Characterization of a Bioresorbable Magnesium-Reinforced PLA-Integrated GTR/GBR Membrane as Dental Applications

Inferior mechanical properties have always been a limitation of the bioresorbable membranes in GBR/GTR. This study is aimed atfabricating a bioresorbable magnesium-reinforced polylactic acid- (PLA-) integrated membrane and investigating its mechanicalproperties, degradation rate, and biocompatibility. The uncoated andfluoride-coated magnesium alloys, AZ91, were made intostrips. Then, magnesium-reinforced PLA-integrated membrane was made through integration. PLA strips were used in thecontrol group instead of magnesium strips. Specimens were cut into rectangular shape and immersed in Hank’s Balanced SaltSolution (HBSS) at 37°C for 4, 8, and 12 d. The weight loss of the AZ91 strips was measured. Three-point bending tests wereconducted before and after the immersion to determine the maximum load on specimens. Potentiodynamic polarization (PDP),electrochemical impedance spectroscopy (EIS), scanning electron microscopy (SEM), and energy-dispersive spectroscopy (EDS)were conducted on coated and uncoated AZ91 plates to examine corrosion resistance. Murinefibroblast and osteoblast cellswere cultured on circular specimens and titanium disks for 1, 3, and 5 d. Thereafter, WST test was performed to examine cellproliferation. As a result, the coated and uncoated groups showed higher maximum loads than the control group at all timepoints. The weight loss of AZ91 strips used in the coated group was lower than that in the uncoated group. PDP, EIS, SEM, andEDS showed that the coated AZ91 had a better corrosion resistance than the uncoated AZ91. The cell proliferation test showedthat the addition of AZ91 did not have an adverse effect on osteoblast cells. Conclusively, the magnesium-reinforced PLA-integrated membrane has excellent load capacity, corrosion resistance, cell affinity, and proper degradation rate. Moreover, ithas great potential as a bioresorbable membrane in the GBR/GTR application.