Literature DB >> 25982624

Arthroscopic anterior talofibular ligament repair for lateral instability of the ankle.

Masato Takao¹, Kentaro Matsui², James W Stone³, Mark A Glazebrook⁴, John G Kennedy⁵, Stephane Guillo⁶, James D Calder⁷, Jon Karlsson⁸.

Abstract

UNLABELLED: Although several arthroscopic procedures for lateral ligament instability of the ankle have been reported recently, it is difficult to augment the reconstruction by arthroscopically tightening the inferior extensor retinaculum. There is also concern that when using the inferior extensor retinaculum, this is not strictly an anatomical repair since its calcaneal attachment is different to that of the calcaneofibular ligament. If a ligament repair is completed firmly, it is unnecessary to add argumentation with inferior extensor retinaculum. The authors describe a simplified technique, repair of the lateral ligament alone using a lasso-loop stitch, which avoids additionally tighten the inferior extensor retinaculum. In this paper, it is described an arthroscopic anterior talofibular ligament repair using lasso-loop stitch alone for lateral instability of the ankle that is likely safe for patients and minimal invasive. LEVEL OF EVIDENCE: Therapeutic study, Level V.

Entities: Chemical Disease Species

Keywords: Ankle arthroscopy; Anterior talofibular ligament; Arthroscopic repair; Lasso-loop stitch; Lateral instability of the ankle; Self-cinching stitch

Mesh：

Year: 2015 PMID： 25982624 PMCID： PMC4823369 DOI： 10.1007/s00167-015-3638-0

Source DB: PubMed Journal: Knee Surg Sports Traumatol Arthrosc ISSN： 0942-2056 Impact factor: 4.342

Introduction

Lateral ligament reconstruction of the ankle is indicated when conservative measures have failed to improve functional lateral ankle instability in order to prevent subsequent disorders such as osteochondral lesions of the talar dome and osteoarthritis of the ankle [8–10, 17]. The direct anatomic repair of lateral ligaments of the ankle, originally described by Broström [4], is popular, and the subsequent augmentation of the technique by additionally tightening the inferior extensor retinaculum (IER) has resulted in good outcomes being reported in the literature [11]. However, the open technique requires at least a 4-cm-long incision with significant dissection and soft tissue debridement, and it sometimes causes superficial nerve injury [11]. Recently, several authors have reported good results using an arthroscopy-assisted lateral ligament repair [1, 5–7, 12, 14, 15, 18]. Most of them also attempted to reinforce the construct by using the IER but found that this was both technically difficult and added significant surgery time to the procedure [2]. There is also concern that when using the IER, this is not strictly an anatomical repair since its calcaneal attachment is 10 mm anterior to that of the calcaneofibular ligament (CFL) and this may thus restrict full plantar flexion of the ankle. The need to reinforce lateral ligament repair with the IER is therefore debatable [3]. The lasso-loop stitch is one of the self-cinching stitches [13]. Previous studies have shown that they have superior tissue-holding strength when compared to equivalent non-self-cinching stitches, and it is widely used with good clinical results in shoulder surgery to aid margin convergence in rotator cuff repairs and as traction sutures during stabilization procedure [16]. The lasso-loop stitch is also simple and easy to use in a narrow working space. The authors introduced a lasso-loop stitch to arthroscopic repair of the ATFL alone.

Technical note

The patient is placed in a supine position on an operating table under spinal or general anaesthesia. It is important keep the ankle elevated above the opposite leg by approximately 20 cm using a leg holder with the foot at the distal edge of the bed in order to allow full dorsiflexion of the ankle. No distraction of the ankle joint was necessary. A 2.7 mm, 30° arthroscope was used with an irrigation pump at 60 mmHg. Two initial anterior arthroscopy portals were used—the arthroscope was introduced through a medial midline (MML) portal just lateral to the tibialis anterior tendon, and this portal was used to identify the correct position for the accessory anterolateral (AAL) working portal by trans-illumination of the skin (Fig. 1). A needle was used to ensure the correct position of the portal enabling dissection to the fibular ATFL attachment prior to skin incision and blunt dissection with a mosquito clip. Hypertrophic scar tissue was removed where necessary from the lateral gutter using a motorized shaver via the AAL portal, while all other soft tissue including joint capsule and fibula periosteum was left intact.

Fig. 1

Portals (MML medial midline portal, AAL accessory anterolateral portal, TA tibialis anterior tendon, LM lateral malleolus)

Portals (MML medial midline portal, AAL accessory anterolateral portal, TA tibialis anterior tendon, LM lateral malleolus) A suture anchor is placed in the fibula ATFL footprint via the ALL portal. The correct position is ensured by identifying the fibula attachment of the anterior inferior tibiofibular ligament (AITFL) and the drill hole made approximately 7 mm distal to the lower edge of the AITFL. The anchor is then inserted into this hole and leaving the anchor sutures exiting through the ALL portal (Fig. 2).

Fig. 2

Placing a suture anchor. Arthroscopic view (middle, LM lateral malleolus, C cannula, R remnant of the anterior talofibular ligament)

Placing a suture anchor. Arthroscopic view (middle, LM lateral malleolus, C cannula, R remnant of the anterior talofibular ligament) For the lasso-loop stitch, an 18G hollow needle with a 2-0 nylon thread is placed through the ALL portal and into distal ATFL remnant. The needle is rotated several times one way and then in the opposite direction, enlarging the nylon loop (Fig. 3). The loop of the nylon is retrieved through the ALL portal with a grasping instrument, and the needle is then withdrawn. One end of the anchor suture is then passed through the loop of nylon. The nylon loop is then used to pull just the mid-portion of the anchor suture through the ATFL such that a loop of suture is created in the ATFL. The free end of the suture is then passed through this loop and pulled tight creating a self-cinching stitch (Fig. 4). The other end of the anchor suture is then used to draw the self-cinching stitch tightening the ATFL (Fig. 5). Then, square knot and granny knot are done two times using a knot pusher by turns to an axial thread (Fig. 6).

Fig. 3

Fig. 4

Suture relay technique. The loop of the nylon is retrieved through the ALL portal with a grasping instrument (left). One end of the anchor suture is then passed through the loop of nylon (second from the left). The nylon loop is then used to pull just the mid-portion of the anchor suture through the ATFL such that a loop of suture is created in the ATFL (middle). The free end of the suture is then passed through this loop (second from the right) and pulled tight creating a self-clinching stitch (right)

Fig. 5

Arthroscopic view. End of a remnant of the ATFL (left) is moved to a bone side (right) by pulling contralateral thread (arrowhead: End of a remnant of the ATFL, LM lateral malleolus)

Fig. 6

Square knot by turns to an axial thread using a knot pusher

Inserting a needle into distal ATFL remnant. An 18G hollow needle with a 2-0 nylon thread is placed into distal ATFL remnant. The needle is rotated several times one way and then in the opposite direction, enlarging the nylon loop Suture relay technique. The loop of the nylon is retrieved through the ALL portal with a grasping instrument (left). One end of the anchor suture is then passed through the loop of nylon (second from the left). The nylon loop is then used to pull just the mid-portion of the anchor suture through the ATFL such that a loop of suture is created in the ATFL (middle). The free end of the suture is then passed through this loop (second from the right) and pulled tight creating a self-clinching stitch (right) Arthroscopic view. End of a remnant of the ATFL (left) is moved to a bone side (right) by pulling contralateral thread (arrowhead: End of a remnant of the ATFL, LM lateral malleolus) Square knot by turns to an axial thread using a knot pusher

17 in total

1. Biomechanical evaluation of 3 arthroscopic self-cinching stitches for shoulder arthroscopy: the lasso-loop, lasso-mattress, and double-cinch stitches.

Authors: Brent A Ponce; Chad D Hosemann; Parthasarathy Raghava; Janet P Tate; Alan W Eberhardt; Laurent Lafosse
Journal: Am J Sports Med Date: 2010-11-12 Impact factor: 6.202

2. Extensor retinaculum augmentation reinforces anterior talofibular ligament repair.

Authors: Umur Aydogan; Richard R Glisson; James A Nunley
Journal: Clin Orthop Relat Res Date: 2006-01 Impact factor: 4.176

3. A new technique to improve tissue grip: "the lasso-loop stitch".

Authors: Laurent Lafosse; Antoon Van Raebroeckx; Roman Brzoska
Journal: Arthroscopy Date: 2006-11 Impact factor: 4.772

4. Biomechanical analysis of Brostrom versus Brostrom-Gould lateral ankle instability repairs.

Authors: Steve B Behrens; Mark Drakos; Byung J Lee; Dave Paller; Eve Hoffman; Sarath Koruprolu; Christopher W DiGiovanni
Journal: Foot Ankle Int Date: 2013-02-07 Impact factor: 2.827

5. Arthroscopic Broström repair with Gould augmentation via an accessory anterolateral port for lateral instability of the ankle.

Authors: Kentaro Matsui; Masato Takao; Wataru Miyamoto; Ken Innami; Takashi Matsushita
Journal: Arch Orthop Trauma Surg Date: 2014-07-12 Impact factor: 3.067

6. Arthroscopic-assisted Broström-Gould for chronic ankle instability: a long-term follow-up.

Authors: Caio Nery; Fernando Raduan; Angelo Del Buono; Inacio Diogo Asaumi; Moises Cohen; Nicola Maffulli
Journal: Am J Sports Med Date: 2011-07-29 Impact factor: 6.202

7. Arthroscopic anterior talofibular ligament repair for chronic ankle instability with a suture anchor technique.

Authors: Eung Soo Kim; Kyung Tai Lee; Jun Sic Park; Young Koo Lee
Journal: Orthopedics Date: 2011-04-11 Impact factor: 1.390

8. Arthroscopic suture anchor repair of the lateral ligament ankle complex: a cadaveric study.

Authors: Eric Giza; Edward C Shin; Stephanie E Wong; Jorge I Acevedo; Peter G Mangone; Kirstina Olson; Matthew J Anderson
Journal: Am J Sports Med Date: 2013-08-27 Impact factor: 6.202

9. The "all inside" arthroscopic Broström procedure: a prospective study of 40 consecutive patients.

Authors: James M Cottom; Ryan B Rigby
Journal: J Foot Ankle Surg Date: 2013-05-11 Impact factor: 1.286

10. All-inside arthroscopic lateral collateral ligament repair for ankle instability with a knotless suture anchor technique.

Authors: Jordi Vega; Pau Golanó; Alexandro Pellegrino; Eduard Rabat; Fernando Peña
Journal: Foot Ankle Int Date: 2013-08-26 Impact factor: 2.827

28 in total

1. Arthroscopic anatomical reconstruction of the lateral ankle ligaments.

Authors: S Guillo; M Takao; J Calder; Jon Karlson; Frederick Michels; Thomas Bauer
Journal: Knee Surg Sports Traumatol Arthrosc Date: 2015-09-25 Impact factor: 4.342

2. Endoscopic reconstruction of CFL and the ATFL with a gracilis graft: a cadaveric study.

Authors: Frederick Michels; Guillaume Cordier; Arne Burssens; Evie Vereecke; Stéphane Guillo
Journal: Knee Surg Sports Traumatol Arthrosc Date: 2015-09-26 Impact factor: 4.342

Review 3. Minimally invasive surgical treatment for chronic ankle instability: a systematic review.

Authors: Kentaro Matsui; Bernard Burgesson; Masato Takao; James Stone; Stéphane Guillo; Mark Glazebrook
Journal: Knee Surg Sports Traumatol Arthrosc Date: 2016-02-11 Impact factor: 4.342

4. All-inside endoscopic anatomic reconstruction leads to satisfactory functional outcomes in patients with chronic ankle instability.

Authors: Stéphane Guillo; Haruki Odagiri; Floris van Rooij; Thomas Bauer; Alexandre Hardy
Journal: Knee Surg Sports Traumatol Arthrosc Date: 2020-06-30 Impact factor: 4.342

5. Arthroscopic ankle lateral ligament repair alone versus arthroscopic ankle lateral ligament repair with reinforcement by inferior extensor retinaculum.

Authors: Yuji Samejima; Ryota Inokuchi; Kosui Iwashita; Hiroyasu Ikegami; Yoshiro Musha; Yasuyuki Jujo; Masato Takao
Journal: Arch Orthop Trauma Surg Date: 2021-01-17 Impact factor: 3.067

6. Arthroscopic modified Broström operation versus open reconstruction with local periosteal flap in chronic ankle instability.

Authors: Moritz Mederake; Ulf Krister Hofmann; Ingmar Ipach
Journal: Arch Orthop Trauma Surg Date: 2021-05-16 Impact factor: 3.067

7. Optimal suture anchor direction in arthroscopic lateral ankle ligament repair.

Authors: Ichiro Yoshimura; Tomonobu Hagio; Masahiro Noda; Kazuki Kanazawa; So Minokawa; Takuaki Yamamoto
Journal: Knee Surg Sports Traumatol Arthrosc Date: 2017-05-26 Impact factor: 4.342

8. Arthroscopic Repair of Ankle Instability With All-Soft Knotless Anchors.

Authors: Hélder Pereira; Gwen Vuurberg; Nuno Gomes; Joaquim Miguel Oliveira; Pedro L Ripoll; Rui Luís Reis; João Espregueira-Mendes; C Niek van Dijk
Journal: Arthrosc Tech Date: 2016-02-01

9. Anatomy of the inferior extensor retinaculum and its role in lateral ankle ligament reconstruction: a pictorial essay.

Authors: M Dalmau-Pastor; Y Yasui; J D Calder; J Karlsson; G M M J Kerkhoffs; J G Kennedy
Journal: Knee Surg Sports Traumatol Arthrosc Date: 2016-04 Impact factor: 4.342

10. Searching for consensus in the approach to patients with chronic lateral ankle instability: ask the expert.

Authors: Frederick Michels; H Pereira; J Calder; G Matricali; M Glazebrook; S Guillo; J Karlsson; Jorge Acevedo; Jorge Batista; Thomas Bauer; James Calder; Dominic Carreira; Woojin Choi; Nuno Corte-Real; Mark Glazebrook; Ali Ghorbani; Eric Giza; Stéphane Guillo; Kenneth Hunt; Jon Karlsson; S W Kong; Jin Woo Lee; Frederick Michels; Andy Molloy; Peter Mangone; Kentaro Matsui; Caio Nery; Saturo Ozeki; Chris Pearce; Hélder Pereira; Anthony Perera; Bas Pijnenburg; Fernando Raduan; James Stone; Masato Takao; Yves Tourné; Jordi Vega
Journal: Knee Surg Sports Traumatol Arthrosc Date: 2017-04-25 Impact factor: 4.342