Restoration of active fingers flexion with tensor fascia lata transfer in total brachial plexus palsy

Adult traumatic brachial plexus injuries: advances and current updates

Nerve grafting, tendon transfer and joint fusion are routinely used to improve the upper limb function in patients with brachial plexus palsies. Newer techniques have been developed that provide additional options for reconstruction. Nerve transfer is a tool for restoring upper limb function in total root avulsions where nerve grafting is not possible. In partial brachial plexus injuries, nerve transfers can greatly improve shoulder, elbow, wrist and hand function. Intraoperative electrical stimulation can be used to diagnose precisely which nerve is injured and to choose which nerve fascicles should be transferred. Finally, measuring the postoperative outcome can improve the evaluation of our techniques. The aim of this article was to present the current techniques used to treat patients with brachial plexus injury.

Biceps Transfer to FDP-FPL Tendon Augmented with Fascia Lata to Restore Hand Function in Neglected Fracture Treated by Traditional Bone-setters

Neglected bone fractures owing to the traditional bone-setter practices could lead to devastating complications. We aimed to describe the procedure and outcome of fascia lata augmentation for a forearm massive soft tissue loss case. Here, we report a case of a 14-year-old boy who presented to our hospital with a history of neglected right forearm fracture 4 years prior. He had been treated by a traditional bone-setter instead of seeking professional medical help, which resulted in wide-spread infection requiring debridement and, eventually, massive soft tissue loss, wrist radial deviation deformity due to epiphyseal growth arrest, and loss of all right-hand function. Intervention performed was biceps transfer to flexor digitorum profundus (FDP) and flexor pollicis longus (FPL) tendon augmented with fascia lata with anterior capsulectomy, bilobed flap, and transfixing wire of wrist joint, followed by ulnar centralization with wrist arthrodesis. The patient reported satisfaction postreconstruction, owing to the enhancement of hand function and appearance. He also showed significant improvement in activities of daily living and penmanship, and was even able to continue his old hobby as a traditional puppeteer. Autologous fascia lata tendon transfer connecting biceps to FDP and FPL tendon alongside ulnar centralization with wrist arthrodesis is a novel technique that has promising results to improve hand function and appearance.

Tendon transfers for C8-T1 palsy of the brachial plexus in adults

Brachial plexus palsy after C8-T1 nerve root injury is rare, but causes a loss of finger flexion and extension, which greatly limits the patient's grip function. It can benefit from nerve transfers if the diagnosis is made early. Otherwise, tendon transfers may be proposed. Transfers of the extensor carpi radialis longus and brachioradialis to the flexor digitorum profundus and the flexor pollicis longus, respectively, restores finger flexion and thumb flexion. Tenodesis of the extensor digitorum communis allows passive extension of the fingers during active wrist flexion. Translocation of the flexor pollicis longus and the creation of a "lasso equivalent" on the flexor digitorum superficialis provides some recovery of the intrinsic function of the fingers and thumb. Finally, a nerve transfer of the lateral cutaneous nerve of forearm on the superficial branch of the ulnar nerve can improve sensitivity on the ulnar edge of the hand to limit the risk of cutaneous lesions, which frequently occur in this type of paralysis.

Transfer of the triceps brachii to the finger and thumb extensors: Anatomical study and report on one case

Our aims were to study the anatomical feasibility of triceps brachii long head (TBLH) transfer to the extensor digitorum communis (EDC) and extensor pollicis longus (EPL) tendons through a medial route, and to report on its first clinical application. Dissections were conducted on 10 fresh-frozen cadaver specimens. Using a posteromedial approach, the TBLH was separated from the remaining triceps and extended distally with a fascia lata strip. This strip was then tunneled through a medial route and secured distally to the EDC and EPL tendons. The transfer tenodesis effect during elbow extension was assessed with metacarpophalangeal (MCP) joint motion of the thumb and index finger, and the distance between the thumb and index finger tips (TI distance). This transfer was performed in an eight-year-old boy with incomplete recovery of a right brachial plexus birth palsy; preoperatively, shoulder and elbow functions were recovered as well as active gripping distally, but he had no active wrist or finger extension. With the trapeziometacarpal and radiocarpal joints stabilized, 90° elbow extension provided a mean extension of the thumb and index finger MCP joints of 34 ± 5° and 90 ± 11°, respectively, with a mean TI distance of 116 ± 16 mm. Twelve months after surgery, the boy had full active MCP joint extension, independent from elbow extension. Transferring the TBLH to the EDC and EPL tendons is anatomically feasible. Larger clinical studies will be needed to assess more adequately its functional outcomes.

Distal Biceps Brachii Tendon Transfer for Re-establishing Extrinsic Finger Function: Feasibility Study in Cadavers

PURPOSE

To determine the anatomic feasibility of transferring the biceps brachii tendon into either the extensor digitorum communis (EDC) or flexor digitorum profundus (FDP), determine the excursion imparted to EDC and FDP tendons after transfer, and compare the work capacity of the cadaver biceps to previously published data on the biceps as well as the recipient muscles by calculating the physiologic cross-sectional area (PCSA).

METHODS

Four fresh-frozen cadaver shoulder-elbow-wrist specimens were used to measure tendon excursion that can be obtained with transfer of the distal biceps tendon into either the EDC or FDP. Two cadavers had distal biceps-to-EDC transfer performed, and the other 2 had distal biceps-to-FDP performed. Passive ranging of each elbow from flexion to extension and active loading at 90° of elbow flexion were then performed on each specimen to determine tendon excursion. An analysis of the PCSA of the biceps muscle was performed on each specimen.

RESULTS

Distal biceps-to-EDC transfer resulted in an average of 24 mm of tendon excursion with passive loading, and 24 mm of tendon excursion with active loading. Distal biceps-to-FDP transfer resulted in an average of 24 mm of tendon excursion with passive loading, and 24 mm of tendon excursion with active loading. The average PCSA was 3.6 cm².

CONCLUSIONS

Transfer of the distal biceps tendon into the EDC or FDP is anatomically feasible and provides roughly 24 mm of tendon excursion to the tendon units. The PCSA in the specimens used is slightly lower than other published data; it closely approximates the PCSA of the EDC, but is only half of the PCSA of the FDP in previously published data.

CLINICAL RELEVANCE

The findings suggest potentially novel transfer options for restoring finger flexion and extension in patients lacking FDP or EDC function.

Tendon grafts: their natural history, biology and future development

The use of tendon grafts has diminished as regimes of primary repairs and rehabilitation have improved, but they remain important in secondary reconstruction. Relatively little is known about the cellular biology of grafts, and the general perception is that they have little biological activity. The reality is that there is a wealth of cellular and molecular changes occurring with the process of engraftment that affect the quality of the repair. This review highlights the historical perspectives and modern concepts of graft take, reviews the different attachment techniques and revisits the biology of pseudosheath formation. In addition, we discuss some of the future directions in tendon reconstruction by grafting, which include surface modification, vascularized tendon transfer, allografts, biomaterials and cell-based therapies.

Transfer of the recovered biceps to the long flexors of the digits to restore grip function following complete traumatic brachial plexus palsy

Restoration of grip function was achieved through transfer of the recovered biceps tendon to the long digital flexors using a fascia lata graft in seven patients with complete brachial plexus palsy. Initial nerve repair was followed by biceps transfer with stabilising wrist and hand fusions. The biceps recovered to Medical Research Council (MRC) grade 4 in all cases. Patients were reviewed at a mean time of 26.7 (range 7-63) months after biceps transfer. After transfer, the total active movement of the digits averaged 55 (range 30-90)8. The strongest measurable grip strength was 6 kg. Patient satisfaction was high. The excellent excursion of the elbow provides a good basis for a transfer to power grip function, enabling a greater total active movement of the fingers to be achieved. We recommend this method as a useful adjunct to the treatment of the complete brachial plexus palsy.