Do position and size matter? An analysis of cage and placement variables for optimum lordosis in PLIF reconstruction.

PURPOSE: To examine monosegmental lordosis after posterior lumbar interbody fusion (PLIF) surgery and relate lordosis to cage size, shape, and placement. METHODS: Eighty-three consecutive patients underwent single-level PLIF with paired identical lordotic cages involving a wide decompression and bilateral facetectomies. Cage parameters relating to size (height, lordosis, and length) and placement (expressed as a ratio relative to the length of the inferior vertebral endplate) were recorded. Centre point ratio (CPR) was the distance to the centre of both cages and indicated mean position of both cages. Posterior gap ratio (PGR) was the distance to the most posterior cage and indicated position and cage length indirectly. Relationships between lordosis and cage parameters were explored. RESULTS: Mean lordosis increased by 5.98° (SD 6.86°). The cages used varied in length from 20 to 27 mm, in lordosis from 10° to 18°, and in anterior cage height from 10 to 17 mm. The mean cage placement as determined by CPR was 0.54 and by PGR was 0.16. The significant correlations were: both CPR and PGR with lordosis gain at surgery (r = 0.597 and 0.537, respectively, p < 0.001 both), cage lordosis with the final lordosis (r = 0.234, p < 0.05), and anterior cage height was negatively correlated with a change in lordosis (r = -0.297, p < 0.01). CONCLUSION: Cage size, shape, and position, in addition to surgical technique, determine lordosis during PLIF surgery. Anterior placement with sufficient "clear space" behind the cages is recommended. In addition, cages should be of moderate height and length, so that they act as an effective pivot for lordosis.

Development and validation of a subject-specific finite element model of the functional spinal unit to predict vertebral strength.

Finite element models of an isolated vertebral body cannot accurately predict compressive strength of the spinal column because, in life, compressive load is variably distributed across the vertebral body and neural arch. The purpose of this study was to develop and validate a patient-specific finite element model of a functional spinal unit, and then use the model to predict vertebral strength from medical images. A total of 16 cadaveric functional spinal units were scanned and then tested mechanically in bending and compression to generate a vertebral wedge fracture. Before testing, an image processing and finite element analysis framework (SpineVox-Pro), developed previously in MATLAB using ANSYS APDL, was used to generate a subject-specific finite element model with eight-node hexahedral elements. Transversely isotropic linear-elastic material properties were assigned to vertebrae, and simple homogeneous linear-elastic properties were assigned to the intervertebral disc. Forward bending loading conditions were applied to simulate manual handling. Results showed that vertebral strengths measured by experiment were positively correlated with strengths predicted by the functional spinal unit finite element model with von Mises or Drucker-Prager failure criteria ( R2 = 0.80-0.87), with areal bone mineral density measured by dual-energy X-ray absorptiometry ( R2 = 0.54) and with volumetric bone mineral density from quantitative computed tomography ( R2 = 0.79). Large-displacement non-linear analyses on all specimens did not improve predictions. We conclude that subject-specific finite element models of a functional spinal unit have potential to estimate the vertebral strength better than bone mineral density alone.

Pathogenesis of Vertebral Anterior Wedge Deformity: A 2-Stage Process?

STUDY DESIGN: Biomechanical and radiographical study on cadaveric spines. OBJECTIVE: To explain the pathogenesis of vertebral "anterior wedge" deformity, which causes senile kyphosis. SUMMARY OF BACKGROUND DATA: This deformity arises with minimal trauma and is difficult to reproduce in cadaveric spines. We hypothesize that wedging is created by a 2-stage process. First, excessive loading damages a vertebral endplate and decompresses the adjacent intervertebral disc. This alters load sharing between the vertebral body cortex and trabeculae so that subsequent cyclic loading causes progressive collapse of the unsupported anterior cortex. METHODS: Thirty-four cadaveric thoracolumbar "motion segments," aged 70 to 98 years, were positioned in flexion and overloaded in compression. Physiologically reasonable cyclic compressive loading was then applied to each flexed specimen, at progressively higher loads, for up to 2 hours. Before and after initial overload and again after cyclic loading, the distribution of loading on the vertebra was assessed from measurements of compressive stress within the adjacent disc. These "stress profiles" were repeated in the neutral, flexed, and extended postures. Progressive vertebral body deformity was assessed radiographically. RESULTS: Compressive overload induced endplate fracture at an average force of 2.31 kN. There was minimal anterior wedging, but pressure in the adjacent disc nucleus (in flexion) fell by an average of 55% and neural arch load bearing increased by 166%. Subsequent cyclic loading exaggerated these changes and concentrated compressive stress within the anterior annulus. After both stages, height of the anterior and posterior vertebral cortexes was reduced by 32% and 12%, respectively, so that anterior wedging of the vertebral body increased from 5.0° to 11.4° on average. All changes were highly significant (P < 0.001). CONCLUSION: Anterior wedge deformities can be created consistently by a 2-stage process involving initial endplate damage, followed by progressive collapse of the anterior cortex. Detecting initial endplate damage may be important to minimize vertebral deformity in patients with osteoporosis. LEVEL OF EVIDENCE: N/A.

Is kyphoplasty better than vertebroplasty at restoring form and function after severe vertebral wedge fractures?

BACKGROUND CONTEXT: The vertebral augmentation procedures, vertebroplasty and kyphoplasty, can relieve pain and facilitate mobilization of patients with osteoporotic vertebral fractures. Kyphoplasty also aims to restore vertebral body height before cement injection and so may be advantageous for more severe fractures. PURPOSE: The purpose of this study was to compare the ability of vertebroplasty and kyphoplasty to restore vertebral height, shape, and mechanical function after severe vertebral wedge fractures. STUDY DESIGN/SETTING: This is a biomechanical and radiographic study using human cadaveric spines. METHODS: Seventeen pairs of thoracolumbar "motion segments" from cadavers aged 70-98 years were injured, in a two-stage process involving flexion and compression, to create severe anterior wedge fractures. One of each pair underwent vertebroplasty and the other kyphoplasty. Specimens were then compressed at 1 kN for 1 hour to allow consolidation. Radiographs were taken before and after injury, after treatment, and after consolidation. At these same time points, motion segment compressive stiffness was assessed, and intervertebral disc "stress profiles" were obtained to characterize the distribution of compressive stress on the vertebral body and neural arch. RESULTS: On average, injury reduced anterior vertebral body height by 34%, increased its anterior wedge angle from 5.0° to 11.4°, reduced intradiscal (nucleus) pressure and motion segment stiffness by 96% and 44%, respectively, and increased neural arch load bearing by 57%. Kyphoplasty caused 97% of the anterior height loss to be regained immediately, although this reduced to 79% after consolidation. Equivalent gains after vertebroplasty were significantly lower: 59% and 47%, respectively (p<.001). Kyphoplasty reduced vertebral wedging more than vertebroplasty (p<.02). Intradiscal pressure, neural arch load bearing, and motion segment compressive stiffness were restored significantly toward prefracture values after both augmentation procedures, even after consolidation, but these mechanical effects were similar for kyphoplasty and vertebroplasty. CONCLUSIONS: After severe vertebral wedge fractures, vertebroplasty and kyphoplasty were equally effective in restoring mechanical function. However, kyphoplasty was better able to restore vertebral height and reverse wedge deformity.

Universal No-fault Compensation is Associated With Improved Return to Work Rates in Spine Fusion.

STUDY DESIGN: Retrospective cohort study and systematic literature review. OBJECTIVE: To examine the influence of "universal no-fault compensation" upon return-to-work rates in patients undergoing lumbar spinal fusion, and then to make comparison with workers' compensation (WC) and non-workers' compensation (non-WC) claimants. SUMMARY OF BACKGROUND DATA: Compensation has an adverse influence upon outcomes and return to work in lumbar spinal fusion. It is unclear whether this is due to the compensation per se, or due to the features of WC including its adversarial environment, delayed resolution of claims, and need for disability enhancement to promote compensation. The New Zealand Accident Compensation Corporation (ACC) is a universal no-fault system offering early treatment and salary reimbursement. Given the differing features of these compensation systems, comparison of return-to-work rates may give insight into the differing outcomes for the two compensation systems. METHODS: From a cohort of 428 patients undergoing lumbar spinal fusion, 178 patients covered by ACC system underwent a structured interview to determine pre-injury, pre-surgical, and post-surgical work status. A systematic literature review was performed relating to lumbar spine fusion, return to work, and WC. RESULTS: The return-to-work rate for the ACC patients in work at the time of their injury was 81%. The systematic review of 21 studies including 2519 subjects revealed a return-to-work rate of 40% for WC patients, and 74% for non-WC patients (P < 0.001). There was a significantly greater return-to-work rate for ACC patients than WC patients (P < 0.001), but no difference between ACC and non-WC patients. CONCLUSION: The return-to-work rates for a universal no-fault compensation system are higher than those under WC cover, and are compatible with non-WC cases. This suggests that the features of WC may contribute to the inferior return-to-work rates.

Intervertebral disc decompression following endplate damage: implications for disc degeneration depend on spinal level and age.

STUDY DESIGN: Mechanical and morphological studies on cadaveric spines. OBJECTIVE: To explain how spinal level and age influence disc degeneration arising from endplate fracture. SUMMARY OF BACKGROUND DATA: Disc degeneration can be initiated by damage to a vertebral body endplate, but it is unclear why endplate lesions, and patterns of disc degeneration, vary so much with spinal level and age. METHODS: One hundred seventy-four cadaveric motion segments, from T7-T8 to L5-S1 and aged 19 to 96 years, were subjected to controlled compressive overload to damage a vertebral body. Stress profilometry was performed before and after damage to quantify changes in intradiscal pressure, and compressive stresses in the annulus. Eighty-six of the undamaged vertebral bodies were then sectioned in the midsagittal plane, and the thickness of the central bony endplate was measured from microradiographs. Regression analysis was used to compare the relative influences of spinal level, age, disc degeneration, and sex on results obtained. RESULTS: Compressive overload caused endplate fracture at an average force of 3.4 kN, and reduced motion segment height by an average 1.88 mm. Pressure loss in the adjacent nucleus pulposus decreased from 93% at T8-T9 to 38% at L4-L5 (R = 22%, P < 0.001), and increased with age (R = 19%, P < 0.001), especially in male specimens. Stress concentrations in the posterior annulus increased after endplate fracture, with the effect being greatest at upper spinal levels (R = 7%, P < 0.001). Endplate thickness increased by approximately 50% between T11 and L5 (R = 21%, P < 0.001). CONCLUSION: Endplate fracture creates abnormal stress distributions in the adjacent intervertebral disc, increasing the risk of internal disruption and degeneration. Effects are greatly reduced in the lower lumbar spine, and in young specimens, primarily because of differences in nucleus volume, and materials properties, respectively. Disc degeneration between L4 and S1 may often be unrelated to endplate fracture. LEVEL OF EVIDENCE: N/A.

The risks of overly effective postoperative epidural analgesia.

Continuous epidural analgesia is frequently used to provide supplemental postoperative pain control. Epidural analgesia has the potential to mask the early symptoms that signal impending complications after even routine surgical procedures. We report a case of sciatic nerve palsy following epidural anesthesia after an uncomplicated leg length correction. Good epidural anesthesia may remove a patient's normal protective sensation, allowing pain and other signs of nerve compression from prolonged unchanged postoperative positioning to go unnoticed. This case highlights the need for heightened awareness of potential neurologic compromise in the setting of epidural analgesia. We recommend closely monitoring the patient's neurologic condition and frequently evaluating the patient's position in bed.