Planning the Surgical Correction of Spinal Deformities: Toward the Identification of the Biomechanical Principles by Means of Numerical Simulation

In decades of technical developments after the first surgical corrections of spinal deformities, the set of devices, techniques, and tools available to the surgeons has widened dramatically. Nevertheless, the rate of complications due to mechanical failure of the fixation or the instrumentation remains rather high. Indeed, basic and clinical research about the principles of deformity correction and the optimal surgical strategies (i.e., the choice of the fusion length, the most appropriate instrumentation, and the degree of tolerable correction) did not progress as much as the implantable devices and the surgical techniques. In this work, a software approach for the biomechanical simulation of the correction of patient-specific spinal deformities aimed to the identification of its biomechanical principles is presented. The method is based on three-dimensional reconstructions of the spinal anatomy obtained from biplanar radiographic images. A user-friendly graphical user interface allows for the planning of the desired deformity correction and to simulate the implantation of pedicle screws. Robust meshing of the instrumented spine is provided by using consolidated computational geometry and meshing libraries. Based on a finite element simulation, the program is able to predict the loads and stresses acting in the instrumentation as well as those in the biological tissues. A simple test case (reduction of a low-grade spondylolisthesis at L3–L4) was simulated as a proof of concept, and showed plausible results. Despite the numerous limitations of this approach which will be addressed in future implementations, the preliminary outcome is promising and encourages a wide effort toward its refinement.

[1]  J. Dubousset,et al.  A new technic for segmental spinal osteosynthesis using the posterior approach. , 2014, Orthopaedics & traumatology, surgery & research : OTSR.

[2]  Antonius Rohlmann,et al.  Effect of different surgical strategies on screw forces after correction of scoliosis with a VDS implant , 2006, European Spine Journal.

[3]  M. Tunyogi-Csapó,et al.  Accuracy and reliability of coronal and sagittal spinal curvature data based on patient-specific three-dimensional models created by the EOS 2D/3D imaging system. , 2012, The spine journal : official journal of the North American Spine Society.

[4]  M. Romano,et al.  Review of rehabilitation and orthopedic conservative approach to sagittal plane diseases during growth: hyperkyphosis, junctional kyphosis, and Scheuermann disease. , 2009, European journal of physical and rehabilitation medicine.

[5]  Erin M. Mannen,et al.  Mechanical analysis of the human cadaveric thoracic spine with intact rib cage. , 2015, Journal of biomechanics.

[6]  M. Viceconti,et al.  Extracting clinically relevant data from finite element simulations. , 2005, Clinical biomechanics.

[7]  C. Lamartina,et al.  Asymmetrical pedicle subtraction osteotomy in the lumbar spine in combined coronal and sagittal imbalance , 2014, European spine journal.

[8]  M. Aebi,et al.  Pedicle subtraction osteotomies (PSO) in the lumbar spine for sagittal deformities , 2014, European Spine Journal.

[9]  K. Kaneda,et al.  An In Vitro Human Cadaveric Study Investigating the Biomechanical Properties of the Thoracic Spine , 2002, Spine.

[10]  Van C. Mow,et al.  Is the Nucleus Pulposus a Solid or a Fluid? Mechanical Behaviors of the Nucleus Pulposus of the Human Intervertebral Disc , 1996, Spine.

[11]  Hubert Labelle,et al.  Biomechanical modeling and analysis of a direct incremental segmental translation system for the instrumentation of scoliotic deformities. , 2011, Clinical biomechanics.

[12]  Hubert Labelle,et al.  Biomechanical modeling of brace design. , 2006, Studies in health technology and informatics.

[13]  Mingyue Ding,et al.  Surface Reconstruction through Poisson Disk Sampling , 2015, PloS one.

[14]  A Rohlmann,et al.  Instrumented Forceps for Measuring Tensile Forces in the Rod of the VDS Implant During Correction of Scoliosis. Eine Zange zur intraoperativen Messung der Zugkräfte im Gewindestab des VDS-Instrumentariums bei der Skoliosekorrektur , 2003, Biomedizinische Technik. Biomedical engineering.

[15]  W. Skalli,et al.  In Vivo Distribution of Spinal Intervertebral Stiffness Based on Clinical Flexibility Tests , 2010, Spine.

[16]  Antonius Rohlmann,et al.  Effect of multilevel lumbar disc arthroplasty on spine kinematics and facet joint loads in flexion and extension: a finite element analysis , 2012, European Spine Journal.

[17]  P. Surynková,et al.  Surface Reconstruction , 2010 .

[18]  S. Tadano,et al.  Scoliosis corrective force estimation from the implanted rod deformation using 3D-FEM analysis , 2015, Scoliosis.

[19]  William C. Hutton,et al.  Can Variations in Intervertebral Disc Height Affect the Mechanical Function of the Disc? , 1996, Spine.

[20]  Hutton Wc,et al.  Can variations in intervertebral disc height affect the mechanical function of the disc , 1996 .

[21]  Jack C Y Cheng,et al.  Three-Dimensional Characterization of Torsion and Asymmetry of the Intervertebral Discs Versus Vertebral Bodies in Adolescent Idiopathic Scoliosis , 2014, Spine.

[22]  Mark D. Brown,et al.  Intraoperative Measurement of Lumbar Spine Motion Segment Stiffness , 2002, Spine.

[23]  P. R. Harrington,et al.  Treatment of scoliosis. Correction and internal fixation by spine instrumentation. , 1962, The Journal of bone and joint surgery. American volume.

[24]  H Labelle,et al.  Preoperative Planning Simulator for Spinal Deformity Surgeries , 2008, Spine.

[25]  V. Goel,et al.  Distraction magnitude and frequency affects the outcome in juvenile idiopathic patients with growth rods: finite element study using a representative scoliotic spine model. , 2015, The spine journal : official journal of the North American Spine Society.

[26]  C. Ames,et al.  Use of Surgimap Spine in sagittal plane analysis, osteotomy planning, and correction calculation. , 2013, Neurosurgery clinics of North America.

[27]  Jingming Xie,et al.  Posterior vertebral column resection for correction of rigid spinal deformity curves greater than 100°. , 2012, Journal of neurosurgery. Spine.

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

[29]  Tony M. Keaveny,et al.  BONE MECHANICS , 2005 .

[30]  M. Sauté,et al.  Thoracoscopic Spine Release Before Posterior Instrumentation in Scoliosis , 1997, Clinical orthopaedics and related research.

[31]  R. Assietti,et al.  Biomechanics of the C5-C6 Spinal Unit Before and After Placement of a disc prosthesis , 2006, Biomechanics and modeling in mechanobiology.

[32]  C. Aubin,et al.  Biomechanical Analysis of Corrective Forces in Spinal Instrumentation for Scoliosis Treatment , 2012, Spine.

[33]  K. Scheffler,et al.  Intraoperative determination of the load–displacement behavior of scoliotic spinal motion segments: preliminary clinical results , 2012, European Spine Journal.

[34]  Hubert Labelle,et al.  Biomechanical Analysis of 4 Types of Pedicle Screws for Scoliotic Spine Instrumentation , 2012, Spine.

[35]  Hubert Labelle,et al.  Variability of spinal instrumentation configurations in adolescent idiopathic scoliosis , 2006, European Spine Journal.

[36]  Development of a scoliotic spine model for biomechanical in vitro studies. , 2015, Clinical biomechanics.

[37]  W Skalli,et al.  3D reconstruction of the spine from biplanar X-rays using parametric models based on transversal and longitudinal inferences. , 2009, Medical engineering & physics.

[38]  Hans Müller-Storz,et al.  The influence of cancellous bone density on load sharing in human lumbar spine: a comparison between an intact and a surgically altered motion segment , 2001, European Spine Journal.

[39]  Brice Ilharreborde,et al.  Use of EOS imaging for the assessment of scoliosis deformities: application to postoperative 3D quantitative analysis of the trunk , 2014, European Spine Journal.

[40]  Munish C. Gupta,et al.  Complications and intercenter variability of three-column osteotomies for spinal deformity surgery: a retrospective review of 423 patients. , 2014, Neurosurgical focus.

[41]  J G Werner,et al.  Telemeterized load measurement using instrumented spinal internal fixators in a patient with degenerative instability. , 1996, Spine.

[42]  Pierre Roussouly,et al.  Sagittal balance disorders in severe degenerative spine. Can we identify the compensatory mechanisms? , 2011, European Spine Journal.

[43]  Tomoyuki Saito,et al.  Relationship between bone density and bone metabolism in adolescent idiopathic scoliosis , 2013, Scoliosis.

[44]  C. Lamartina,et al.  Corner osteotomy: a modified pedicle subtraction osteotomy for increased sagittal correction in the lumbar spine , 2014, European Spine Journal.

[45]  Hubert Labelle,et al.  Biomechanical Analysis of Vertebral Derotation Techniques for the Surgical Correction of Thoracic Scoliosis: A Numerical Study Through Case Simulations and a Sensitivity Analysis , 2013, Spine.

[46]  Mark D. Brown,et al.  Measurement of Cadaver Lumbar Spine Motion Segment Stiffness , 2002, Spine.

[47]  Pasquale Vena,et al.  A finite element model of the L4–L5 spinal motion segment: biomechanical compatibility of an interspinous device , 2005, Computer methods in biomechanics and biomedical engineering.

[48]  Wafa Skalli,et al.  Evaluation of a Patient-Specific Finite-Element Model to Simulate Conservative Treatment in Adolescent Idiopathic Scoliosis , 2015, Spine deformity.

[49]  L. Lenke Sagittal balance. , 2014, Journal of neurosurgery. Spine.

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

[51]  Hubert Labelle,et al.  Computer simulation for the optimization of instrumentation strategies in adolescent idiopathic scoliosis , 2009, Medical & Biological Engineering & Computing.

[52]  T. Burd,et al.  Corrective osteotomies in spine surgery. , 2008, The Journal of bone and joint surgery. American volume.

[53]  Fabio Galbusera,et al.  Rigid and flexible spinal stabilization devices: a biomechanical comparison. , 2011, Medical engineering & physics.

[54]  G. Qiu,et al.  One-stage posterior-only lumbosacral hemivertebra resection with short segmental fusion: a more than 2-year follow-up , 2016, European Spine Journal.

[55]  R. Tomaszewski,et al.  Radiological evaluation of the eighth thoracic vertebra rotation in the pectus excavatum , 2015, Scoliosis.