EARLY ACTIVE MOBILIZATION OF TENDON GRAFTS USING MESH REINFORCED SUTURE TECHNIQUES

被引：15

作者：

SILFVERSKIOLD, KL ^{[1
]}

MAY, EJ ^{[1
]}

机构：

[1] GOTHENBURG UNIV,SAHLGRENS HOSP,DEPT ORTHOPAED SURG,DIV HAND SURG,S-41345 GOTHENBURG,SWEDEN

来源：

JOURNAL OF HAND SURGERY-BRITISH AND EUROPEAN VOLUME | 1995年 / 20B卷 / 03期

关键词：

D O I：

10.1016/S0266-7681(05)80082-8

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：

The flexor digitorum profundus tendon in 11 digits with division of both flexor tendons in zone 2 was reconstructed with a palmaris longus tendon graft in a two-stage procedure, The distal and proximal fixation of the graft was reinforced with a polyester mesh sleeve placed around the ends of the graft during stage 1, All digits were mobilized with a combination of active extension and active and passive flexion within 3 days of the second stage, There were three ruptures, one due to faulty technique and two due to falls on outstretched hands during alcohol intoxication and football, Excluding the ruptures, the mean active composite distal and proximal interphalangeal joint range of motion 6 weeks and 6 months post-operatively was 141 degrees and 136 degrees respectively, The results indicate that palmaris longus tendon grafts can survive and heal during early active mobilization, with few or no adhesions of functional significance. The techniques described here represent one possible approach to the safe implementation of early active mobilization after tendon grafting procedures.

引用

页码：301 / 307

页数：7

共 32 条

[1] Abrahamsson, Gelberman, Lohmander, Variations in cellular proliferation and matrix synthesis in intrasynovial and extrasynovial tendons: An in vitro study in dogs, Journal of Hand Surgery, 19 A, 2, pp. 259-265, (1994)
[2] Amis, Campbell, Kempson, Miller, Comparison of the structure of neotendons induced by implantation of carbon or polyester fibres, Journal of Bone and Joint Surgery, 66 B, 1, pp. 131-139, (1984)
[3] Arnoczky, Torzilli, Warren, Allen, Biologic fixation of ligament prostheses and augmentations: An evaluation of bone ingrowth in the dog, American Journal of Sports Medicine, 16, 2, pp. 106-112, (1988)
[4] Becker, Orak, Duponselle, Early active motion following a beveled technique of flexor tendon repair: Report on fifty cases, Journal of Hand Surgery, 4, 5, pp. 454-460, (1979)
[5] Boyes, Flexor-tendon grafts in the fingers and thumb: An evaluation of end results, Journal of Bone and Joint Surgery, 32 A, 3, pp. 489-499, (1950)
[6] Gelberman, Amiel, Gonsalves, Woo, Akeson, The influence of protected passive mobilization on the healing of flexor tendons: A biochemical and microangiographic study, The Hand, 13, 2, pp. 120-128, (1981)
[7] Gelberman, Chu, Williams, Seiler, Amiel, Angiogenesis in healing autogeous flexor-tendon grafts, Journal of Bone and Joint Surgery, 74 A, 8, pp. 1207-1216, (1992)
[8] Goodship, Wilcock, Shah, The development of tissue around various prosthetic implants used as replacements for ligaments and tendons, Clinical Orthopaedics and Related Research, 196, pp. 61-68, (1985)
[9] Hitchcock, Light, Bunch, Knight, Sartori, Patwardhan, Hollyfield, The effect of immediate constrained digital motion on the strength of flexor tendon repairs in chickens, Journal of Hand Surgery, 12 A, 4, pp. 590-595, (1987)
[10] Hunter, Salisbury, Flexor-tendon reconstruction in severely damaged hands, Journal of Bone and Joint Surgery, 53 A, 5, pp. 829-858, (1971)

← 1 2 3 4 →