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

Abstract: IntroductionPosterior lumbar intervertebral fusion (PLIF) was introduced to clinical practice in the mid-1940s independently by Jaslow [33] and by Cloward [14][15][16]. The theoretical bases of this procedure were outlined: mechanical stability is provided by the intervertebral fusion, the original disc height is restored and the intervertebral foramina are distracted. Lin et al. [38] postulated four biomechanical principles to get a high rate of fusion: preservation of the integrity of the posterior portion … Show more

“…Secondly, the discongruency between the cylindrical shape of the cage and the wedge-shaped intervertebral disc space in the sagittal plane could result in destruction of the posterior part of the L5 endplate. If so, the posterior part of the cage, which is supposed to resist a considerable amount of compressive force, will rest on the softer cancellous vertebral body bone [2,6,16]. The decrease of posterior intervertebral disc height during this time is a result of the subsidence of the cage into the posterior part of the vertebral body.…”

Anterior lumbar interbody fusion with threaded fusion cages and autologous bone grafts

“…Secondly, the discongruency between the cylindrical shape of the cage and the wedge-shaped intervertebral disc space in the sagittal plane could result in destruction of the posterior part of the L5 endplate. If so, the posterior part of the cage, which is supposed to resist a considerable amount of compressive force, will rest on the softer cancellous vertebral body bone [2,6,16]. The decrease of posterior intervertebral disc height during this time is a result of the subsidence of the cage into the posterior part of the vertebral body.…”

Anterior lumbar interbody fusion with threaded fusion cages and autologous bone grafts

“…In order to mimic the clinical situation as much as possible, spinal implants have often been tested in vitro on human cadaver segments [6,17,20]. One problem with the use of human specimens, however, is the large variation in geometry and mechanical properties.…”

The use of a quadruped as an in vivo model for the study of the spine – biomechanical considerations

“…Hansson et al [14] found a linear correlation between BMD and maximum compression force, calculating a significant (P<0.01) correlation coefficient of 0.81-0.90. In compression tests with "interbody cages" between vertebral bodies, Jost et al [18] observed a significant (P<0.0005) linear correlation between the above variables.…”

“…The literature offers no uniform recommendations for the test conditions in compression trials of this type, and test speeds of 5 mm/min [14,30], 0.4 mm/s [18], 35 mm/ min [38] and 2.54 mm/s [16] are described in the literature. Since no group of authors offers any rationale for their respective test speed, we assumed that the various speeds were determined by the test machine employed in each case.…”

Biomechanical compression tests with a new implant for thoracolumbar vertebral body replacement