ANULUS FISSURES: AN IDEAL MICRO-ENVIRONMENT FOR THE INGROWTH OF NERVES AND BLOOD VESSELS INTO HUMAN INTERVERTEBRAL DISCS

M Stefanakis; J Luo; I Harding; P Dolan; MA Adams

doi:10.1302/1358-992X.94BSUPP_I.SBPR2010-028

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ANULUS FISSURES: AN IDEAL MICRO-ENVIRONMENT FOR THE INGROWTH OF NERVES AND BLOOD VESSELS INTO HUMAN INTERVERTEBRAL DISCS

The 27th annual ACM SI/GUCCS conference

M Stefanakis
J Luo
I Harding
P Dolan
MA Adams

ANULUS FISSURES: AN IDEAL MICRO-ENVIRONMENT FOR THE INGROWTH OF NERVES AND BLOOD VESSELS INTO HUMAN INTERVERTEBRAL DISCS

Stefanakis M, Luo J, Harding I, Dolan P, Adams M. ANULUS FISSURES: AN IDEAL MICRO-ENVIRONMENT FOR THE INGROWTH OF NERVES AND BLOOD VESSELS INTO HUMAN INTERVERTEBRAL DISCS. Orthop Procs. 2012;94-B(SUPP_I):28-28. doi:10.1302/1358-992X.94BSUPP_I.SBPR2010-028

Stefanakis, M, et al. “ANULUS FISSURES: AN IDEAL MICRO-ENVIRONMENT FOR THE INGROWTH OF NERVES AND BLOOD VESSELS INTO HUMAN INTERVERTEBRAL DISCS.” Orthopaedic Proceedings, vol. 94-B, no. SUPP_I, 2012, pp. 28-28., https://doi.org/10.1302/1358-992X.94BSUPP_I.SBPR2010-028

Stefanakis, M., Luo, J., Harding, I., Dolan, P., & Adams, M. (2012). ANULUS FISSURES: AN IDEAL MICRO-ENVIRONMENT FOR THE INGROWTH OF NERVES AND BLOOD VESSELS INTO HUMAN INTERVERTEBRAL DISCS. Orthopaedic Proceedings, 94-B(SUPP_I), 28-28. https://doi.org/10.1302/1358-992X.94BSUPP_I.SBPR2010-028

Stefanakis, M., Luo, J., Harding, I., Dolan, P. and Adams, M. (2012) “ANULUS FISSURES: AN IDEAL MICRO-ENVIRONMENT FOR THE INGROWTH OF NERVES AND BLOOD VESSELS INTO HUMAN INTERVERTEBRAL DISCS.” Orthopaedic Proceedings, 94-B(SUPP_I), pp. 28-28. Available at: https://doi.org/10.1302/1358-992X.94BSUPP_I.SBPR2010-028

Stefanakis, M, J Luo, I Harding, P Dolan, and MA Adams. “ANULUS FISSURES: AN IDEAL MICRO-ENVIRONMENT FOR THE INGROWTH OF NERVES AND BLOOD VESSELS INTO HUMAN INTERVERTEBRAL DISCS.” Orthopaedic Proceedings 94-B, no. SUPP_I (2012): 28-28. https://doi.org/10.1302/1358-992X.94BSUPP_I.SBPR2010-028

Stefanakis M, Luo J, Harding I, Dolan P, Adams M. ANULUS FISSURES: AN IDEAL MICRO-ENVIRONMENT FOR THE INGROWTH OF NERVES AND BLOOD VESSELS INTO HUMAN INTERVERTEBRAL DISCS. Orthop Procs. 2012 Jan 1;94-B(SUPP_I):28-28. https://doi.org/10.1302/1358-992X.94BSUPP_I.SBPR2010-028

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Abstract

Background

Fissures in the anulus fibrosus are common in disc degeneration, and are associated with discogenic pain. We hypothesise that anulus fissures are conducive to the ingrowth of blood vessels and nerves.

Purpose

To investigate the mechanical and chemical micro-environment of anulus fissures.

Methods

Six thoracolumbar spine specimens, comprising three vertebrae and two discs, were obtained from cadavers aged 68-83 yr. Discs were injected with blue dye to reveal the location of complete anulus fissures. Each specimen was then subjected to 1000 N compression, while intradiscal compressive stress was investigated by pulling a miniature pressure transducer through the disc, in planes likely to cross the anulus fissures. Some additional disc fragments were removed at surgery from patients with discogenic back pain, and examined histologically to gauge the concentration of collagen and proteoglycans within radial fissures, using a qualitative method.

Results

Stress profiles were obtained perpendicular to major anulus fissures in seven discs. A marked local reduction in vertically-acting compressive stress usually coincided with fissure location (confirmed at dissection), and stress reductions were inversely proportional to average pressure in the nucleus (r²=0.56, p<0.05). Surgical disc samples showed local depletion of proteoglycans around the margins of radial and circumferential fissures, leaving a collagen-rich scaffold of the type known to support nerve and blood vessel growth.

Conclusion

Compressive stresses within anulus fissures are reduced most when the disc nucleus is decompressed, because this facilitates internal displacements of disrupted tissue. Anulus fissures provide a micro-environment that is mechanically and chemically conducive to the ingrowth of blood vessels and nerves.

Conflicts of interest: None

Source of Funding: M Stefanakis is funded by a Greek Institute of Scholarships (I.K.Y) Award.

We can confirm that this abstract has not been published previously in whole or substantial part and that they have not been presented previously at a national meeting.