Biomechanical Evaluation of Posterior Dynamic Stabilization Systems in Lumbar Spine
Biomechanical Evaluation of Posterior Dynamic Stabilization Systems in Lumbar Spine

Author: Bharath K. Parepalli

Publisher:

Published: 2009

Total Pages: 204

ISBN-13:

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Fusion has been the gold standard treatment for treating the disc degeneration. Fusion surgeries restrict the motion at the implanted level there by imposing additional load at the adjacent levels. Many clinical studies have showed that adjacent segment degeneration was observed in patients over time. In order to overcome problems with fusion devices, dynamic stabilization systems are being used to treat disc degeneration related problems. These implants restore intersegmental motion across the implanted level with minimal effects on the adjacent levels. In vitro cadaveric testing was conducted on seven harvested sheep spines using established protocols. Axient was implanted in the spines 3 months prior to sacrificing. Main aim of this testing is to see if the performance is altered by the presence of surrounding muscle tissue. The specimens were prepared and tested under load control protocol. All six loading modes were tested by applying a pure moment of 10Nm (in steps of 2.5Nm) and angular displacement was calculated for the following cases: 1) Intact spine + Axient with surrounding muscle tissue, 2) Intact spine + Axient with muscle tissue removed, 3) Intact spine (with implant removed). Relative motion of L4 vertebra with respect to L5 was calculated. Statistical analysis was performed (on the implanted level data) to see if there is a statistical significance between cases 1 and 2. Biomechanical testing was also performed on 4 human cadavers to observe the trend with Axient compared to FE results. A validated 3-D non linear finite element model of the L3-S1 lumbar spine was used to evaluate biomechanics of various dynamic stabilization systems in comparison with traditional rigid rod system. The model was modified at L4-L5 level to simulate three different dynamic stabilization systems (DSFM-1, DSFM-2 and Axient, Innovative Spinal Technologies Inc., Mansfield, MA). Grade I was simulated at L4-L5 level. Follower preload of 400N and a 10Nm bending moment was applied to simulate physiological flexion, extension, lateral bending and axial rotation. Range of motion (ROM), intra discal pressure (IDP) and facet loads were calculated for all the models. Implant with better performance was then compared with fusion system in both grade I and grade II degenerated spines. In vitro results showed that there is no significant difference in the performance of the Axient with and without surrounding muscle tissue in terms of range of motion. Coming to FE results, Axient performed better over the other two implants (DSFM-1 and DSFM-2). Axient device was able to restore the motion at the implanted level compared to fusion device. Higher motions were observed at the adjacent level (L5-S1) with fusion device compared to intact and injured models. Both devices were able to stabilize the diseased spine and unload the treated disc.

Stability Imparted by a Posterior Lumbar Interbody Fusion Cage Following Surgery
Stability Imparted by a Posterior Lumbar Interbody Fusion Cage Following Surgery

Author: Vadapalli Sasidhar

Publisher:

Published: 2004

Total Pages: 264

ISBN-13:

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In order to promote solid fusion across a decompressed spinal segment, inter-body spacers/cages are used with and without posterior instrumentation to provide an initial "rigid" fixation of the segment. Inter-body spacers (cages) of various shapes (e.g., rectangular, cylindrical) and materials are currently available on the market. Important factors affecting the biomechanics of the fused segment are (i) cage shape and placement, (ii) cage material property (iii) surgical approach used-posterior vs. antero lateral (iv) cage with additional instrumentation. The objective of this study is to address change in the stability and stress patterns associated with the various factors described above. A cadaveric study using established protocols and a finite element (FE) study were conducted. For the cadaveric study, nine fresh ligamentous lumbar spine specimens (L1-S2) were radiographed out of which six specimens were prepared for testing by fixing a base to the sacrum and a loading frame to the top-most vertebra. Each specimen was subjected to pure moment (6 Nm in steps of 1.5 Nm) in six loading modes: flexion, extension, right and left lateral bending, and right and left axial rotation. The load-displacement data was collected in a sequential manner for the following cases: 1) intact spine, 2) insertion of rectangular cages (Vertebral spacer PR, Synthes, Inc.), 3) fixation with posterior instrumentation, 4) fatiguing the instrumented spine. The relative motion of L4 with respect to L5 was calculated for all these cases. A validated three-dimensional, nonlinear FE model of lumbar spine from L3-L5 was used. The model was modified to simulate the bilateral placement of cages alone. Contact surfaces were defined between the cages and the endplates to simulate the bone-implant interface. The cages were placed using posterior approach and left antero lateral approach to see the effect of the surgical approach on the stability of the segment. In the FE model with cage placed using posterior approach, posterior instrumentation was added. For this model the material property of the cage was changed form PEEK to titanium to study the change in load sharing and stresses on the endplates. For all the models a 6Nm moment was applied and all the six loading cases were simulated. The relative motion of L4 with respect to L5 was calculated, stresses in the implants and endplates were studied. Results from the in vitro study indicate that the stability of the spine decreased after the stand alone placement of bilateral cage when compared to the intact for all the loading cases except in flexion. However, no statistically significant difference was seen in the stability between intact and stand alone cage placement. After stabilization with posterior fixation using the pedicle screw rod system, the stability increased in all loading cases. There was no significant change in stability after fatiguing. The FE model predictions for the bilateral cage alone and with additional instrumentation placed at L4-L5 disc space were within 1 SD of the cadaveric data in all loading modes. There was no change in stability offered by stand alone cage placement using antero lateral approach and posterior approach. For the cage made of titanium peak Von mises stress in the endplates were twice of that for cage made of PEEK. Cages placed laterally from the mid-sagittal plane provide better stability in bending when compared to medially placed cages.

A Biomechanical Evaluation of Three Atlantoaxial Transarticular Screw Salvaging Fixation Techniques
A Biomechanical Evaluation of Three Atlantoaxial Transarticular Screw Salvaging Fixation Techniques

Author: Tejaswy Potluri

Publisher:

Published: 2010

Total Pages: 100

ISBN-13:

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Injuries to the neck, or cervical region, are very severe types of injuries since there is a potential risk of damage to the spinal cord. Any neck injury can have devastating if not life threatening consequences. The upper cervical spine consists of three vertebrae: The occiput (C0), the atlas (C1) and the axis (C2). Stabilization of the atlanto-axial complex following a neck injury is a challenging procedure because of its complicated anatomy. Several stabilization techniques have been reported for C1-C2 fixation. These techniques include posterior wiring and bone graft, posterior transarticular screws or a combination. Fixation with transarticular screws has been the gold standard in effectively stabilizing the segment. However, the drawback of using the transarticular screws is that they have a potential risk of vertebral artery injury due to a high riding transverse foramen of C2 vertebra, screw malposition or fracture of the C1 lateral mass. In such cases, it is not recommended to proceed with inserting the contralateral transarticular screw and the surgeon should find an alternative to fix the contralateral side. Many studies are available comparing different atlanto-axial stabilization techniques but none of them compared the techniques to fix the contralateral side while using the transarticular screw on one side. The current options are C1 Lateral Mass Screw and C2 Pedicle Screw or C1 Lateral Mass Screw and C2 Intralaminar Screw or C1-2 Sublaminar Wire. The purpose of this study is to compare the biomechanical stability of the three C1-C2 transarticular screw salvaging fixation techniques through in vitro testing and finite element modeling. An in vitro testing using nine cadaver specimens was done to compare the degree of stability afforded by the three salvaging fixation techniques at C1-C2 level. To compare the efficiency of bilateral instrumentation over unilateral case, unilateral transarticular screw was also investigated. A finite element model of the C0-C3 has been developed and applied to study as well as compare the effects of the three C1-C2 transarticular screw fixation techniques on the biomechanical behavior of the upper cervical spine. The intact model was validated by comparing with previously published experimental results as well as with the in vitro results. Finite element models representing the following combinations with C1-2 Transarticular Screw on one side and: 1) C1 Lateral Mass Screw and C2 Pedicle Screw (TS+C1LMS+C2PS) 2) C1 Lateral Mass Screw and C2 Intralaminar Screw (TS+C1LMS+C2ILS) 3) C1-2 Sublaminar Wire (TS+WIRE) on the other side were evaluated. Various parameters like range of motion, facet loading and implant stresses were evaluated. Results show that all the three bilateral fixation procedures significantly reduced motion in all the loading modes when compared to unilateral fixation. When the three bilateral techniques were compared, TS+C1LMS+C2PS and TS+C1LMS+C2ILS afforded same stability and instrumentation stresses in all the loading modes. In addition, both the techniques were highly stable in axial rotation mode when compared to TS+WIRE. TS+WIRE resulted in higher stresses when compared to the other two bilateral techniques in all the loading modes.

Handbook of Spine Technology
Handbook of Spine Technology

Author: Boyle C. Cheng

Publisher: Springer

Published: 2021-04-01

Total Pages: 0

ISBN-13: 9783319444239

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This handbook is the most authoritative and up-to-date reference on spine technology written for practitioners, researchers, and students in bioengineering and clinical medicine. It is the first resource to provide a road map of both the history of the field and its future by documenting the poor clinical outcomes and failed spinal implants that contributed to problematic patient outcomes, as well as the technologies that are currently leading the way towards positive clinical outcomes. The contributors are leading authorities in the fields of engineering and clinical medicine and represent academia, industry, and international government and regulatory agencies. The chapters are split into five sections, with the first addressing clinical issues such as anatomy, pathology, oncology, trauma, diagnosis, and imaging studies. The second section, on biomechanics, delves into fixation devices, the bone implant interface, total disc replacements, injury mechanics, and more. The last three sections, on technology, are divided into materials, commercialized products, and surgery. All appropriate chapters will be continually updated and available on the publisher’s website, in order to keep this important reference as up-to-date as possible in a fast-moving field.

The Cervical Spine
The Cervical Spine

Author: Edward C. Benzel

Publisher: Lippincott Williams & Wilkins

Published: 2012-08-29

Total Pages: 1633

ISBN-13: 1605477524

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The Cervical Spine is the most comprehensive, current, and authoritative reference on the cervical spine. Prepared by internationally recognized members of The Cervical Spine Research Society Editorial Committee, the Fifth Edition presents new information, new technologies, and advances in clinical decision making. The text provides state-of-the-art coverage of basic and clinical research, diagnostic methods, and medical and surgical treatments, bringing together the latest thinking of the foremost orthopaedic surgeons, neurosurgeons, neurologists, rheumatologists, radiologists, anatomists, and bioengineers. Chapters cover anatomy, physiology, biomechanics, neurologic and functional evaluation, and radiographic evaluation and address the full range of pediatric problems, fractures, spinal cord injuries, tumors, infections, inflammatory conditions, degenerative disorders, and complications. Accompanying the text is a website with the fully searchable text plus a color image bank.

5th Kuala Lumpur International Conference on Biomedical Engineering 2011
5th Kuala Lumpur International Conference on Biomedical Engineering 2011

Author: Hua-Nong Ting

Publisher: Springer Science & Business Media

Published: 2011-06-17

Total Pages: 892

ISBN-13: 364221729X

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The Biomed 2011 brought together academicians and practitioners in engineering and medicine in this ever progressing field. This volume presents the proceedings of this international conference which was hold in conjunction with the 8th Asian Pacific Conference on Medical and Biological Engineering (APCMBE 2011) on the 20th to the 23rd of June 2011 at Berjaya Times Square Hotel, Kuala Lumpur. The topics covered in the conference proceedings include: Artificial organs, bioengineering education, bionanotechnology, biosignal processing, bioinformatics, biomaterials, biomechanics, biomedical imaging, biomedical instrumentation, BioMEMS, clinical engineering, prosthetics.