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Compressive strength of interbody cages in the lumbar spine: the effect of cage shape, posterior instrumentation and bone density (1998)

Jost, B. ; Cripton, P. A. ; Lund, T. ; [et al.]

Springer

European spine journal 7 (1998), S. 132-141

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ISSN: 1432-0932

Keywords: Key words Spine ; Interbody ; Fusion ; Compression ; Biomechanics ; Implant ; Posterior ; lumbar intervertebral fusion

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Abstract One goal of interbody fusion is to increase the height of the degenerated disc space. Interbody cages in particular have been promoted with the claim that they can maintain the disc space better than other methods. There are many factors that can affect the disc height maintenance, including graft or cage design, the quality of the surrounding bone and the presence of supplementary posterior fixation. The present study is an in vitro biomechanical investigation of the compressive behaviour of three different interbody cage designs in a human cadaveric model. The effect of bone density and posterior instrumentation were assessed. Thirty-six lumbar functional spinal units were instrumented with one of three interbody cages: (1) a porous titanium implant with endplate fit (Stratec), (2) a porous, rectangular carbon-fibre implant (Brantigan) and (3) a porous, cylindrical threaded implant (Ray). Posterior instrumentation (USS) was applied to half of the specimens. All specimens were subjected to axial compression displacement until failure. Correlations between both the failure load and the load at 3 mm displacement with the bone density measurements were observed. Neither the cage design nor the presence of posterior instrumentation had a significant effect on the failure load. The loads at 3 mm were slightly less for the Stratec cage, implying lower axial stiffness, but were not different with posterior instrumentation. The large range of observed failure loads overlaps the potential in vivo compressive loads, implying that failure of the bone-implant interface may occur clinically. Preoperative measurements of bone density may be an effective tool to predict settling around interbody cages.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/s005860050043

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Biomechanics of stand-alone cages and cages in combination with posterior fixation: a literature review (2000)

Oxland, T. R. ; Lund, T.

Springer

European spine journal 9 (2000), S. S095

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ISSN: 1432-0932

Keywords: Key words Interbody cage ; Biomechanics ; Implant ; Stabilization ; Strength

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Abstract Interbody cages in the lumbar spine have met with mixed success in clinical studies. This has led many investigators to supplement cages with posterior instrumentation. The objective of this literature review is to address the mechanics of interbody cage fixation in the lumbar spine with respect to three-dimensional stabilization and the strength of the cage-vertebra interface. The effect of supplementary posterior fixation is reviewed. Only three-dimensional stabilization evaluations in human cadaveric models are included. These studies involve the application of different loads to the spine and the measurement of vertebral motion in flexion-extension, axial rotation, and lateral bending. There are no published studies which detected any differences between different cage designs. However, it does seem that cages inserted from an anterior direction provide better stabilization to the spine than those inserted from a posterior direction. In general, anterior cages stabilize better than posterior cages in axial rotation and lateral bending. Cages from both directions stabilized well in flexion, but not in extension. Supplementary posterior fixation with pedicle or translaminar screws substantially improves the stabilization in all directions. The strength of the cage-vertebra interface from studies using human cadaveric specimens is also reviewed. The axial compressive strength of this interface is highly dependent upon vertebral body bone density. Other factors such as preservation of the subchondral bony end-plate and cage design are clearly less important in the compressive strength. Supplementary posterior instrumentation does not enhance substantially the interface strength in axial compression.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/PL00010028

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A new approach to computer-aided spine surgery: fluoroscopy-based surgical navigation (2000)

Nolte, L. -P. ; Slomczykowski, M. A. ; Berlemann, U. ; [et al.]

Springer

European spine journal 9 (2000), S. S078

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ISSN: 1432-0932

Keywords: Key words Spine ; Implant ; Pedicle screws ; Navigation ; Fluoroscopy

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Abstract A new computer-based navigation system for spinal surgery has been designed. This was achieved by combining intraoperative fluoroscopy-based imaging using conventional C-arm technology with freehand surgical navigation principles. Modules were developed to automate digital X-ray image registration. This is in contrast to existing computed tomography- (CT) based spinal navigation systems, which require a vertebra-based registration procedure. Cross-referencing of the image intensifier with the surgical object allows the real-time image-interactive navigation of surgical tools based on one single registered X-ray image, with no further image updates. Furthermore, the system allows the acquisition and real-time use of multiple registered images, which provides an advanced multi-directional control (pseudo 3D) during surgical action. Stereotactic instruments and graphical user interfaces for image-interactive transpedicular screw insertion have been developed. A detailed validation of the system was performed in the laboratory setting and throughout an early clinical trial including eight patients in two spine centers. Based on the resulting data, the new technique promises improved accuracy and safety in open and percutaneous spinal surgery.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/PL00010026

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