Biomechanical analysis of differing pedicle screw insertion angles.

BACKGROUND Pedicle screw fixation to stabilize lumbar spinal fusion has become the gold standard for posterior stabilization. A significant percentage of surgical candidates are classified as obese or morbidly obese. For these patients, the depth of the incisions and soft tissue makes it extremely difficult to insert pedicle screws along the pedicle axis. As such, the pedicle screws can only be inserted in a much more sagittal axis. However, biomechanical stability of the angled screw insertion has been controversial. We hypothesized that the straight or parallel screw was a more stable construct compared to the angled or axially inserted screw when subjected to caudal cyclic loading. METHODS We obtained 12 fresh frozen lumbar vertebrae from L3 to L5 from five cadavers. Schantz screws (6.0 mm) were inserted into each pedicle, one angled and along the axis of the pedicle and the other parallel to the spinous process. Fluoroscopic imaging was used to guide insertion. Each screw was then subjected to caudal cyclic loads of 50 N for 2000 cycles at 2 Hz. Analysis of initial damage, initial rate of damage, and total damage during cyclic loading was undertaken. FINDINGS Average total fatigue damage for straight screws measured 0.398+/-0.38 mm, and 0.689+/-0.96 mm for angled screws. Statistical analysis for total fatigue damage ratio of angled to straight screws revealed that a significant stability was achieved in straight-screw construct (P<0.03). INTERPRETATION This study showed that straight screw insertion results in a more stable pedicle-screw construct. The angled screw insertion technique resulted in more scattered values of damage indicating that the outcome from the angled screw fixation is less predictable. This validates the use of this technique to implant pedicle screws across the axis of the pedicle (parallel to the mid sagittal line) rather than along the axis, and has broad implications in instrumented posterior lumbar spinal surgery.

[1]  R Roy-Camille,et al.  Internal fixation of the lumbar spine with pedicle screw plating. , 1986, Clinical orthopaedics and related research.

[2]  P. McAfee,et al.  Survivorship Analysis of Pedicle Spinal Instrumentation , 1991, Spine.

[3]  B. Myers,et al.  The Role of Imaging and In Situ Biomechanical Testing in Assessing Pedicle Screw Pull‐Out Strength , 1996, Spine.

[4]  K. Mann,et al.  A fatigue damage model for the cement-bone interface. , 2004, Journal of biomechanics.

[5]  D N Kunz,et al.  Pedicle Screw Pullout Strength: Correlation with Insertional Torque , 1993, Spine.

[6]  O. Böstman,et al.  Complications of transpedicular lumbosacral fixation for non-traumatic disorders. , 1997, The Journal of bone and joint surgery. British volume.

[7]  B. T. Field,et al.  A biomechanical study of intrapeduncular screw fixation in the lumbosacral spine. , 1986, Clinical orthopaedics and related research.

[8]  S. Esses,et al.  The spinal pedicle screw: techniques and systems. , 1989, Orthopaedic review.

[9]  V K Goel,et al.  Effect of Specimen Fixation Method on Pullout Tests of Pedicle Screws , 1996, Spine.

[10]  H H BOUCHER,et al.  A method of spinal fusion. , 1959, The Journal of bone and joint surgery. British volume.

[11]  S. Cook,et al.  Biomechanical evaluation and preliminary clinical experience with an expansive pedicle screw design. , 2000, Journal of spinal disorders.

[12]  V. Frankel,et al.  Fatigue behavior of adult cortical bone: the influence of mean strain and strain range. , 1981, Acta orthopaedica Scandinavica.

[13]  G. Saillant,et al.  Osteosynthesis of thoraco-lumbar spine fractures with metal plates screwed through the vertebral pedicles. , 1976, Reconstruction surgery and traumatology.

[14]  W. Hutton,et al.  Biomechanical study of lumbar pedicle screws: does convergence affect axial pullout strength? , 1998, Journal of spinal disorders.

[15]  A. Tencer,et al.  Caudo-cephalad loading of pedicle screws: mechanisms of loosening and methods of augmentation. , 1993, Spine.

[16]  A G Patwardhan,et al.  Analysis of the Morphometric Characteristics of the Thoracic and Lumbar Pedicles , 1987, Spine.

[17]  T C Hearn,et al.  Biomechanical Testing of a New Design for Schanz Pedicle Screws , 1993, Journal of orthopaedic trauma.

[18]  F. Magerl Stabilization of the lower thoracic and lumbar spine with external skeletal fixation. , 1984, Clinical orthopaedics and related research.

[19]  K. Mann,et al.  Creep dominates tensile fatigue damage of the cement–bone interface , 2004, Journal of orthopaedic research : official publication of the Orthopaedic Research Society.

[20]  K. Murota,et al.  An Experimental Study on Transpedicular Screw Fixation in Relation to Osteoporosis of the Lumbar Spine , 1991, Spine.

[21]  J. Leong,et al.  Microfracture and Changes in Energy Absorption to Fracture of Young Vertebral Cancellous Bone Following Physiological Fatigue Loading , 2004, Spine.

[22]  S. Yerby,et al.  Loading of pedicle screws within the vertebra. , 1997, Journal of biomechanics.

[23]  M. Zindrick The role of transpedicular fixation systems for stabilization of the lumbar spine. , 1991, The Orthopedic clinics of North America.

[24]  J. K. Mayfield,et al.  The Effects of Pedicle Screw Fit: An In Vitro Study , 1994, Spine.

[25]  R. Roy-Camille Posterior screw plate fixation in thoracolumbar injuries. , 1992, Instructional course lectures.

[26]  B. Cunningham,et al.  Triangulation of Pedicular Instrumentation: A Biomechanical Analysis , 1991, Spine.