Biomechanical evaluation of an expandable meshed bag augmented with pedicle or facet screws for percutaneous lumbar interbody fusion

Biomechanical evaluation of an expandable meshed bag augmented with pedicle or facet screws for percutaneous lumbar interbody fusion

Abstract Objective To evaluate the biomechanics of lumbar motion segments instrumented with stand-alone OptiMesh system augmented with posterior fixation using facet or pedicle screws and the efficacy of discectomy and disc distraction. Background context OptiMesh bone graft containment system has b...

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Veröffentlicht in:The spine journal 2010-11, Vol.10 (11), p.987-993
Hauptverfasser: Zheng, Xiujun, MD, Chaudhari, Rahul, MD, Wu, Chunhui, PhD, Mehbod, Amir A., MD, Erkan, Serkan, MD, Transfeldt, Ensor E., MD
Format: Artikel
Sprache:eng
Schlagworte:
Biomechanical Phenomena
Bone Screws
Cadaver
Diskectomy, Percutaneous - instrumentation
Diskectomy, Percutaneous - methods
Expandable
Humans
Internal Fixators
Lumbar interbody fusion
Lumbar Vertebrae - surgery
Mesh
Orthopedics
Percutaneous
Range of Motion, Articular
Spinal Fusion - instrumentation
Spinal Fusion - methods
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Zusammenfassung:Abstract Objective To evaluate the biomechanics of lumbar motion segments instrumented with stand-alone OptiMesh system augmented with posterior fixation using facet or pedicle screws and the efficacy of discectomy and disc distraction. Background context OptiMesh bone graft containment system has been used for vertebral compression fractures and percutaneous lumbar interbody fusion. The filled mesh bag serves as the interbody device providing structural support to the motion segment being fused. No biomechanical data of this new device are available in the literature. Methods Twenty-four fresh human cadaveric lumbar motion segments were divided into two groups. In the control group, multidirectional flexibility testing was conducted after an intact condition and standard transforaminal lumbar interbody fusion (TLIF) procedure. In the OptiMesh group, testing was performed following intact, stand-alone OptiMesh procedure, OptiMesh with facet screws (placed using the transfacet approach), and OptiMesh with pedicle screws and rods. Range of motion (ROM) was calculated for each surgical treatment. The lordosis and disc height change of intact and instrumented specimens were measured in the lateral radiographs to evaluate the disc space distraction. In the OptiMesh group, cyclic loading in flexion extension (FE) was applied to measure cage subsidence or collapse (10,000 cycles at 6 Nm). After biomechanical testing, all the specimens were dissected to inspect the discectomy and end plate preparation. The area of discectomy was measured. Results The mean ROM of the intact specimens was 2.7°, 7.4°, and 7.2° in axial torsion (AT), lateral bending (LB), and FE, respectively. There was no difference between the control group and OptiMesh group. The mean ROM of the stand-alone OptiMesh system decreased to 2.4°, 5.1°, and 4.3° in AT, LB, and FE. The ROM decreased to 0.9° in AT, 2.2° in LB, and 0.9° in FE with OptiMesh system and facet screws. On average, OptiMesh system with pedicle screws and rods reduced the ROM to 1.3° in AT, 1.6° in LB, and 1.1° in FE. Compared with the intact condition and stand-alone OptiMesh system, both posterior fixation options had significant statistical difference (p
ISSN:1529-9430
1878-1632
DOI:10.1016/j.spinee.2010.08.016