Top

Published in:

01-05-2006 | Original Article

Intradiscal pressure measurements in normal discs, compressed discs and compressed discs treated with axial posterior disc distraction: an experimental study on the rabbit lumbar spine model

Authors: Thorsten Guehring, Frank Unglaub, Helga Lorenz, Georg Omlor, Hans-Joachim Wilke, Markus W. Kroeber

Published in: European Spine Journal | Issue 5/2006

Abstract

Intervertebral disc (IVD) pressure measurement is an appropriate method for characterizing spinal loading conditions. However, there is no human or animal model that provides sufficient IVD pressure data. The aim of our study was to establish physiological pressure values in the rabbit lumbar spine and to determine whether temporary external disc compression and distraction were associated with pressure changes. Measurements were done using a microstructure-based fibreoptic sensor. Data were collected in five control rabbits (N, measurement lying prone at segment L3/4 at day 28), five rabbits with 28 days of axial compression (C, measurement at day 28) and three rabbits with 28 days of axial compression and following 28 days of axial distraction (D, measurement at day 56). Disc compression and distraction was verified by disc height in lateral radiographs. The controls (N) showed a level-related range between 0.25 MPa–0.45 MPa. The IVD pressure was highest at level L3/4 (0.42 MPa; range 0.38–0.45) with a decrease in both cranial and caudal adjacent segments. The result for C was a significant decrease in IVD pressure (0.31 MPa) when compared with controls (P=0.009). D showed slightly higher median IVD pressure (0.32 MPa) compared to C, but significantly lower levels when compared with N (P=0.037). Our results indicate a high range of physiological IVD pressure at different levels of the lumbar rabbit spine. Temporary disc compression reduces pressure when compared with controls. These data support the hypothesis that temporary external compression leads to moderate disc degeneration as a result of degradation of water-binding disc matrix or affected active pumping mechanisms of nutrients into the disc. A stabilization of IVD pressure in discs treated with temporary distraction was observed.

Adams MA, Freeman B, Morrison HP, Nelson IW, Dolan P (2000) Mechanical initiation of intervertebral disc degeneration. Spine 13:1625–1636CrossRef

Castagnera L, Grenier N, Lavignolle B, Greselle JF, Senegas J, Caille JM (1991) Study of correlation between intradiscal pressure and magnetic resonance imaging data in evaluation of disc degeneration. Therapeutic issue with percutaneus nucleotomy. Spine 16(3):348–352PubMed

Chen J, Baer AE, Paik PY, Yan W, Setton LA (2002) Matrix protein gene expression in intervertebral disc cells subjected to altered osmolarity. Biochem Biophys Res Commun 10;293(3):932–938

Cunningham BW, Kotani Y, McNulty PS, Cappuccino A, McAfee PC (1997) The effect of spinal destabilisation and instrumentation on lumbar intradiscal pressure. An in vitro biomechanical analysis. Spine 22:2655–2663CrossRefPubMed

Eck JC, Humphreys SC, Lim TH, Jeong ST, Kim JG, Hodges SD, An HS (2002) Biomechanical study on the effect of cervical spine fusion on adjacent-level intradiscal pressure and segmental motion. Spine 27(22):2431–2434CrossRefPubMed

Freemont AJ, Watkins A, Le Maitre C, Jeziorska M, Hoyland JA (2002) Current understanding of cellular and molecular events in intervertebral disc degeneration: implications for therapy. J Pathol 196:374–379CrossRefPubMed

Höjer S, Krantz M, Ekström L, Kaigle A, Holm S (1999) A microstructure based fiberoptic pressure sensor for measurements in lumbar intervertebral discs. Proc SPIE 3570:115–122CrossRef

Hutton WC, Ganey TM, Elmer WA, Kozlowska EE, Ugbo JL, Doh ES, Whitesides TE (2000) Does long-term compressive loading on the intervertebral disc cause degeneration? Spine 25(23):2993–3004CrossRefPubMed

Iatridis JC, Mente PL, Stokes IA, Aronsson DD, Alini M (1999) Compression-induced changes in intervertebral disc properties in a rat tail model. Spine 24:996–1002CrossRefPubMed

10.

Kroeber MW, Unglaub F,Wang H, Schmid C, Thomsen M, Nerlich A, Richter W (2002) New in vivo animal model to create intervertebral disc degeneration and to investigate the effects of therapeutical strategies to stimulate disc regeneration. Spine 23:2684–2690CrossRef

11.

Kroeber M, Unglaub F, Guehring T, Campana M, Carstens C (2003) Poster presentation ESS Prag 2003, award “best poster in basic science”. Eur Spine J 12(suppl1):S1–S79CrossRefPubMed

12.

Kroeber M, Unglaub F, Guehring T, Nerlich A, Tamer H, Lotz J, Carstens C (2005) Effects of controlled dynamic disc distraction on degenerated intervertebral discs: an in vivo study on the rabbit lumbar spine model. Spine 30(2):181–187CrossRefPubMed

13.

Lotz JC, Colliou OK, Chin JR, Duncan NA, Liebenberg E (1998) Volvo award winner in biomechanical studies. Compression-induced degeneration of the intervertebral disc: An in vivo mouse model and finite-element study. Spine 23:2493–2506CrossRefPubMed

14.

Nachemson AL (1975) Towards a better understanding of low-back pain: a review of the mechanics of the lumbar disc. Rheumatoid Rehabil 14(3):129–143

15.

Panjabi M, Brown M, Lindahl S, Irstam L, Hermens M (1988) Intrinsic disc pressures a measure of integrity of the lumbar spine. Spine 13(8):913–917PubMed

16.

Phillips FM, Reuben J, Wetzel FT (2002) Intervertebral disc degeneration adjacent to a lumbar fusion. An experimental rabbit model. J Bone Joint Surg Br 3;84(2):289–294

17.

Pospiech J, Wilke HJ, Claes LE, Stolke D (1996) Intradiscal pressure forces on cervical intervertebral discs in physiologic and pathologic conditions. In vitro study. Langenbecks Arch Chir 381(6):303–308CrossRefPubMed

18.

Roberts S, Caterson B, Menage J, Evans EH, Jaffray DC, Eisenstein SM (2000) Matrix metalloproteinases and aggrecanase. Spine 23:3005–3013CrossRef

19.

Rubinstein R (1981) Simulation and the Monte Carlo Method. Wiley, New York

20.

Sasaki M, Takahashi T, Miyahara K, Hirose AT (2001) Effects of chondroitinase ABC on intradiscal pressure in sheep: an in vivo study. Spine 26:463–468CrossRefPubMed

21.

Sato K, Kikuchi S, Yonezawa T (1999) In vivo intradiscal pressure measurement in healthy individuals and in patients with ongoing back problems. Spine 23:2468–2474CrossRef

22.

Sato K, Nagata K, Hirohashi T (2002) Intradiscal pressure after repeat intradiscal injection of hypertonic saline:an experimental study. Eur Spine J 11(1):52–56CrossRefPubMed

23.

Sieve J, Baird P, Jeziorsk M, Watkins A, Hoyland JA, Freemont AJ (2002) Expression of chondrocyte markers by cells of normal and degenerative intervertebral discs. J Clin Pathol Mol Pathol 55:91–97

24.

Stoll TM, Dubois G, Schwarzenbach O (2002) The dynamic neutralization system for the spine: a multi-center study of a novel non-fusion system. Eur Spine J 8(11Suppl2):S170–S178

25.

Swanson KE, Lindsey DP, Hsu KY, Zucherman JF, Yerby SA (2003) The effect of an interspinous implantat on intervertebral disc pressure. Spine 28(1):26–32CrossRefPubMed

26.

Unglaub F, Guehring T, Lorenz H, Carstens C, Kroeber MW (2005) Effects of unisegmental dynamic disc compression on adjacent segments: an in vivo animal model. Eur Spine J (epub ahead of publication)

27.

Walsh AJ, Lotz JC (2004) Biological response of the intervertebral disc to dynamic loading. J Biomech 37(3):329–337CrossRefPubMed

28.

Weiler C, Nerlich A, Zipperer J, Bachmeier BE, Boos N (2002) 2002 SSE award competition in basic science: expression of major matrix metalloproteinases is associated with intervertebral disc degradation and resorption. Eur Spine J 11:308–320CrossRefPubMed

29.

Weinhoffer SL, Guyer RD, Herbert M, Griffith SL (1995) Intradiscal pressure measurements above an instrumented fusion. A cadaveric study. Spine 20:526–531PubMed

30.

Wilke H, Neef P, Hinz B, Seidel H, Claes L (2001) Intradiscal pressure together with anthropometric data – a data set for validation of models. Clin Biomech 16(Suppl1):111–126CrossRef

31.

Zöfel P, Bühl A (2000) SPSS Version 10; Einführung in die moderne Datenanlyse unter Windows. Addison Wesley Longman Publishing Group, London

Title: Intradiscal pressure measurements in normal discs, compressed discs and compressed discs treated with axial posterior disc distraction: an experimental study on the rabbit lumbar spine model
Authors: Thorsten Guehring
Frank Unglaub
Helga Lorenz
Georg Omlor
Hans-Joachim Wilke
Markus W. Kroeber
Publication date: 01-05-2006
Publisher: Springer-Verlag
Published in: European Spine Journal / Issue 5/2006
Print ISSN: 0940-6719
Electronic ISSN: 1432-0932
DOI: https://doi.org/10.1007/s00586-005-0953-z

At a glance: The STEP trials

Springer Medicine

Intradiscal pressure measurements in normal discs, compressed discs and compressed discs treated with axial posterior disc distraction: an experimental study on the rabbit lumbar spine model

Abstract

At a glance: The STEP trials

Springer Medicine

Abstract

Please log in to get access to this content

Other articles of this Issue 5/2006

Back extensor muscle fatigue in patients with lumbar disc herniation

A systematic review of bio-psychosocial risk factors for an unfavourable outcome after lumbar disc surgery

Surgical pinealectomy accelerates intervertebral disc degeneration process in chicken

Mono-disciplinary or multidisciplinary back pain guidelines? How can we achieve a common message in primary care?

Lumbar spinal fusion patients’ demands to the primary health sector: evaluation of three rehabilitation protocols. A prospective randomized study

A hypothesis of chronic back pain: ligament subfailure injuries lead to muscle control dysfunction