Top

Published in:

01-12-2010 | Original Article

The stabilizing potential of anterior, posterior and combined techniques for the reconstruction of a 2-level cervical corpectomy model: biomechanical study and first results of ATPS prototyping

Authors: Heiko Koller, Rene Schmidt, Michael Mayer, Wolfgang Hitzl, Juliane Zenner, Stefan Middendorf, Nicolaus Gräf, H. Resch, Hans-Joachim Willke

Published in: European Spine Journal | Issue 12/2010

Abstract

Clinical studies reported frequent failure with anterior instrumented multilevel cervical corpectomies. Hence, posterior augmentation was recommended but necessitates a second approach. Thus, an author group evaluated the feasibility, pull-out characteristics, and accuracy of anterior transpedicular screw (ATPS) fixation. Although first success with clinical application of ATPS has already been reported, no data exist on biomechanical characteristics of an ATPS-plate system enabling transpedicular end-level fixation in advanced instabilities. Therefore, we evaluated biomechanical qualities of an ATPS prototype C4–C7 for reduction of range of motion (ROM) and primary stability in a non-destructive setup among five constructs: anterior plate, posterior all-lateral mass screw construct, posterior construct with lateral mass screws C5 + C6 and end-level fixation using pedicle screws unilaterally or bilaterally, and a 360° construct. 12 human spines C3–T1 were divided into two groups. Four constructs were tested in group 1 and three in group 2; the ATPS prototypes were tested in both groups. Specimens were subjected to flexibility test in a spine motion tester at intact state and after 2-level corpectomy C5–C6 with subsequent reconstruction using a distractable cage and one of the osteosynthesis mentioned above. ROM in flexion–extension, axial rotation, and lateral bending was reported as normalized values. All instrumentations but the anterior plate showed significant reduction of ROM for all directions compared to the intact state. The 360° construct outperformed all others in terms of reducing ROM. While there were no significant differences between the 360° and posterior constructs in flexion–extension and lateral bending, the 360° constructs were significantly more stable in axial rotation. Concerning primary stability of ATPS prototypes, there were no significant differences compared to posterior-only constructs in flexion–extension and axial rotation. The 360° construct showed significant differences to the ATPS prototypes in flexion–extension, while no significant differences existed in axial rotation. But in lateral bending, the ATPS prototype and the anterior plate performed significantly worse than the posterior constructs. ATPS was shown to confer increased primary stability compared to the anterior plate in flexion–extension and axial rotation with the latter yielding significance. We showed that primary stability after 2-level corpectomy reconstruction using ATPS prototypes compared favorably to posterior systems and superior to anterior plates. From the biomechanical point, the 360° instrumentation was shown the most efficient for reconstruction of 2-level corpectomies. Further studies will elucidate whether fatigue testing will enhance the benefit of transpedicular anchorage with posterior constructs and ATPS.

Abddullah KG, Steinmetz MP, Mroz TE (2009) Morphometric and volumetric analysis of the lateral masses of the lower cervical spine. Spine 34:1476–1479CrossRef

Abumi K, Shono Y, Taneichi H, Itoh M, Kaneda K (1999) Correction of cervical kyphosis using pedicle screw fixation systems. Spine 24:2456–2462CrossRef

Acosta LF, Aryan HE, Chou D, Ames CP (2008) Long-term biomechanical stability and clinical improvement after extended multilevel corpectomy and circumferential reconstruction of the cervical spine using titanium mesh cages. J Spinal Disord Tech 21:165–174PubMedCrossRef

Ames PC, Bozkus MH, Chamberlain RH, Acosta FL, Papadopoulos SM, Sonntag VKH, Crawford NR (2005) Biomechanics of stabilization after cervicothoracic compression-flexion injury. Spine 30:1505–1512PubMedCrossRef

Aramomi M, Masaki Y, Koshizuka, Kadota R, Okawa A, Koda M, Yamazaki M (2008) Anterior pedicle screw fixation for multilevel cervical corpectomy and spinal fusion. Acta Neurochir 150:575–582CrossRef

Aryan HE, Sanchez-Mejia RO, Ben-Haim S, Ames CP (2007) Successful treatment of cervical myelopathy with minimal morbidity by circumferential decompression and fusion. Eur Spine J 16:1401–1409PubMedCrossRef

Bogduk N, Mercer S (2000) Biomechanics of the cervical spine. I: Normal kinematics. Clin Biomech 15:633–648CrossRef

Bozkus H, Ames CP, Chamberlain RH, Nottmeier EW, Sonntag VKH, Papadopoulos SM, Crawford NR (2005) Biomechanical analysis of rigid stabilization techniques for three-column injury in the lower cervical spine. Spine 30:915–922PubMedCrossRef

Bransford RJ, Russo A, Freeborn M, Nuyen Q, Lee MJ, Chapman J, Bellabarba C (2009) Posterior C2 instrumentation: accuracy and risks associated with four techniques. In: 16th international meeting on advanced spine technologies, Vienna

10.

Brazenor GA (2007) Comparison of multisegment anterior cervical fixation using bone graft versus a titanium rod and buttress prosthesis. Spine 32:63–71PubMedCrossRef

11.

Brodke DS, Klimo P, bachus KN, Braun JT, Dailey AT (2006) Anterior cervical fixation: analysis of load-sharing and stability with use of static and dynamic plates. J Bone Joint Surg 88-A:1566–1573CrossRef

12.

Cha SH, Kim C, Choi BK, Kim HJ, Baek SY (2007) C-arm assessment of cervical pedicle screw-coaxial fluoroscopy and oblique view. Eur Spine J 32:1721–1727

13.

Cheng BC, Hafez MA, Cunningham B, Hassan S, Welch WC (2008) Biomechanical evaluation of occipitocervicothoracic fusion: impact of partial or sequential fixation. Spine J 8:821–826PubMedCrossRef

14.

Dahdaleh NS, Nakamura S, Torner JC, Lim TH, Hitchon PW (2009) Biomechanical rigidity of cadaveric cervical spine with posterior versus combined posterior and anterior instrumentation. J Neurosurg Spine 10:133–138PubMedCrossRef

15.

Dailey A, Fassett D, Finn M, Bacchus K, Brodke D (2008) Do dynamic cervical plates provide adequate stability in flexion distraction injuries? In: Annual meeting of the CSRS, Austin, TX

16.

Dmitriev AE, Kuklo TR, Jr Lehman RA, Rosner MK (2007) Stabilizing potential of anterior, posterior, and circumferential fixation for multilevel cervical arthrodesis. Spine 32:E188–E196PubMedCrossRef

17.

Do Koh Y, Lim TH, Won You J, Eck J, An HS (2001) A biomechanical comparison of modern anterior and posterior plate fixation of the cervical spine. Spine 26:15–21PubMedCrossRef

18.

Dvorak MF, Pitzen T, Zhu Q, Gordon JD, Fisher CG, Oxland TR (2005) Anterior cervical plate fixation: a biomechanical study to evaluate the effects of plate design, endplate preparation, and bone mineral density. Spine 30:294–301PubMedCrossRef

19.

Hart R, Gillard J, Prem S, Shea M, Kitchel S (2005) Comparison of stiffness and failure load of two cervical spine fixation techniques in an in vitro human model. J Spinal Disord Tech 18:S115–S118PubMedCrossRef

20.

Hart RA, Tatsumi RL, Hiratzka JR, Yoo JU (2008) Perioperative complications of combined anterior and posterior cervical decompression and fusion crossing the cervico-thoracic junction. Spine 33:2887–2891PubMedCrossRef

21.

Hasegawa K, Hirano T, Shimoda H, Homma T, Morita O (2008) Indications for cervical pedicle screw instrumentation in nontraumatic lesions. Spine 33:2284–2289PubMedCrossRef

22.

Hostin RA, Wu C, Perra JH, Polly DW, Akesen B, Wroblewski M (2008) A biomechanical evaluation of three revision screw strategies for failed lateral mass fixation. Spine 33:2415–2421PubMedCrossRef

23.

Ianuzzi A, Zambrano I, Tataria J, Ameerally A, Agulnick M, Little Goodwin JSL, Stephen M, Khalsa PS (2006) Biomechanical evaluation of surgical constructs for stabilization of cervical teardrop fractures. Spine J 6:514–523PubMedCrossRef

24.

Isomi T, Panjabi MM, Wang JL, Vaccaro AR, Garfin SR, Patel T (1999) Stabilizing potential of anterior cervical plates in multilevel corpectomies. Spine 24:2219–2223PubMedCrossRef

25.

Ito Y, Sugimoto Y, Tomioka M, Hasegawa Y, Nakago K, Yagata Y (2008) Clinical accuracy of 3D fluoroscopy-assisted cervical pedicle screw insertion. J Neurosurg Spine 9:450–453PubMedCrossRef

26.

Johnston LT, Karaikovic EE, Lautenschlager EP, Marcu D (2006) Cervical pedicle screws vs. lateral mass screws: uniplanar fatigue analysis and residual pullout strengths. Spine J 6:667–672PubMedCrossRef

27.

Jones EL, Heller JG, Silcox DH, Hutton WC (1997) Cervical pedicle screws versus lateral mass screws: anatomic feasibility and biomechanical comparison. Spine 22:977–982PubMedCrossRef

28.

Kast E, Mohr K, Richter HP, Börm W (2006) Complications of transpedicular screw fixation in the cervical spine. Eur Spine J 15:327–334PubMedCrossRef

29.

Koller H, Acosta F, Tauber M, Fox M, Martin H, Forstner R, Augat P, Penzkofer R, Pirich C, Kässmann H, Resch H, Hitzl W (2008) Cervical anterior transpedicular screw fixation (ATPS)—Part II. Accuracy of manual insertion and pull-out strength of ATPS. Eur Spine J 17:539–555PubMedCrossRef

30.

Koller H, Hempfing A, Acosta F, Fox M, Scheiter A, Tauber M, Holz U, Resch H, Hitzl W (2008) Cervical anterior transpedicular screw fixation. Part I: Study on morphological feasibility, indications, and technical prerequisites. Eur Spine J 17:523–538PubMedCrossRef

31.

Koller H, Hempfing A, Ferraris L, Meier O, Metz-Stavenhagen P (2006) 4- and 5-level anterior fusions of the cervical spine: review of literature and clinical results. Eur Spine J 16:2055–2071CrossRef

32.

Koller H, Hitzl W, Acosta F, Tauber M, Zenner J, Resch H, Yukawa Y, Meier O, Schmidt R, Mayer M (2009) In vitro study of accuracy of cervical pedicle screw insertion using an electronic conductivity device (ATPS part III). Eur Spine J 18(9):1300–1313

33.

Kotani Y, Cunningham BW, Abumi K, McAfee PC (1994) Biomechanical analysis of cervical stabilization systems. An assessment of transpedicular screw fixation in the cervical spine. Spine 19:2529–2539PubMedCrossRef

34.

Kothe R, Rüter W, Schneider E, Linke B (2004) Biomechanical analysis of transpedicular screw fixation in the subaxial cervical spine. Spine 29:1869–1875PubMedCrossRef

35.

Kristof RA, Kiefer T, Thudium M, Ringel F, Stoffel M, Kovacs A, Mueller C-A (2009) Comparison of ventral corpectomy and plate-screw-instrumented fusion with dorsal laminectomy and rod-screw-instrumented fusion for treatment of at least two vertebral-level spondylotic cervical myelopathy. Eur Spine J 18(12):1951–1956

36.

Lindsey C, Deviren V, Xu Z, Yeh RF, Puttlitz CM (2009) The effects of rod countering on spinal construct fatigue strength. Spine 31:1680–1687CrossRef

37.

Lu J, Wu X, Li Yonggang, Kong X (2007) Surgical results of anterior corpectomy in the aged patients with cervical myelopathy. Eur Spine J 17:129–135PubMedCrossRef

38.

Mummaneni PV, Dhall SS, Rodts GE, Haid RW (2008) Circumferential fusion for cervical kyphotic deformity. J Neurosurg Spine 9:515–521PubMedCrossRef

39.

O’Brien JR, Dmitriev AE, Yu W, Gelb D, Ludwig S (2009) Posterior-only stabilization of 2-column and 3-column injuries at the cervicothoracic junction. J Spinal Disord 22:340–346CrossRef

40.

O’Shaughnessy BA, Liu JC, Hsieh PC, Koski TR, Ganju A, Ondra SL (2008) Surgical treatment of fixed cervical kyphosis with myelopathy. Spine 33:771–778PubMedCrossRef

41.

Panjabi MM, Isomi T, Wang JL (1999) Loosening at the screw-vertebra junction in multilevel anterior cervical plate constructs. Spine 24:2383–2388PubMedCrossRef

42.

Panjabi MM, Krag M, Summers D, videmann T (1985) Biomechanical time-tolerance of fresh cadaveric human spine specimens. J Orthop Res 3:292–300PubMedCrossRef

43.

Porter RW, Crawford NR, Chamberlain RH, Park SC, Detwiler PW, Apostolides PJ, Sonntag VKH (2003) Biomechanical analysis of multilevel cervical corpectomy and plate constructs. J Neurosurg 99:98–103PubMed

44.

Rath SA, Moszko S, Schäffner PM, Cantone G, Braun V, Richter HP, Antoniadis G (2008) Accuracy of pedicle screw insertion in the cervical spine for internal fixation using frameless stereotactic guidance. J Neurosurg Spine 8:237–245PubMedCrossRef

45.

Ratliff J, Cooper PR (2003) Cervical laminoplasty: a critical review. J Neurosurg 98:230–238PubMed

46.

Sakamoto T, Neo M, Nakamura T (2004) Transpedicular screw placement evaluated by axial computed tomography of the cervical pedicle. Spine 22:2510–2514CrossRef

47.

Sakaura H, Hosono N, Mukai Y, Ishii T, Iwasaki M, Yoshikawa H (2005) Long-term outcome of laminoplasty for cervical myelopathy due to disc herniation: a comparative study of laminoplasty and anterior spinal fusion. Spine 30:756–759PubMedCrossRef

48.

Sandler AJ, Dvorak J, Humke T, Grob D, Daniels W (1996) The effectiveness of various cervical orthoses. Spine 21:1624–1629PubMedCrossRef

49.

Schlenk RP, Stewart T, Benzel EC (2003) The biomechanics of iatrogenic spinal destabilization and implant failure. Neurosurg Focus 15(3):E2

50.

Schmidt R, Wilke HJ, Claes L, Puhl W, Richter M (2005) Effect of constrained posterior screw and rod systems for primary stability: biomechanical in vitro comparison of various instrumentations in a single-level corpectomy model. Eur Spine J 14:372–380PubMedCrossRef

51.

Schmidt R, Wilke HJ, Claes L, Puhl W, Richter M (2003) Pedicle screws enhance primary stability in multilevel cervical corpectomies: biomechanical in vitro comparison of different implants including constrained and nonconstrained posterior instruments. Spine 16:1821–1828CrossRef

52.

Schneider AM, Hipp JA, Nguyen L, Reitman CA (2007) Reduction in head and intervertebral motion provided by 7 contemporary cervical orthoses in 45 individuals. Spine 32:E-1–E-6CrossRef

53.

Sembrano JN, Mehbod AA, Garvey TA, Denis F, Perra JH, Schwender JD, Transfeldt EE, Winter RB, Wroblewski M (2009) A concomitant posterior approach improves fusion rates but not overall reoperation rates in multilevel cervical fusion for spondylosis. J Spinal Disord Tech 22:162–169PubMedCrossRef

54.

Singh K, Vaccaro AR, Kim J, Lorenz EP, Lim TH, An HS (2003) Biomechanical comparison of cervical spine reconstructive techniques after a multilevel corpectomy of the cervical spine. Spine 28:2352–2357, 2358

55.

Steinmetz MP, Stewart TJ, Kager CD, Benzel EC, Vaccaro AR (2007) Cervical deformity correction. Neurosurg 60(Suppl):S90–S97CrossRef

56.

Suda K, Kajino T, Moridaira H, Limoto S, Taneichi H (2008) How to avoid fatal vascular complications caused by pedicle screws—surgical strategy for safe screw placement. Spineweek, Geneva

57.

Wei-bing X, Wun-Jer S, Lv Gang, Yue Z, Ming-xi J, Lian-shun J (2009) Reconstructive techniques study after anterior decompression of multilevel cervical spondylotic myelopathy. J Spinal Disord Tech 22:511–515PubMedCrossRef

58.

Wilke HJ, Claes L, Schmitt H, Wolf S (1994) A universal spine tester for in vitro experiments with muscle force simulation. Eur Spine J 3:91–97PubMedCrossRef

59.

Wilke HJ, Jungkunz B, Wenger K, Claes LE (1998) 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. Anat Rec 251:15–19PubMedCrossRef

60.

Wilke HJ, Wenger K, Claes L (1998) Testing criteria for spinal implants: recommendations for the standardization of in vitro stability testing of spinal implants. Eur Spine J 7:148–154PubMedCrossRef

61.

Wolfa CE (2006) Anatomical, biomechanical, and practical considerations in posterior occipitocervical instrumentation. Spine J 6:225S–232SCrossRef

62.

Yukawa Y, Kato F, Ito K, Horie Y, Hida T, Nakashima H, Machino M (2008) Placement and complications of cervical pedicle screws in 144 cervical trauma patients using pedicle axis view techniques by fluoroscope. Eur Spine J 18:1293–1299CrossRef

63.

Yukawa Y, Kato F, Ito K, Nakashima H, Machino M (2009) Anterior cervical pedicle screw and plate fixation using fluoroscope-assisted pedicle axis view imaging: a preliminary report of a new cervical reconstruction technique. Eur Spine J 18:911–916PubMedCrossRef

Title: The stabilizing potential of anterior, posterior and combined techniques for the reconstruction of a 2-level cervical corpectomy model: biomechanical study and first results of ATPS prototyping
Authors: Heiko Koller
Rene Schmidt
Michael Mayer
Wolfgang Hitzl
Juliane Zenner
Stefan Middendorf
Nicolaus Gräf
H. Resch
Hans-Joachim Willke
Publication date: 01-12-2010
Publisher: Springer-Verlag
Published in: European Spine Journal / Issue 12/2010
Print ISSN: 0940-6719
Electronic ISSN: 1432-0932
DOI: https://doi.org/10.1007/s00586-010-1503-x

At a glance: The ONWARDS insulin icodec trials

Springer Medicine

The stabilizing potential of anterior, posterior and combined techniques for the reconstruction of a 2-level cervical corpectomy model: biomechanical study and first results of ATPS prototyping

Abstract

At a glance: The ONWARDS insulin icodec trials

Springer Medicine

Abstract

Please log in to get access to this content

Other articles of this Issue 12/2010

Benchmarking in the SWISSspine Registry: results of 52 Dynardi lumbar total disc replacements compared with the data pool of 431 other lumbar disc prostheses

Biomechanical and histological evaluation of an expandable pedicle screw in osteoporotic spine in sheep

Correction of post-traumatic hyperkyphosis of the upper thoracic spine by multiple Chevron osteotomies

The results of simultaneous posterior–anterior–posterior surgery in multilevel tuberculosis spondylitis associated with severe kyphosis

Correction of posttraumatic kyphosis of the thoracolumbar spine with modified pedicle subtraction osteotomy

Announcements for issue 11, 2010