Summary
An experimental study was designed to test the efficacy of a silicon barrier around a nerve root in order to prevent post operative epidural root scar adhesions. In 32 Sprague-Dawely rats a lumbar nerve root was microsurgically exposed bilaterally. In 16 animals a silicon tube, prepared with a longitudinal cut along half of its wall, was placed around one nerve root, while the contralateral side served as control. In another group of 12 animals, an autologous subcutaneous fat graft was placed on the exposed root. A group of 4 animals served as the control group which had not been operated upon.
No post operative neurological deficit was observed in any of the animals. All animals were sacrificed 60 days after the operation and a block of tissue including the nerve roots were resected bilaterally without removal of the silicon or fat graft. Longitudinal and transverse cuts of the roots were stained with Haematoxilin and Eosin and with Masson's trichrome collagen stain.
The roots in the “unoperated” control group were clean of any scar tissue. In 13 out of 16 animals, silicon prevented scar formation around the root as opposed to scar adhesions around control root on the contralateral side and as compared to unoperated roots. In the silicon group, adhesions penetrated only through the longitudinal narrow cut edge of the tube. Fat did not prevent adhesions in 11 out of 12 animals.
We conclude that a silicon barrier is an effective method preventing post operative epidural root scarring in rats.
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References
Barbera J, Gonzalez J, Esquerdo J, Broseta J, Barcia-Salorio LJ (1978) Prophylaxis of the laminectomy membrane. An experimental study in dogs. J Neurosurg 49: 419–424
Brayant MS, Bremer A, Nguyen T (1980) Autogenic fat transplant in the epidural space in routine lumbar spine surgery. Neurosurgery 13: 367–370
Burton CV, Kirkaldy-Willis WH, Yong-Hing K, Heithoff KB (1981) Causes of failure of surgery on the lumbar spine. Clin Orthop 157: 191–199
Fager CA, Friedberg SR (1980) Analysis of failure and poor results of lumbar spine surgery. Spine 5: 87–94
Finnegan W, Rothman RH, Fenlin JM, Marvel JP, Nardini RA (1975) Salvage spine surgery. J Bone Joint Surg (A) 57: 1034
Hadani M, Harel A, Solomon A, Beldin M, Lavie V, Schwarts M (1984) Substances originating from the optic nerve of neonatal rabbit induce regeneration-associated response in the injured optic nerve of adult rabbit. Proc Natl Acad Sci U.S.A. 81: 7965–7969
Kivilioto O (1976) Use of free fat transplant to prevent epidural scar formation. An experimental study. Acta Orthop Scand [Suppl] 164: 1–75
Martin-Ferrer S (1989) Failure of autologous fat grafts to prevent postoperative epidural fibrosis in surgery of the lumbar spine. Neurosurgery 24(5): 718–721
North RB, Campbell JN, James CS, Conover-Walker MK, Wang H, Piantadosi S, Rybock JD, Long DM (1991) Failed back syndrome: 5 year follow-up in 102 patients undergoing repeated operation. Neurosurgery 28 (5): 685–691
Schlarb H, Wenker H (1977) Re-operation performed on patients suffering from an intervertebral disc prolapse in the lumbar region. Adv Neurosurg 4: 32–35
Schubiger O, Valabanis A (1982) CT differentiation between recurrent disc herniation and post-operative scar formation. Neuroradiology 22: 251–254
Siquera E, Kranzler L, Dharkar D (1983) Fibrosis of the dura matter. A cause of “failed back” syndrome. Surg Neurol 19: 168–170
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Hadani, M., Ram, Z., Horowitz, A. et al. Silicon prevents post laminectomy epidural root adhesions an experimental study in rats. Acta neurochir 123, 153–156 (1993). https://doi.org/10.1007/BF01401872
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DOI: https://doi.org/10.1007/BF01401872