Becker et al: Influence of two consecutive partial lateral corpectomies on passive motion of the canine lumbar spine
Veterinary Surgery 1, 2026

🔍 Key Findings

Each PLC significantly increased passive range of motion (ROM) in the sagittal and dorsal planes (p < .05).
No significant change was observed in rotational ROM after either PLC.
First PLC increased sagittal ROM by 2.4° (23% increase); second PLC added 1.0° (8% increase).
Dorsal ROM increased by 2.3° after first PLC and 1.5° after second PLC.
Second PLC did not cause greater destabilization than the first — both contributed similarly to ROM increase.
Failure testing showed that spinal segments with two PLCs failed at 13 Nm, while native spines withstood up to 25 Nm, suggesting reduced load-bearing capacity but not clinically significant under normal conditions.
Rotational stability was preserved, possibly due to intact facet joints and lamina, which play a larger role in rotation.
Study supports the clinical feasibility of two consecutive PLCs, but cautions against excessive bone removal due to potential for spinal instability.

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Becker et al: Influence of two consecutive partial lateral corpectomies on passive motion of the canine lumbar spine
Veterinary Surgery 1, 2026

🔍 Key Findings

Each PLC significantly increased passive range of motion (ROM) in the sagittal and dorsal planes (p < .05).
No significant change was observed in rotational ROM after either PLC.
First PLC increased sagittal ROM by 2.4° (23% increase); second PLC added 1.0° (8% increase).
Dorsal ROM increased by 2.3° after first PLC and 1.5° after second PLC.
Second PLC did not cause greater destabilization than the first — both contributed similarly to ROM increase.
Failure testing showed that spinal segments with two PLCs failed at 13 Nm, while native spines withstood up to 25 Nm, suggesting reduced load-bearing capacity but not clinically significant under normal conditions.
Rotational stability was preserved, possibly due to intact facet joints and lamina, which play a larger role in rotation.
Study supports the clinical feasibility of two consecutive PLCs, but cautions against excessive bone removal due to potential for spinal instability.

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Multiple Choice Questions on this study

In Becker 2026 et al., on lumbar spine PLC biomechanics, what explanation was given for the preservation of rotational stability despite PLCs?

A. Preservation of intervertebral discs

B. Passive stabilizing system compensates

C. Facet joints and lamina remained intact

D. Paraspinal muscles preserved

E. Central canal expansion reduces torque

Answer: Facet joints and lamina remained intact

Explanation: Rotational stability was attributed to the integrity of facet joints and dorsal structures, which were not affected by PLCs.

In Becker 2026 et al., on lumbar spine PLC biomechanics, how did the second PLC compare biomechanically to the first in terms of passive range of motion increase?

A. It had a significantly greater destabilizing effect

B. It caused no additional change

C. It caused less increase than the first

D. It caused a similar magnitude of increase

E. It caused a greater increase only in flexion

Answer: It caused a similar magnitude of increase

Explanation: Both the first and second PLCs significantly increased ROM, but the second did not have a greater effect than the first.

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