Abstract
BackgroundRigid interspinous process fixation (ISPF) may serve as a minimally disruptive adjunct to lumbar interbody fusion. Previous biomechanical assessments of ISPF have demonstrated particularly advantageous outcomes in stabilizing the sagittal plane. However, ISPF has not been well characterized in regard to its impact on interbody load, which has implications for the risk of cage migration or subsidence, and sagittal alignment. The purpose of this study was to biomechanically assess in vitro the interbody load (IBL), focal lordosis (FL), and spinous process loading generated by in situ compression/distraction with a novel ISPF device capable of incremental in situ shortening/extension. Bilateral pedicle screw fixation (BPSF) was used as a control.MethodsTwo fresh frozen human lumbar spines were thawed and musculature was removed, leaving ligaments intact. Seven functional spinal units were iteratively tested, which involved a standard lateral discectomy, placement of a modified lateral cage possessing two load cells, and posterior fixation. BPSF and ISPF were performed at each level, with order of fixation was randomized. BPSF was first performed with maximum compressive exertion followed by 75% exertion to represent clinical application. The ISPF device was implanted at a neutral height and incrementally shortened/extended in situ in 1-mm increments. IBL and FL were measured under each condition. Loads on the spinous processes were estimated through bench-top mechanical calibration.ResultsNo significant differences in IBL were observed, but the ISPF device produced a significantly greater change in FL compared to the clinically relevant BPSF compression. IBL, as a function of ISPF device height, expressed linear behavior during compression and exponential behavior during distraction.ConclusionsThe novel ISPF device produced clinically effective IBL and FL, performing well in comparison to BPSF. Additionally, incremental ISPF device manipulation demonstrated predictable and clinically safe trends regarding loading of the interbody space and spinous processes.
Highlights
Rigid interspinous process fixation (ISPF) has been proposed as a less invasive alternative to pedicle screw fixation (PSF) for supplemental use in circumferential lumbar fusion [1,2]
The purpose of this study was to biomechanically assess in vitro the interbody load (IBL), focal lordosis (FL), and spinous process loading generated by in situ compression/distraction with a novel ISPF device capable of incremental in situ shortening/extension
The change (%) in IB load, relative to baseline, and change in focal lordosis were compared between the ISPF device at its in situ compressed state, the ISPF device at its in situ distracted state, Bilateral pedicle screw fixation (BPSF) under 75% exertion, and BPSF under 100% exertion by Friedman’s test with Dunn’s test for multiple post hoc comparisons
Summary
Rigid interspinous process fixation (ISPF) has been proposed as a less invasive alternative to pedicle screw fixation (PSF) for supplemental use in circumferential lumbar fusion [1,2]. With ISPF, compression or distraction is applied through the spinous processes and leverages a larger posterior moment arm about the IB space compared to manipulations through PSF. The larger moment arm achieved by ISPF may translate to substantial variations in the focal lordosis and IB loading, even with small adjustments. Rigid interspinous process fixation (ISPF) may serve as a minimally disruptive adjunct to lumbar interbody fusion. The purpose of this study was to biomechanically assess in vitro the interbody load (IBL), focal lordosis (FL), and spinous process loading generated by in situ compression/distraction with a novel ISPF device capable of incremental in situ shortening/extension. Bilateral pedicle screw fixation (BPSF) was used as a control
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