A BIOMECHANICAL INVESTIGATION OF SHORT SEGMENT SPINAL FIXATION FOR BURST FRACTURES WITH VARYING DEGREES OF POSTERIOR DISRUPTION

被引：39

作者：

MANN, KA ^{[1
]}

MCGOWAN, DP ^{[1
]}

FREDRICKSON, BE ^{[1
]}

FALAHEE, M ^{[1
]}

YUAN, HA ^{[1
]}

机构：

[1] SUNY HLTH SCI CTR,DEPT ORTHOPED SURG,750 E ADAMS ST,SYRACUSE,NY 13210

来源：

SPINE | 1990年 / 15卷 / 06期

关键词：

Biomechanical testing; Fixateur interne; Internal fixation devices; Spinal fracture; Syracuse l-plate;

D O I：

10.1097/00007632-199006000-00008

中图分类号：

R74 [神经病学与精神病学];

学科分类号：

摘要：

A biomechanical study was performed to evaluate the effectiveness of the Fixateur Interne pedicle screw system and the Syracuse I-Plate anterior fixation system. A total of 12 fresh frozen cadaver spines were tested intact, after burst fracture was created and application of a fixation device (six each), and after six serial transections of posterior ligaments and bony structures. Spines were loaded to a maximum of 10 N-m in flexion, extension, left and right lateral bending, and clockwise and counterclockwise rotation. Results indicate that both systems reduce spinal flexibility in flexion, extension, and lateral bend loading when used to reduce and fix a classic burst fracture without posterior disruption. No decrease in flexibility was found in axial rotation for either device. After transection of all posterior elements, the l-Plate construct became much more flexible than the intact spine in flexion, extension, and axial rotation loading. The internal fixator construct retained more stability than the l-Plate construct after transection of posterior elements in flexion and extension loading, but was considerably more flexible than the intact spine in axial rotation loading. The results imply that the posterior internal fixator provides much better stabilization than the anterior I- Plate for those cases in which there is a large amount of posterior disruption in addition to an anterior burst injury. Neither device provides extensive support in axial rotation loading. © Lippincott-Raven Publishers.

引用

页码：470 / 478

页数：9

共 22 条

[1]

Cook S.D., Barrack R.L., Georgette F.S., Et al., An analysis of failed Harrington rods, Spine, 10, pp. 313-316, (1985)

[2]

Dick W., Kluger P., Magerl F., Woersdorfer 0, Zach G: A new device for internal fixation of thoracolumbar and lumbar spine fractures: The ‘Fixateur Interne, Paraplegia, 23, pp. 225-232, (1985)

[3]

Dunn H.K., Anterior stabilization of thoracolumbar injuries, Clin Orthop, 189, pp. 116-124, (1984)

[4]

Flesch J.R., Leider L.L., Erickson D.L., Chou S.N., Bradford D.S., Harrington instrumentation and spine fusion for unstable fractures and fracture-disloca- tions of the thoracic and lumbar spine, J Bone Joint Surg, 59 A, pp. 143-151, (1977)

[5]

Gertzbein S.D., Macmichael D., Tile M., Harrington instrumentation as a method of fixation in fractures of the spine: A critical analysis of deficiencies, J Bone Joint Surg, 64, pp. 526-529, (1982)

[6]

Harrington P.R., Treatment of scoliosis—Correction and internal fixation by spine instrumentation, J Bone Joint Surg, 44 A, pp. 5910-6610, (1962)

[7]

Kaneda K., Abumi K., Fujiya M., Burst fractures with neurologic deficits of the thoracolumbar spine: Results of anterior decompression and stabilization with anterior instrumentation, Spine, 9, pp. 788-795, (1984)

[8]

Kostuik J.P., Anterior spinal cord decompression for lesions of the thoracic and lumbar spine: Techniques, new methods of internal fixation, results, Spine, 8, pp. 512-531, (1983)

[9]

Krag M.H., Beynnon B.D., Pope M.H., Et al., An internal fixator for posterior application to short segments of the thoracic, lumbar, or lumbosacral spine: Design and testing, Clin Orthop, 203, pp. 75-98, (1986)

[10]

Luque E.R., Cassis N., Ramirez-Wiella G., Segmental spinal instrumentation in the treatment of fractures of the thoraco-lumbar spine, Spine, 7, pp. 312-317, (1982)

← 1 2 3 →