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Abstract

Background:

The structural importance of the spring ligament complex in arch stability has been described. Furthermore, the pathology of this complex is often noted in patients with posterior tibial tendon dysfunction. The purpose of this biomechanical study was to evaluate spring ligament repair alone versus augmentation with the FiberTape device in a cadaveric flatfoot model.

Methods:

Eight paired, below-the-knee, cadaveric specimens underwent flatfoot creation and reconstruction. The experimental group received augmentation with FiberTape (InternalBrace). After potting, specimens were loaded statically to measure talonavicular contact pressures and flatfoot correction. Cyclic loading was performed in a stepwise fashion. Loading was performed at 1 Hz and 100 cycles, at 100-N intervals from 500 to 1800 N, with the Achilles tendon also loaded to simulate weightbearing in the postoperative period.

Results:

Control specimen analysis demonstrated failures of 8 of 8 (100%) spring ligament suture repairs, occurring through suture cut-through (5 specimens), suture fatigue and elongation (2), or knot failure (1). One of 8 (12.5%) FiberTape-augmented repairs failed after cyclic loading. The difference in number of repair failures was statistically significant between the 2 groups (P = .0014). Analysis revealed that at forces of 1600 N (P = .03) and 1700 N (P = .02) there were statistically significant differences between the FiberTape-augmented group and the control group, with a greater collapse in the lateral Meary talo–first metatarsal angle in the controls. There was no significant difference or abnormal increase in contact pressures of the talonavicular joint in both groups.

Conclusion:

FiberTape augmentation of the spring ligament appears biomechanically safe and effective under cyclic loading.

Clinical relevance:

Spring ligament augmentation with this device may be another biomechanically safe and reasonable treatment modality for surgeons during flatfoot reconstruction. It is possible that early protected weightbearing after these procedures may be performed.

Keywords

spring ligament flatfoot biomechanics cadaveric tendon disorders

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References

Acevedo

Vora

Anatomical reconstruction of the spring ligament complex “Internal Brace” augmentation. Foot Ankle Spec. 2013;6:441-445.

Aydogan

Moore

Andrews

Roush

Kunselman

Lewis

GS.

Comparison of proximal and distal oblique second metatarsal osteotomies with varying Achilles tendon tension: biomechanical study in a cadaver model. J Bone Joint Surg Am. 2015;97(23):1945-1951.

Aydogan

Roush

Moore

Andrews

Lewis

GS.

Biomechanical consequences of adding plantar fascia release to metatarsal osteotomies: changes in forefoot plantar pressures. J Orthop Res. 2017;35(4):800-804.

Baxter

Demetracopoulos

Prado

Tharmviboonsri

Deland

JT.

Lateral column lengthening corrects hindfoot valgus in a cadaveric flatfoot model. Foot Ankle Int. 2015;36(6):705-709.

Coetzee

Ellington

Ronan

Stone

RM.

Functional results of open Broström ankle ligament repair augmented with a suture tape. Foot Ankle Int. 2018;39(3):304-310.

Deland

de Asla

Sung

et al . Posterior tibial tendon insufficiency: which ligaments are involved? Foot Ankle Int. 2005;26(6):427-435

Dumontier

Falicov

Mosca

Sangeorzan

Calcaneal lengthening: investigation of deformity correction in a cadaver flatfoot model. Foot Ankle Int. 2005;26(2):166-170.

Jennings

Christensen

JC.

The effects of sectioning the spring ligament on rearfoot stability and posterior tibial tendon efficiency. J Foot Ankle Surg. 2008;47(3):219-224.

Johnson

Cohen

DiGiovanni

Lamdan

Subtalar arthrodesis with flexor digitorum longus transfer and spring ligament repair for treatment of posterior tibial tendon insufficiency. Foot Ankle Int. 2000;21(9):722-729.

10.

Mann

Thompson

FM.

Rupture of the posterior tibial tendon causing flat foot. Surgical treatment. J Bone Joint Surg Am. 1985;67:556-561.

11.

Patrick

Lewis

Roush

Kunselman

Cain

JD.

Effects of medial displacement calcaneal osteotomy and calcaneal Z osteotomy on subtalar joint pressures: a cadaveric flatfoot model. J Foot Ankle Surg. 2016;55(6):1175-1179.

12.

Viens

Wijdicks

Campbell

LaPrade

Clanton

TO.

Anterior talofibular ligament ruptures, part 1: biomechanical comparison of augmented Broström repair techniques with the intact anterior talofibular ligament. Am J Sports Med. 2014;42(2):405-411.

13.

Zanolli

Glisson

Nunley

Easley

ME.

Biomechanical assessment of flexible flatfoot correction: comparison of techniques in a cadaver model. J Bone Joint Surg Am. 2014;96(6):e45.

Supplementary Material

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Biomechanical Evaluation of Spring Ligament Augmentation With the FiberTape Device in a Cadaveric Flatfoot Model

Abstract

Background:

Methods:

Results:

Conclusion:

Clinical relevance:

Keywords

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References

Supplementary Material