming method [82] and powder sintering method [48] show local collapse of pores with shortened elastic deformation. Following the linear elastic deformation ending at the yield strength, normally magnesium samples exhibit a long plateau of constant stress [82].…”

“…Changing the pore size, pore shape, porosity, and pore distribution can affect the mechanical properties [48,83,84]. Increasing porosity results in the decrease of compression strength, yield strength, and Young's modulus [48,83,84].…”

“…Increasing porosity results in the decrease of compression strength, yield strength, and Young's modulus [48,83,84]. The mechanical properties of porous magnesium prepared by the green compacts method using carbamide particles as the space holder and under 100 MP uniaxial pressure were studied to demonstrate the dependence of mechanical properties on pore size and porosity [48]. Scaffolds with pore size of 70-400 µm and porosity of 35-55%…”

“…On the other hand, in the untreated osteocartilage defect with the highest accessibility to bone marrow cavity, no reproduction of subchondral bone in the central part was observed [118]. Magnesium scaffolds with optimal porosity should provide appropriate mechanical support [47,48], osteoinductive properties, excellent biocompatibility [121], biodegradability and bioresorbability [122]. Thus, such scaffolds can be designed to be suitable candidates for subchondral bone plate replacement.…”

“…The presence of porosity adversely affects the corrosion resistance by enhancing the surface area exposed to the corrosive media [48]. In order to control the degradability of Mg scaffolds produced by powder metallurgy method, a multilayer polymeric matrix composed of polycaprolactone (PCL) and gelatin (Gel) reinforced with bioactive glass (BaG) particles has been coated on the surface of Mg scaffolds by freeze drying process [49].…”

Porous magnesium-based scaffolds for tissue engineering

Progress and Challenge for Magnesium Alloys as Biomaterials

A Novel Manufacturing Route for Fabrication of Topologically‐Ordered Porous Magnesium Scaffolds