Ex-vivo biomechanical analysis of an original repair of canine calcaneal tendon rupture using a synthetic implant as mechanical support fixed by sutures in the proximal tendinous part and by an interference screw in the bone distal part

Background: Rupture of the common calcaneal tendon is the second most frequent tendon rupture in dogs and may lead to severe lameness and pain. Surgical repair consists of re-apposition of the damaged tendon ends using sutures, but this type of repair is not always possible especially if the tendon has retracted. Tendon augmentation with an ultra-high molecular weight polyethylene (UHMWPE) implant is a recent solution to support the sutures and allow the repair of the canine calcaneal tendon. However, its biomechanical fixation strength remains untested for this pathology. Aim: To evaluate the biomechanical fixation strength of a UHMWPE implant for the repair of the canine calcaneal tendon. Methods: Ex-vivo biomechanical study was carried out on eight cadaveric hindlimbs from four adult dogs. Hindlimbs were tested under two independent modalities: proximal tendinous fixation (PTF) and distal calcaneus fixation (DCF), using a testing machine. PTF was achieved by eight simple interrupted polypropylene sutures performed through the UHMWPE implant. The latter was sandwiched inside the gastrocnemius tendon, which had previously been incised over about 5 cm longitudinally, and through the tendon of the superficial digital flexor. DCF was performed using an interference screw, which locked the UHMWPE implant into a calcaneus tunnel drilled perpendicularly. Results: Yield, failure load, and linear stiffness (mean ± SD) for the DCF modality were 920 ± 139 N, 1,007 ± 146 N, and 92 ± 15.21, respectively, which were greater than for the PTF modality (663 ± 92 N, 685 ± 84 N and 25.71 ± 5.74, respectively, p < 0.05). Failure modes were different between fixation modalities: for PTF it was suture breakage (n = 7/8), while for DCF it was implant damage and slippage (n = 8/8). Conclusion: The biomechanical fixation strength of the UHMWPE implant was greater for DCF than that of PTF, and should be suitable for calcaneal tendon repair in dogs. The clinical prediction of rupture of this calcaneal tendon repair will occur at the level of the PTF.

[1]  E. Viguier,et al.  Biomechanical analysis of an original repair of an achilles tendon rupture in dogs: preliminary results , 2020 .

[2]  E. Viguier,et al.  Biomechanical comparison of two suturing techniques during Achilles tendinoplasty in dogs: preliminary results , 2020 .

[3]  M. Fisher,et al.  Effect of partial vs complete circumferential epitendinous suture placement on the biomechanical properties and gap formation of canine cadaveric tendons. , 2020, Veterinary surgery : VS.

[4]  E. Viguier,et al.  Repair of Tendon Disruption Using a Novel Synthetic Fiber Implant in Dogs and Cats: The Surgical Procedure and Three Case Reports , 2020, Veterinary medicine international.

[5]  M. Fisher,et al.  Biomechanical evaluation of an autologous flexor digitorum lateralis graft to augment the surgical repair of gastrocnemius tendon laceration in a canine ex vivo model. , 2020, Veterinary surgery : VS.

[6]  G. Moore,et al.  Influence of Interlocking Horizontal Mattress Epitendinous Suture Placement on Tendinous Biomechanical Properties in a Canine Common Calcaneal Laceration Model , 2020, Veterinary and Comparative Orthopaedics and Traumatology.

[7]  M. Fisher,et al.  Effect of bite depth of an epitendinous suture on the biomechanical strength of repaired canine flexor tendons. , 2019, American journal of veterinary research.

[8]  Oded Ben-Amotz,et al.  The use of bidirectional barbed suture in the treatment of a complete common calcanean tendon rupture in a dog: Long‐term clinical and ultrasonographic evaluation , 2019, Clinical case reports.

[9]  C. Carozzo,et al.  Effect of the number of interference screws for the fixation of an intra-articular cranial cruciate ligament prosthesis in dogs: Biomechanical study , 2019, Computer Methods in Biomechanics and Biomedical Engineering.

[10]  P. Chabrand,et al.  Biomechanical analysis of a ligament fixation system for CCL reconstruction in a canine cadaver model , 2019, Computer Methods in Biomechanics and Biomedical Engineering.

[11]  A. Aoki,et al.  Effect of the positional relationship between the interference screw and the tendon graft in the bone tunnel in ligament reconstruction , 2019, Journal of orthopaedic surgery.

[12]  K. Kraus,et al.  Application of tendon plating to manage failed calcaneal tendon repairs in a dog. , 2018, Veterinary surgery : VS.

[13]  M. Katayama Augmented Repair of an Achilles Tendon Rupture Using the Flexor Digitorum Lateralis Tendon in a Toy Poodle. , 2016, Veterinary surgery : VS.

[14]  T. McNicholas,et al.  Biomechanical evaluation of a non-locking pre-manufactured loop suture technique compared to a three-loop pulley suture in a canine calcaneus tendon avulsion model , 2016, Veterinary and Comparative Orthopaedics and Traumatology.

[15]  T. Banks,et al.  Biomechanical evaluation of double Krackow sutures versus the three-loop pulley suture in a canine gastrocnemius tendon avulsion model. , 2014, Australian veterinary journal.

[16]  S. Corr,et al.  Retrospective study of Achilles mechanism disruption in 45 dogs , 2010, Veterinary Record.

[17]  C. Puttlitz,et al.  In vitro biomechanical comparison of polypropylene mesh, modified three-loop pulley suture pattern, and a combination for repair of distal canine achilles' tendon injuries. , 2009, Veterinary surgery : VS.

[18]  W. Baltzer,et al.  Achilles tendon repair in dogs using the semitendinosus muscle: surgical technique and short-term outcome in five dogs. , 2009, Veterinary surgery : VS.

[19]  M. O'Sullivan,et al.  The effects of freezing on the tensile properties of repaired porcine flexor tendon. , 2008, The Journal of hand surgery.

[20]  Alan L. Zhang,et al.  Biomechanical Analysis of Femoral Tunnel Pull-out Angles for Anterior Cruciate Ligament Reconstruction with Bioabsorbable and Metal Interference Screws , 2007, The American journal of sports medicine.

[21]  C. Nielsen,et al.  Outcome following surgical repair of achilles tendon rupture and comparison between postoperative tibiotarsal immobilization methods in dogs , 2006, Veterinary and Comparative Orthopaedics and Traumatology.

[22]  J. Tarlton,et al.  Biomechanical and clinical evaluation of a modified 3-loop pulley suture pattern for reattachment of canine tendons to bone. , 2004, Veterinary surgery : VS.

[23]  J. Tarlton,et al.  The three-loop pulley suture versus two locking-loop sutures for the repair of canine achilles tendons. , 2004, Veterinary surgery : VS.

[24]  I. Kessler The “Grasping” Technique for Tendon Repair , 1973, The Hand.

[25]  J. Innes,et al.  Mechanical Testing of a Synthetic Canine Gastrocnemius Tendon Implant. , 2015, Veterinary surgery : VS.

[26]  J. Bleedorn,et al.  Reconstruction of chronic triceps tendon avulsion using synthetic mesh graft in a dog , 2015, Veterinary and Comparative Orthopaedics and Traumatology.

[27]  M. Morton,et al.  Repair of chronic rupture of the insertion of the gastrocnemius tendon in the dog using a polyethylene terephthalate implant , 2015, Veterinary and Comparative Orthopaedics and Traumatology.

[28]  R. Meeson,et al.  Soft-tissue injuries associated with cast application for distal limb orthopaedic conditions , 2011, Veterinary and Comparative Orthopaedics and Traumatology.

[29]  I. Jopp,et al.  Morphological and biomechanical studies on the common calcaneal tendon in dogs , 2009, Veterinary and Comparative Orthopaedics and Traumatology.

[30]  J. Gaughan,et al.  Fourteen-year prospective results of a high-density polyethylene prosthetic anterior cruciate ligament reconstruction. , 2007, Journal of long-term effects of medical implants.