SUTURE ANCHOR FAILURE STRENGTH - AN IN-VIVO STUDY

被引：90

作者：

BARBER, FA ^{[1
]}

CAWLEY, P ^{[1
]}

PRUDICH, JF ^{[1
]}

机构：

[1] PLANO ORTHOPED & SPORTS MED CTR,PLANO,TX

来源：

ARTHROSCOPY | 1993年 / 9卷 / 06期

关键词：

SUTURE ANCHOR; MITEK; STATAK; EXPANDING SUTURE PLUG; TAG WEDGE;

D O I：

10.1016/S0749-8063(05)80500-6

中图分类号：

R826.8 [整形外科学]; R782.2 [口腔颌面部整形外科学]; R726.2 [小儿整形外科学]; R62 [整形外科学（修复外科学）];

学科分类号：

摘要：

Suture anchors are increasingly used to secure tendons or ligaments to bone. These devices are applicable for arthroscopic shoulder stabilization and rotator cuff repair. This study reports the in vivo characteristics of four anchors, including one absorbable anchor composed of poly-L-lactic acid. Failure strength and method of failure were recorded for these anchors as a function of time. Samples of four anchors [Mitek G2, Zimmer Statak, Acufex TAG wedge, and the absorbable Arthrex expanding suture plug (ESP)] were implanted into ram femurs and harvested at intervals. Each bone-anchor-suture system was stressed to failure. The failure force and failure method was recorded. Mitek G2 and Statak suture anchors failed consistently at 30 pounds by suture breakage. They had no implantation difficulties. The TAG wedge exhibited suture pull-out and implant flipping at insertion. The TAG wedge failed by suture cut-out, anchor pull-out, and suture breakage. Its average failure strength was initially 16 pounds, but increased to 28 pounds at 2 weeks and reached the 30-pound level by 4 weeks. The ESP poly-L-lactic acid anchors experienced implantation breakage in 20% because of their greater length and composition. At pull-out testing, the ESP failed by suture cut-out, anchor pull-out, and suture breakage. Failure strength was initially 27 pounds, was 17 pounds at 2 weeks, and increased to 30 pounds by 6 weeks. The absorbable ESP does not have initial pull-out strength comparable with the Mitek and Statak suture anchors but does achieve this strength by 6 weeks. This information should provide insight about the suitability of these suture anchors in the clinical setting.

引用

页码：647 / 652

页数：6

共 9 条

[1]

Richmond JC, Donaldson WR, Fu F, Harner CD, Modification of the Bankart reconstruction with a suture anchor report of a new technique, Am J Sports Med, 19, pp. 343-346, (1991)

[2]

Bartlett EC, Suture anchors for arthroscopic rotator cuff repair, Instructional course, Arthroscopy Association of North America annual meeting, (1993)

[3]

Zuckerman JD, Spivak JM, Richmond JC, Et al., Anterior shoulder repairs using a suture to bone anchor: description of technique and clinical results, AAOS Technical Exhibit 3716, (1991)

[4]

Carpenter JE, Fish DN, Huston LJ, Goldstein SA, Pull-out strength of five suture anchors, Arthroscopy, 9, pp. 109-113, (1993)

[5]

Rozema FR, Bos RRM, Boering G, Leenslag JW, Pennings AJ, Verweil AB, Absorbable bone-plates and screws for the fixation of malar fractures. Implant materials in biofunction, Advances in biomaterials, 8, pp. 251-255, (1988)

[6]

Nakamura T, Shimamoto T, Watanabe S, Shimizu Y, Hyon SH, Ikada Y, Ueber die anwendung von in vivo zersetzbaren polymeren in der thoraxchirurgie, Makromolekulare Chemie. Macromolecular Symposia, 19, pp. 201-208, (1988)

[7]

Chabot F, Christel P, Vert M, In vivo tests of bioresorbable bone plates in long lasting poly(L-lactic acid), Presented at the UPAC Symposium, Polymers in Medicine and Biology, (1987)

[8]

Vert M, Christel P, Chabot F, Leray J, Macromolecular biomaterials, (1984)

[9]

Elrod BF, Arthroscopic shoulder stabilization with a bioabsorbable Tak, Presented at the Arthroscopy Association of North America annual meeting, (1993)

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