Bibliographic Details
| Title: |
Finite element analysis shows minimal stability difference between individualized minihemilaminectomy-corpectomy and partial lateral corpectomy in a dog model. |
| Authors: |
Yuki Kikuchi1,2 yuki.kikuchi1013@gmail.com, Masakazu Shimada3, Fumitaka Takahashi1,2, Shinya Yamaguchi1,2, Yasushi Hara1 |
| Source: |
American Journal of Veterinary Research. Dec2024, Vol. 85 Issue 12, p1-11. 11p. |
| Subject Terms: |
*FINITE element method, *SPINAL instability, *BEAGLE (Dog breed), *SPINAL cord, *ROTATIONAL motion, *ANGLES |
| Abstract: |
OBJECTIVE: Use finite element analysis to evaluate the biomechanical effects of spinal decompression procedures in healthy Beagle dogs, comparing individualized mini-hemilaminectomy-corpectomy (iMHC), mini-hemilaminectomy, partial lateral corpectomy (PLC), and hemilaminectomy. METHODS: A finite element model of the L1-L2 functional spinal unit was generated using CT data. For each decompression model, loads were applied in 0.2-Nm steps (maximum, 2.0 Nm) in 6 directions: flexion, extension, right and left lateral bending, and right and left axial rotation. The L1 spinous process tip displacement angle was quantified numerically. RESULTS: Among the 4 techniques, mini-hemilaminectomy exhibited the smallest displacement angles across all directions. Hemilaminectomy exhibited the largest displacement angles in extension, flexion, right rotation, and left rotation across all techniques. Left and right lateral bending displacement angles were marginally larger for iMHC than for hemilaminectomy at 0.4 Nm; however, at 2.0 Nm, displacement angles were similar. CONCLUSIONS: Mini-hemilaminectomy minimizes functional spinal unit instability to the greatest extent. Hemilaminectomy is more unstable than iMHC and PLC in flexion, extension, and rotation. Mini-hemilaminectomy-corpectomy and PLC are more unstable than hemilaminectomy in lateral bending, with iMHC being slightly more unstable than PLC or nearly equal. CLINICAL RELEVANCE: Mini-hemilaminectomy minimizes instability to the greatest extent in cases of ventrolateral spinal compression. In cases of ventral spinal compression, iMHC may be preferable to PLC for providing equivalent stability without impeding spinal cord visualization, but both techniques can cause instability depending on loading direction, so careful attention to postoperative instability is necessary when excessive vertebral body resection is involved. [ABSTRACT FROM AUTHOR] |
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