Background:

This study aims to evaluate the biomechanical stability of a novel lateral plate (NLP) that can be employed in oblique lateral lumbar fusion (OLIF).

Methods:

In vitro biomechanical tests were performed on six fresh calf lumbar vertebrae specimens. The surgical segment was set at L3-4. Each specimen was tested in the following order: intact state (INT); OLIF cage only/stand-alone (SA); cage supplemented with lateral screw-rod (LSR); cage supplemented with novel lateral plate (NLP); and cage supplemented with unilateral or bilateral pedicle screw-rod (UPS or BPS). A pure moment of ±7.5 Nm was applied to the specimen to produce six different motion directions, including flexion and extension, lateral bending, and axial rotation, and the range of motion (ROM) of L3-4 in each direction was recorded.

Results:

In addition to flexion-extension, NLP reduced the ROM of SA (P < 0.05). In flexion-extension, the ROM of NLP was similar to those of SA and LSR (P > 0.05); compared to pedicle screw-rod (PSD), the ROM of NLP was higher (P < 0.05). In lateral bending, the ROM of NLP was close to that of LSR and PSD (P > 0.05). In axial rotation, the ROM of NLP was higher than that of PSD (P < 0.05), and close to that of LSR (P > 0.05).

Conclusion:

NLP can enhance surgical segment stability in all directions of motion, similar to LSR, but weaker than UPS and BPS in flexion-extension and rotation.