Biomechanical Evaluation of Transpedicular Nucleotomy With Intact Annulus Fibrosus

Study Design. Biomechanical testing of partially nucleotomized ovine cadaveric spines. Objective. To explore how the nucleus pulposus (NP) affects the biomechanical behavior of the intervertebral disc (IVD) by performing a partial nucleotomy via the transpedicular approach. Summary of Background Data. Mechanical loading represents a crucial part of IVD homeostasis. However, traditional regenerative strategies require violation of the annulus fibrosus (AF) resulting in significant alteration of joint mechanics. The transpedicular nucleotomy represents a suitable method to create a cavity into the NP, as a model to study IVD regeneration with intact AF. Methods. A total of 30 ovine-lumbar- functional spinal units (FSUs) (L1-L6) randomly assigned to 5 groups: control; transpedicular tunnel (TT); TT + polymethylmethacrylate (PMMA) to repair the bone tunnel; nucleotomy; nucleotomy + PMMA. Flexion/extension, lateral-bending, and axial-rotation were evaluated under adaptive displacement control. Axial compression was applied for 15 cycles of preconditioning followed by 1 hour of constant compression. Viscoelastic behavior was modeled and parameterized. Results. TT has minimal effects on rotational biomechanics. The nucleotomy increases ROM and neutral zone (NZ) displacement width whereas decreasing NZ stiffness. TT + PMMA has small effects in terms of ROM. Nucleotomy + PMMA brings ROM back to the control, increases NZ stiffness, and decreases NZ displacement width. The nucleotomy tends to increase the rate of early creep. TT reduces early and late damping. The use of PMMA increased late elastic stiffness (S2) and reduced viscous damping (&eegr;2) culminating in faster resolution of creep. Conclusion. Biomechanical properties of NP are crucial for IVD repair. This study demonstrated that TT does not affect rotational stability whereas partial nucleotomy with intact AF induce rotational instability, highlighting the central role of NP in early stages of IDD. Therefore, this model represents a successful platform to validate and optimize disc regeneration strategies. Level of Evidence: N/A

[1]  M. Adams,et al.  What is Intervertebral Disc Degeneration, and What Causes It? , 2006, Spine.

[2]  H. Wilke,et al.  Preliminary Investigations on Intradiscal Pressures during Daily Activities: An In Vivo Study Using the Merino Sheep , 2013, PloS one.

[3]  Bing Wang,et al.  Injection of AAV2-BMP2 and AAV2-TIMP1 into the nucleus pulposus slows the course of intervertebral disc degeneration in an in vivo rabbit model. , 2012, The spine journal : official journal of the North American Spine Society.

[4]  Sounok Sen,et al.  Nucleus pulposus glycosaminoglycan content is correlated with axial mechanics in rat lumbar motion segments , 2006, Journal of orthopaedic research : official publication of the Orthopaedic Research Society.

[5]  G B Andersson,et al.  The Effect of Disc Degeneration and Facet Joint Osteoarthritis on the Segmental Flexibility of the Lumbar Spine , 2000, Spine.

[6]  H. Tsuji,et al.  Biorheological responses of the intact and nucleotomized intervertebral discs to compressive, tensile, and vibratory stresses. , 1993, Clinical biomechanics.

[7]  J. Iatridis,et al.  Localized Intervertebral Disc Injury Leads to Organ Level Changes in Structure, Cellularity, and Biosynthesis , 2009, Cellular and molecular bioengineering.

[8]  Y K Liu,et al.  Mechanical Properties of Lumbar Spinal Motion Segments as Affected by Partial Disc Removal , 1986, Spine.

[9]  J. Laible,et al.  Direct measurement of intervertebral disc maximum shear strain in six degrees of freedom: motions that place disc tissue at risk of injury. , 2007, Journal of biomechanics.

[10]  T. King,et al.  Primary instability of lumbar vertebrae as a common cause of low back pain. , 1957, The Journal of bone and joint surgery. British volume.

[11]  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.

[12]  V M Haughton,et al.  The relationship between disc degeneration and flexibility of the lumbar spine. , 2001, The spine journal : official journal of the North American Spine Society.

[13]  D. S. Hickey,et al.  Relation Between the Structure of the Annulus Fibrosus and the Function and Failure of the Intervertebral Disc , 1980, Spine.

[14]  GradSibylle,et al.  A Nucleotomy Model with Intact Annulus Fibrosus to Test Intervertebral Disc Regeneration Strategies. , 2015 .

[15]  Dawn M Elliott,et al.  Comparison of Animal Discs Used in Disc Research to Human Lumbar Disc: Axial Compression Mechanics and Glycosaminoglycan Content , 2008, Spine.

[16]  Vincenzo Denaro,et al.  Mesenchymal stem cells injection in degenerated intervertebral disc: cell leakage may induce osteophyte formation , 2012, Journal of tissue engineering and regenerative medicine.

[17]  M H Krag,et al.  Internal deformations of intact and denucleated human lumbar discs subjected to compression, flexion, and extension loads , 1989, Journal of orthopaedic research : official publication of the Orthopaedic Research Society.

[18]  Gunnar B J Andersson,et al.  Recent Advances in Analytical Modeling of Lumbar Disc Degeneration , 2004, Spine.

[19]  M M Panjabi,et al.  Disc Degeneration Affects the Multidirectional Flexibility of the Lumbar Spine , 1994, Spine.

[20]  M. Panjabi,et al.  Effects of Disc Injury on Mechanical Behavior of the Human Spine , 1984, Spine.

[21]  Vincenzo Denaro,et al.  Intervertebral disc regeneration: from the degenerative cascade to molecular therapy and tissue engineering , 2015, Journal of tissue engineering and regenerative medicine.

[22]  W C Hayes,et al.  A comparison of the effects of automated percutaneous diskectomy and conventional diskectomy on intradiscal pressure, disk geometry, and stiffness. , 1994, Journal of spinal disorders.

[23]  Mauro Alini,et al.  A Nucleotomy Model with Intact Annulus Fibrosus to Test Intervertebral Disc Regeneration Strategies. , 2015, Tissue engineering. Part C, Methods.

[24]  James D. Kang,et al.  Gene therapy for the treatment of degenerative disk disease. , 2008, The Journal of the American Academy of Orthopaedic Surgeons.

[25]  D M Spengler,et al.  In vivo creep behavior of the normal and degenerated porcine intervertebral disk: a preliminary report. , 1988, Journal of spinal disorders.

[26]  I. Kingma,et al.  Quantifying intervertebral disc mechanics: a new definition of the neutral zone , 2011, BMC musculoskeletal disorders.

[27]  P. Roughley Biology of Intervertebral Disc Aging and Degeneration: Involvement of the Extracellular Matrix , 2004, Spine.

[28]  M. Krismer,et al.  Motion in Lumbar Functional Spine Units During Side Bending and Axial Rotation Moments Depending on the Degree of Degeneration , 2000, Spine.

[29]  J. Iatridis,et al.  Mechanisms for mechanical damage in the intervertebral disc annulus fibrosus. , 2004, Journal of biomechanics.

[30]  G. Andersson,et al.  Effect of annular incision type on the change in biomechanical properties in a herniated lumbar intervertebral disc. , 2002, Journal of biomechanical engineering.

[31]  H. Farfan,et al.  Instability of the lumbar spine. , 1982, Clinical orthopaedics and related research.

[32]  Mauro Alini,et al.  The Transpedicular Approach As an Alternative Route for Intervertebral Disc Regeneration , 2013, Spine.

[33]  L. Claes,et al.  Spinal segment range of motion as a function of in vitro test conditions: Effects of exposure period, accumulated cycles, angular‐deformation rate, and moisture condition , 1998, The Anatomical record.

[34]  James D. Kang,et al.  Needle Puncture in Rabbit Functional Spinal Units Alters Rotational Biomechanics , 2015, Journal of spinal disorders & techniques.

[35]  J. Costi,et al.  Needle Puncture Injury Affects Intervertebral Disc Mechanics and Biology in an Organ Culture Model , 2008, Spine.

[36]  H. Goost,et al.  The sheep as a knee osteoarthritis model: early cartilage changes after meniscus injury and repair , 2007, Laboratory animals.

[37]  Dawn M. Elliott,et al.  Trans-Endplate Nucleotomy Increases Deformation and Creep Response in Axial Loading , 2006, Annals of Biomedical Engineering.

[38]  C. P. Winlove,et al.  Pathophysiology of the intervertebral disc and the challenges for MRI , 2007, Journal of magnetic resonance imaging : JMRI.

[39]  L. Setton,et al.  Anisotropic and inhomogeneous tensile behavior of the human anulus fibrosus: experimental measurement and material model predictions. , 2001, Journal of biomechanical engineering.

[40]  P. Roughley,et al.  The role of proteoglycans in aging, degeneration and repair of the intervertebral disc. , 2002, Biochemical Society transactions.

[41]  Marco Bernardini,et al.  The transpedicular approach for the study of intervertebral disc regeneration strategies: in vivo characterization , 2013, European Spine Journal.

[42]  J. Iatridis,et al.  Height and torsional stiffness are most sensitive to annular injury in large animal intervertebral discs. , 2012, The spine journal : official journal of the North American Spine Society.

[43]  P Brinckmann,et al.  Change of disc height, radial disc bulge, and intradiscal pressure from discectomy. An in vitro investigation on human lumbar discs. , 1991, Spine.

[44]  Ian A. F. Stokes,et al.  Mechanical Conditions That Accelerate Intervertebral Disc Degeneration: Overload Versus Immobilization , 2004, Spine.

[45]  James D. Kang,et al.  Novel ex-vivo mechanobiological intervertebral disc culture system. , 2012, Journal of biomechanics.

[46]  A. Nachemson,et al.  IN VIVO MEASUREMENTS OF INTRADISCAL PRESSURE. DISCOMETRY, A METHOD FOR THE DETERMINATION OF PRESSURE IN THE LOWER LUMBAR DISCS. , 1964, The Journal of bone and joint surgery. American volume.