Characterization and Biomechanical Study of a Novel Magnesium Potassium Phosphate Cement

Magnesium potassium phosphate cement (MKPC) has attracted considerable attention as a bone regeneration material. However, there are only a few reports on its biomechanical properties. To evaluate the biomechanical properties of MKPC, we compared the mechanical parameters of pedicle screws enhanced with either MKPC or polymethyl methacrylate (PMMA) bone cement. The results show that the maximum pull-out force of the pedicle screws was 417.86 +/- 55.57 and 444.43 +/- 19.89 N after MKPC cement setting for 30 min and 12 h, respectively, which was better than that of the PMMA cement. In fatigue tests, the maximum pull-out force of the MKPC cement group was 435.20 +/- 7.96 N, whereas that of the PMMA cement in the control group was 346.80 +/- 7.66 N. Furthermore, the structural characterization analysis of the MKPC cement revealed that its microstructure after solidification was an irregular tightly packed crystal, which improved the mechanical strength of the cement. The maximum exothermic temperature of the MKPC reaction was 45.55 +/- 1.35 degrees C, the coagulation time was 7.89 +/- 0.37 min, and the compressive strength was 48.29 +/- 4.76 MPa, all of which meet the requirements of clinical application. In addition, the MKPC cement did not significantly inhibit cell proliferation or increase apoptosis, thus indicating good biocompatibility. In summary, MKPC exhibited good biomechanical properties, high initial strength, good biocompatibility, and low exothermic reaction temperature, demonstrating an excellent application potential in the field of orthopedics.

Automated summary

Magnesium potassium phosphate cement (MKPC) was evaluated for its biomechanical properties and compared with polymethyl methacrylate (PMMA) bone cement. MKPC showed better mechanical parameters and fatigue performance than PMMA. The microstructure of MKPC exhibited irregular tightly packed crystals, which improved its mechanical strength. MKPC demonstrated good biocompatibility and met the clinical application requirements. Therefore, MKPC has excellent potential for orthopedic applications.