1. Introduction

Distal radius fractures are one of the commonest fractures seen worldwide with a steadily rising incidence [1]. They are commonly termed “wrist fractures” which are described as fractures occurring within 3 cm of the radiocarpal joint [2]. These injuries can be intra-articular or extra-articular that are associated with a bimodal age distribution [3]. In women over the age of 40 years the incidence of these injuries has been found to increase rapidly when compared to men within the same age category [4]. There are numerous treatment options available for their management with the most recent advancement being the use of volar locking plates. Recently; the design of the plates used for fixation of these injuries has evolved to accommodate for their use in a variety of different fracture patterns. However, despite these advancements there is a 15% risk of tendon rupture and tenosynovitis after volar plating procedures. This discussion will review the risk factors and management of flexor pollicis longus (FPL) tendon rupture secondary to volar plate fixation of distal radius fractures.

2. Case

Mrs. G.M. a 70-year-old female suffered a right intra-articular distal radius fracture with volar displacement secondary to a fall on her outstretched hand. Open reduction and internal fixation with a 3.5 mm volar locking plate was performed seven (7) days post-injury. The procedure was performed through a modified Henry's approach to the distal radius with the pronator quadratus repaired over the plate during closure. She was reviewed routinely in the outpatient clinic and at one year she was discharged. Her function had returned to normal at this point and there was both clinical and radiographic evidence of fracture union without collapse of the distal fragment (Figure 1).

The patient presented twenty-six (26) months after the initial procedure complaining of an inability to flex her thumb which occurred after reaching for an object one month prior. On examination, she was unable to flex her right thumb at the interphalangeal joint but her wrist was pain-free with a normal range of motion with a well-healed surgical scar. The patient subsequently underwent surgical exploration to address her FPL tendon rupture. A modified Henry’s approach which was extended distally to the carpal tunnel was utilized. On exploration, the distal edge of the plate was found to be uncovered despite the pronator quadratus having been repaired over the plate. (Figure 2) The FPL tendon was ruptured over the distal end of the plate as well as the frayed tendon edges were localised and debrided. The ipsilateral palmaris longus tendon was harvested and used as a graft.

The patient’s tendon was repaired using the tendon graft with a pulvertaft weave for both proximal and distal anastomoses. (Figure 3) She was immobilized in a thumb spica for four weeks after which range of motion exercises were started.

3. Discussion

The utilization of the volar plating technique for the management of distal radius fractures is preferred over dorsal plating by most surgeons in an attempt to minimize the high risk of tendon rupture that is seen with dorsal plating [5-9]. Literature reviews have revealed few studies reporting tendon rupture after the use of volar plates for the fixation of distal radius fractures. In 2013 a systematic review was undertaken and found only forty-seven (47) reported cases of ruptured tendons after volar distal radius plating with FPL tendon rupture being the most common tendon rupture followed by flexor digitorum profundus to the index finger [10]. The true prevalence of flexor tendon ruptures associated with volar plating of distal radius fractures remains unknown. Of the cases reported, fifty percent occurred at 6-26 months after the index operation in the literature [10].One-third of the reported cases were seen in patients between 60-70 years with a female predominance which is in keeping with an increased incidence of distal radius fractures in the older population  as well as the presence of osteoporosis [10, 11].

 

Numerous factors have been attributed to the rupture of flexor tendons after the treatment of distal radius fractures. The commonly reported factors include the placement of the plate distal to the transverse ridge, prominent distal edge of the plate, screw head prominence, malreduction of fracture, and incorrect usage of plate, fracture collapse, tendinopathy and iatrogenic injury [12-16]. The position of the plate has been suggested to be one of the major risk factors for tendon rupture due to irritation of the tendons that overlie the distal end of the plate. The transverse ridge or “watershed line” is located distal to the pronator quadratus muscle, approximately 2 mm from the joint line on the ulnar side of the radius and 10-15 mm from the radial sided articular surface [17]. The placement of a volar plate distal to this line can result in impingement of the traversing flexor tendons which leads to their irritation and potential rupture.

In 2011, a classification system to determine the presence of plate prominence in relation to the watershed line was developed [18]. The postoperative radiographs for the above patient revealed that the distal edge of the plate was distal to the “watershed line” and would be classified as a Soong grade 2. It was found that patients with a Soong grade 2 volar prominence had an increased incidence of flexor tendon ruptures [18, 19]. The volar prominence of this patient’s plate may have attributed to the eventual rupture of her FPL tendon after repetitive irritation caused by the gliding of the tendon over the distal edge of the plate. One recommendation to decrease the risk of tendon attrition by a prominent distal plate end is to repair the pronator quadratus muscle over the plate [16, 20, 21]. The pronator quadratus is found in the deepest muscle layer of the anterior compartment of the forearm and serves to protect the flexor tendons from prominent hardware. In the case described the muscle layer although repaired was still deficient over the distal edge of the plate thus leaving this critical point exposed to the overlying tendons. One study of volar plating for dorsally comminuted distal radius fractures observed that the size of the pronator quadratus varies in individuals especially in middle-aged women who were noted to have the thinnest muscle layer [22, 23]. FPL tendon ruptures although uncommon sequelae of volar plate fixation of these injuries still exists despite recent advancements in the design of these plates A meticulous surgical technique and appropriate plate selection are necessary to aid in the prevention of this complication. Various techniques of repair have been described for these injuries ranging from primary repair, tendon grafting, and tendon transfers. Patients who present with a FPL rupture as a result of friction against the plate have been found to have tenosynovium hypertrophy and a tendon defect with fibrotic tissue as well as tendon retraction. These patients are more likely to benefit from tendon grafting or transfer as performed in the case described above.

4. Conclusion

A variety of tendon graft donor options are available but the commonest tendon graft used is the ipsilateral palmaris longus tendon [24]. There are numerous tendon suturing techniques which can be employed for anastomosis of the tendon graft. However, the pulvertaft weave has been the most commonly used technique for the proximal suture anastomosis of flexor tendon grafts [25, 26]. This technique was employed in the case presented for both the proximal and distal anastomosis. Based on the outcome of this case the pulvertaft weave as a proximal and distal anastomosis suture is a good option once there is sufficient graft length to permit its use on both ends.

Conflict of Interest

The Authors declare that there is no conflict of interest and no funding was received.

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