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The objective of this case report is to emphasize the importance of the identification of all the causative factors responsible for the creation of the congenital clasped thumb, as their detection will perform a critical part in the choice of the proper surgical treatment. This study presents the case of a four-year-old boy with a congenital clasped thumb of the right hand. A short Flexor Pollicis Longus (FPL), an absent Abductor Pollicis Longus (APL), a hypoplastic Extensor Pollicis Brevis (EPB), and palmar displacement of the Extensor Pollicis Longus (EPL) were detected. The surgical treatment included Z-lengthening of the short FPL and augmentation of the insufficient EPL and EPB by tendons transfer. Postoperatively, the thumb was halted in a place of full radial abduction and $20^{\circ }$ of palmar flexion with scotchcast plaster for four weeks. In his last follow-up three years after surgery, he was able to do full abduction and extension of the thumb. He was able to open a door or grasp and hold various objects. He was fully satisfied with the result of the operation. Treatment should be adjusted to address all causative issues of clasped thumb effectively, reduce deforming forces, and increase the activity of insufficient muscles.

Radial deviation and limited flexion of the wrist joint and a lack of abduction of the thumb have been noticed after the Riordan's procedure. Therefore, Tsuge et al. modified the Riordan's procedure, and their procedure includes transfer of the pronator teres to the extensor carpi radialis brevis, the flexor carpi radialis (FCR) to the extensor digitorum communis (EDC), and the palmaris longus to the extensor pollicis longus, along with tenodesis of the abductor pollicis longus. We reviewed the charts of 21 patients with isolated radial nerve paralysis who were treated with the Tsuge's procedure. Mean follow-up period was 11.3 years. Postoperatively, patients showed good extension of the metacarpophalangeal joint measured at the middle finger, useful flexion of the wrist joint, and decreased radial deviation of the wrist. The FCR transfer to the EDC is an excellent procedure for extension of the fingers. However, reconstruction of active abduction of the thumb remains controversial.

Congenital hypoplasia of the extensor tendons, which is defined as a congenital anomaly of the hand involving the extensor mechanism, is a rare condition and there are few previous reports in literature. We reported a case of bilateral congenital hypoplasia of the extensor tendons in a 12-year-old boy who presented with inability to extend his middle and ring fingers treated by the flexor carpi radialis tendon transfers.

Osteochondroma rarely develops from the carpal bones. We report a first case in which a dorsal osteochondroma of the lunate caused attritional rupture of the tendon of the extensor indicis proprius and a tendon of the extensor digitorum communis of index finger.

Opponoplasty using tendon transfer is a useful reconstructive procedure that restores lost thenar muscle function. Tendon transfers, however, require postoperative immobilization periods of up to four weeks before the sutured tendons reach required strength. We developed an opponoplasty procedure using α-TCP (alpha-tricalcium phosphate) cement that does not require postoperative immobilization and was applied to nine hands out of nine cases. The procedure is performed under local anesthesia without a pneumatic tourniquet and on an outpatient basis.

In this procedure, the flexor digitorum superficialis of the ring finger is used as the donor tendon and the palmaris longus tendon is used as a dynamic pulley. The distal end of the transferred tendon is anchored to the inside of a newly formed bone hole in the thumb's proximal phalanx using α-TCP cement.

Our opponoplasty procedure was uneventful postoperatively and produced satisfactory results in all nine cases. The α-TCP cement procedure shows potential for other tendon transfer applications.

A 73-year-old female suffered spontaneous rupture of the extensor pollicis longus (EPL) and extensor pollicis brevis (EPB) tendons, for which she presented for treatment three to four weeks later. At that time there was no active metacarpophalangeal (MCP) or interphalangeal (IP) extension, leading to severe functional impairment of her hand. Since both the EPL and the EPB tendons were ruptured, transfer of the extensor indicis proprius (EIP) tendon was carried out for the EPL and transfer of the accessory abductor pollicis longus (AAPL) was carried out for the EPB. After a three-month period of follow-up, the thumb motion was restored and the patient was able to resume all activities of daily living. Although concomitant spontaneous rupture of both the EPL and the EPB is rare, transfer of the EIP and the AAPL tendons, respectively, seems to be the treatment of choice for anatomic reconstruction of such injuries.

In anterior interosseus nerve syndrome, reconstruction of the paralyzed flexor pollicis longus is occasionally required. Traditionally, the brachioradialis has been used as a motor, but we utilised the palmaris longus, which is expendable. The palmaris longus tendon was transferred in an end-to-side manner, leaving the flexor pollicis longus in situ. The procedure was performed in three patients. All patients regained a full range of thumb interphalangeal joint motion and an average 90% of the pinch strength. The only complication noted was thenar pain due to the adhesion of the palmar branch of the median nerve with the transferred tendon in one patient. This can be avoided if the interlacing suture was placed more proximally. Palmaris longus transfer is a simple technique that gives a satisfactory result.

We report a case of extensor tendon dislocation at the metacarpophalangeal joint of the middle finger in which it appeared that an ulnar translation force created by an end-to-side transfer contributed to the dislocation. We recommend alterations in technique or alternative method of extensor tendon reconstruction to avoid this complication if unfavorable factors for end-to-side transfer exist.

Background: Subcutaneous spontaneous ruptures of the finger extensor tendons at the wrist frequently occur. This study aims to evaluate the outcomes of patients with extensor tendon ruptures treated by our operative methods and postoperative early active mobilization.

Methods: A total of 38 patients with 68 extensor tendon ruptures were included in this study. In the reconstruction of extensor tendon ruptures, tendon transfers (extensor indicis proprius (EIP) tendon transfer and/or interlacing end-to-side suture) and/or free tendon bridge graftings were performed. Immediately after operation in all patients, early active mobilization began by wearing a specially designed bandage or splint.

Results: There was no reoccurrence of re-rupture of a tendon post surgery. A patient satisfaction survey revealed that 29 patients rated their results as “excellent” and 9 were “good.” Postoperatively, the active range of motion of the finger metacarpophalangeal (MP) joint averaged +3^∘(range:- 14$\sim$+20^∘) in extension and 69^∘(range: 60–80^∘) in flexion.

Conclusions: We treated finger extensor tendon ruptures by tendon transfer (EIP tendon transfer to the ruptured extensor tendon and/or interlacing end-to-side suture) and/or bridge tendon grafting. We employed early active mobilization with patients wearing a specially designed bandage or splint immediately after reconstructing surgery. There was no case with re-rupture postoperatively. Our operative techniques and postoperative physiotherapy as early active mobilization in this study led to excellent results after finger extensor tendon ruptures.

Tendon transfer with extensor indicis proprius (EIP) has been performed widely for reconstructing ruptures of the extensor pollicis longus because of its simplicity and clinical outcome. We experienced a rerupture of the extensor pollicis longus restored by incorrect tendon transfer because of a major unrecognized variation in the anatomy of the EIP. Surgeons should perform such transfer with a detailed knowledge of the possible anatomical variations to avoid such serious complications.

Background: Patients with some thumb polydactyly subtypes are regarded as having a high risk of secondary deformities or poor treatment outcomes. Radially deviated type is one of these subtypes, but its characteristics and definitive treatment outcomes remain unclear. This study aimed to evaluate the pre- and intraoperative findings and surgical outcomes of this subtype.

Methods: We identified eight patients with unilateral and proximal phalanx-type polydactyly. The mean age at surgery was 14.6 months, and the mean follow-up period was 7.2 years. We investigated the patients’ initial radiograms, surgical procedures and findings, changes in alignment of the retained thumb, and postoperative outcomes using the Japanese Society for Surgery of the Hand scoring system.

Results: Although the gross appearance of the thumb was a radial deviation, there was an ulnar deviation at the metacarpophalangeal joint on radiography. The ulnar proximal phalanges were delta phalanges in three patients and were connected with the radial proximal phalanges by cartilage in five patients. We retained the ulnar thumbs in all patients and corrected the alignment in seven cases; open wedge osteotomy was performed for three patients with a delta phalanx, and tendon transfers from the radial to ulnar thumb were performed for the other four. The mean outcome score was 17.6/20, with one patient with excellent, six with good, one with fair, and none with poor scores. One patient experienced recurrent radial deviation around the interphalangeal joint five years after surgery and underwent corrective osteotomy, but the other patients maintained good alignment.

Conclusions: Radially deviated thumb polydactyly is not simply radially deviated; the shape of the proximal phalanx of the ulnar thumb is important to determine the surgical procedure. However, our results indicated that the alignment is almost manageable, and the surgical outcome was comparable to that of patients with a proximal phalanx-type thumb polydactyly.

Background: Strong surgical repair is the mechanical basis of early mobilization and prerequisite for biological healing following tendon grafting. Side to side and pulvertaft repairs were developed to meets these demands. However, these techniques have later been modified to improve the strength of repair but their characteristics have not been compared.

Methods: We compared biomechanical strength of the modified side-to-side (SS) repair with the modified Pulvertaft (PT) repair technique in turkey tendons keeping overlap length, anchor points, type of suture, suture throw and amount of suture similar. Two investigators performed 34 repairs during one summer month to test the tensile strength of the repair using mechanical strength testing machine. Variables measured were maximum load, load to first failure, modulus, load at break, mode of failure, site of failure, tensile strain, tensile stress. The statistical comparison was carried by Levene’s test and T test for means.

Results: The mean maximum load for modified SS repair was 50.3 (SD 13.7) N and modified PT repair was 46.9 (SD 16.4) N. The tensile stress at maximum load for SS and modified PT repair was 4.7 (SD 4) MPa and 4.2 (SD 3) MPa respectively. The suture cut through was the commonest mode of failure.

Conclusions: We found no statistical difference between 2 repairs in load at which they started failing (p = 0.16), and maximum load repairs could withstand (p = 0.35). Our study uniquely compares two techniques under standard conditions, and contrary to existing evidence found no difference. However, in our opinion the number of anchor points may have a greater impact than number of weaves on the strength.

Management of malignant peripheral nerve sheath tumours (MPNSTs) is primarily surgical, involving surgical resection with wide margins, and frequently radiation therapy. When a MPNST involves a major peripheral nerve, wide resection leads to significant distal neurologic deficits. A patient who underwent resection of a MPNST involving the median nerve above the elbow is presented. Staged tendon and nerve transfers were performed to restore sensation to the thumb and index finger, thumb opposition and flexion, finger flexion and forearm pronation. These included: 1. radial sensory nerve branches to digital nerves of thumb and index finger, 2. ulnar nerve branch of flexor carpi ulnaris to pronator teres, 3. brachioradialis to flexor pollicis longus, 4. side-to-side transfer of flexor digitorum profundus tendon of index finger to middle, ring and little fingers, 5. extensor indicis proprius to abductor pollicis brevis. The rationale, approach, and favourable results of functional reconstruction in this patient are detailed.

Background: The Pulvertaft weave was described more than 50 years ago and is still used in tendon transfers. The aim of this study was to evaluate the strength of a modified core suture Pulvertaft weave technique and compare it to the original Pulvertaft weave traditionally used in tendon transfer surgery.

Methods: 12 extensor pollicis longus tendons and extensor indices proprius tendons were harvested from fresh frozen cadavers. Six Pulvertaft weaves were performed using FiberWire 4.0 and six core suture tendon weave were performed using FiberLoop 4.0. Biomechanical analysis was performed and stifness, first failure load and ultimate failure load were measured for both set of repairs.

Results: The stiffness of the core suture tendon repair (9.5 N/mm) was greater than that of the Pulvertaft repair (2.5 N/mm) The first failure load of the core suture tendon repairs (68.9 N) was greater than the Pulvertaft repairs (19.2 N) and the ultimate failure load of the core suture tendon repairs (101.8 N) was greater than the Pulvertaft repairs (21.9 N). All of these differences were statistically significant.

Conclusions: The core suture Pulvertaft weave is a modification to the Pulvertaft weave used in tendon transfers. The results of this cadaveric study suggest it is 5 times stronger than the traditional Pulvertaft repair, potentially allowing it to be used with early active motion protocols after tendon transfers.

In this historical report, we celebrate 100 years of a surgical procedure for claw correction described by Harold Stiles, which still holds good and learn more about this pioneer who revolutionised the treatment for claw correction.

Background: A palmaris longus (PL) to extensor pollicis longus (EPL) is a standard tendon transfer used to restore thumb extension in patients with radial nerve palsy. This transfer is done by withdrawing the EPL from the third compartment and passing it subcutaneously to reach the PL. We modified this transfer by rerouting the EPL through the second extensor compartment to improve the retropulsion of the thumb. The aim of this study is to report the outcomes of this modified transfer.

Methods: Four patients with traumatic radial nerve palsy underwent the modified PL to EPL transfer. They also underwent transfer of the pronator teres (PT) to extensor carpi radialis brevis (ECRB) and flexor carpi radialis (FCR) to extensor digitorum communis (EDC). Patients were followed up for at least 1 year after surgery. The data with regard to age, gender, cause of radial nerve palsy, duration between injury and surgery, and duration of follow-up was recorded. At final follow-up, the arc of motion at the interphalangeal joint (IPJ), metacarpophalangeal joint (MCPJ), palmar and radial abduction and retropulsion were measured for the reconstructed thumb and contralateral normal thumb.

Results: All patients were male, with a mean age of 34.3 (range, 19–46) years. The mean duration between the injury and surgery was 15.9 (7–27) months, and the mean post-operative follow-up period was 16.8 (12–25) months. All patients recovered good thumb function. The mean arc of motion of the affected and contralateral thumb were IPJ flexion: 52°/80°; IPJ extension: 21°/14°; MCPJ flexion: 30°/33°; MCPJ extension:24°/31°; radial abduction: 70°/74°; palmar abduction: 68°/75° and retropulsion: 4.8cm/5.0cm.

Conclusion: Rerouting the PL to EPL tendon transfer through the second extensor compartment in radial nerve palsy can restore good thumb function especially retropulsion.

Level of Evidence: Level IV (Therapeutic)

Background: Isolated lower (C8T1) brachial plexus injury (BPI) is uncommon and the aim of treatment is to achieve a satisfactory grasp enabling the use of the hand for daily activities. The aim of this study is to report the outcomes of the transfer of brachioradialis (BR) to flexor pollicis longus (FPL) and biceps to the flexor digitorum profundus (FDP) for an isolated lower BPI.

Methods: This is a retrospective study of all patients with an isolated lower BPI who underwent a BR to FPL and biceps to FDP transfer for restoration of digital flexion over a 1-year period from May 2019 to June 2020. Patient demographic and injury data were collected at the presentation. Outcomes data included the ability to grasp and perform activities of daily living and DASH score.

Results: The study included three patients (all men) with an average age of 30.3 years. All sustained an isolated lower BPI following a road traffic accident and tendon transfers were performed at a mean of 9.3 months after the initial injury. At a mean of 1-year follow-up, all three recovered grade M4 motor power of digital flexion, achieved good grasp function with pulp-to-palm distance of <1 cm. All are able to use the hand for independent as well as bimanual activities. The individual DASH scores were 36, 30 and 30.

Conclusions: BR to FPL for thumb flexion and biceps to FDP using fascia lata graft to restore finger flexion is simple and effective surgeries in patients with isolated lower BPI.

Level of Evidence: Level V (Therapeutic)

Motor deficit in patients with extended upper brachial plexus palsy is variable. A patient with only thumb and finger extensors may seem to have active wrist extension because of them secondarily acting at wrist and causing wrist extension. To determine the presence of wrist extensors, it is important to block the wrist extension caused by the finger and thumb extensors. Conventional muscle testing is often ineffective in these patients as they learn a variety of trick movements over the time. We describe a simple clinical test to reveal the strength of the wrist extensors only by negating the effect of digital extensors on the wrist. If wrist extensors are absent, a nerve or tendon transfer can be done to address this deficit and improve the functional outcome.

Level of Evidence: Level V (Diagnostic)

Forearm deformities are often seen in children with severe birth brachial plexus palsy (BBPP). They may be either a supination or a pronation deformity and both hinder normal use of the hand and parents often request for corrective surgery. However, the correction of these deformities can be challenging due to a paucity of options. Also, there is less information in literature on the management of forearm deformities in BBPP compared to the information with regard to nerve surgery or correction of shoulder deformities. This article presents a synopsis of incidence, pathogenesis, clinical presentation and parental concerns related to these deformities. The decision-making considerations, management strategies and outcome expectations are also discussed. Patient selection is very crucial, and the treatment plan must be individualised depending on the disability, parental expectations and existing motor power in the involved limb. Correction of both the deformities have different considerations; however, effective correction of these deformities is immensely satisfactory to the patient/parents in terms of improved function and appearance of the limb.

Level of Evidence: Level V (Therapeutic)

Background: Primary repair for traumatic injuries to the ulnar nerve alone does not always restore satisfactory hand function, particularly in injuries above the elbow where the long distances for regeneration limit motor reinnervation. Reductions in key pinch and grip strength are some of the main complaints. Tendon transfers have traditionally been used to improve key pinch and grip strength as a late salvage where primary nerve regeneration has run its course. Nerve transfers have been proposed as an alternative procedure and may be offered early to augment recovery, lengthen the window for reinnervation or provide motor reinnervation where the results of nerve repair are expected to be poor. This review sought to identify whether one type of procedure was superior to the other for reconstructing key pinch and grip strength.

Methods: Medline, Embase and Cochrane Library were searched to identify articles that concerned nerve or tendon transfer following isolated traumatic injury to the ulnar nerve. Articles were excluded if patients had polytrauma or degenerative diseases of the peripheral nerves.

Results: A total of 179 articles were screened for inclusion. And 35 full-text articles were read and assessed for eligibility, of which seven articles were eligible. Following citation search, two additional articles were included. Five tendon transfer articles and four nerve transfer articles were included. Key pinch and grip strength outcomes for both procedures were roughly similar, though tendon transfers carried a much higher risk of complications.

Conclusions: Based on the key pinch and grip strength outcomes, tendon transfer and nerve transfer restore a similar degree of function following traumatic ulnar injury. Reported nerve transfer outcomes for grip strength were slightly better. Return to useful function was faster following tendon transfers. Preoperative data and more patient-reported outcome measures should be recorded in future studies to provide more context for each procedure type.

Level of Evidence: Level III (Therapeutic)