Free temporal fascial flap for coverage and extensor tendon reconstruction

Extensor tendon repairing with a rolled deep temporal fascial graft and a free temporoparietal fascial flap as a gliding bed: A case report

Reconstruction of combined skin and tendon loss in an injury of the dorsum of the hand is a challenging problem because it is required to achieve adequate excursion of the tendon. We herein report our case of extensor tendon repair for a dorsal hand injury using a rolled deep temporal fascial (DTF) graft and a free temporoparietal fascial flap. The patient regained satisfactory hand function with minimal donor site morbidity. DTF utilization as tendon grafts spares another incision for tendon grafting. Furthermore, one can integrate all the donor sites into the temporal region by choosing the scalp as a donor site for skin grafting. Patients can benefit from this procedure, which provides a functional reconstruction of the hand and leaves only inconspicuous donor site scars.

Gliding Tissue Reconstruction Using a Dorsal Digital Adipofascial Flap in Complex Extensor Injury

BACKGROUND

Postoperative scar adhesions between tendons and phalanx bones cause persistent disability in complex injuries involving tendons and bones of the hand. Although gliding tissue reconstruction is effective in preventing peritendinous adhesion formation and a dorsal digital adipofascial flap is a reliable method to prevent scar adhesion between tendon and bone after extensor tendon repair, no comparative clinical reports exist. This study aimed to determine the usefulness of a gliding tissue reconstruction method by comparing postoperative range of motion between patients who underwent gliding tissue reconstruction and those who did not.

METHODS

Medical records of patients with complex extensor tendon injury who underwent extensor repair between April 2005 and March 2018 were retrospectively analyzed. Ten patients underwent extensor repair with gliding tissue reconstruction using a dorsal digital adipofascial flap and 13 underwent only extensor repair. A triangular flap was separated after zig-zag incision to expose the injured extensor tendon into dermal and adipofascial flaps. The adipofascial flap, based on a dorsal branch of the digital artery, was placed on the injured bone as the tendon gliding surface. The same extensor tendon suture method and rehabilitation protocol were used in both groups. All patients were followed up for 6 to 12 months.

RESULTS

The mean ± SD % total active movements were 84.1% ± 12.4% and 57.6% ± 13.0% in the groups with and without gliding tissue reconstruction, respectively. Significant differences were found between the 2 groups (P < 0.05).

CONCLUSIONS

Patients with gliding tissue reconstruction had better functional recovery. This reconstruction is recommended to restore the extensor function in cases of complex extensor injury involving finger tendons and bones.

Free perivascular tissue flap transfer

Local flaps and composite grafting are the procedures of choice for reconstructing relatively small soft tissue defects. However, despite their limited conveyable volume, local flaps sometimes require a wide dissection area and long new incisions. Composite grafts also have serious limitations and require a well-vascularized recipient bed. To overcome these limitations, we used a free vascularized perivascular tissue flap based on the descending branch of the lateral femoral circumflex artery. Using this method, we performed reconstructions for seven patients (four cases in head and neck region and three cases in lower limb) with various soft tissue defects (ranged from 4.0 cm(3) to 40.0 cm(3)). This flap was easily elevated, without the need for precise preoperative flap design, and the flap volume was adjustable regardless of whether deep fascia and muscle were included. The flap has a rich vascular supply, which allows bone and cartilage tissue to be combined with the transfer of soft tissue, and satisfactorily treats chronic wounds with poor blood supply.

Mutilating hand injuries: principles and management

The objectives of the treatment of mutilating hand injuries are to insure patient's survival, limb survival and ultimately limb function. Initially, patients are stabilized and cleared of other potentially life threatening trauma. The cornerstone to the early intra-operative management of the mangled hand includes irrigation and debribement. Skeletal stabilization, revascularization, replantation or the use of spare parts to restore functions are addressed at the initial surgery. Subsequent second or third look surgeries may be required to procure a clean wound bed. Regional flaps and free tissue transfer provides definitive coverage than soft tissue is required. Secondary procedures such as tenolysis, joint mobilization or toe transfers may be needed to restore dexterity to the healed yet dysfunctional hand. Adherence to sound safe principles help prevent further mobidity while fostering the restoration of hand function to return the patient to gainful activities.

Functional gliding spaces of the dorsal side of the human hand

The clinical and functional importance of gliding spaces of the hand (e.g., their role in the spread of infection or as a consideration in reconstructive surgery) has been repeatedly emphasized. However, only a few studies have provided details regarding the connective tissue spaces in the metacarpal region of the dorsal side of the human hand. The aim of the present study was to analyze the morphology and elucidate the anatomic relation of functional gliding spaces in the metacarpal region on the dorsal side of the human hand in order to provide a better understanding of function, and of clinical disorders and their treatment. To delineate these spaces we used a plastic (Acrifix 90) injection method. Twenty fixed and unfixed cadaver hands were subcutaneously injected with Acrifix 90 (a methacrylate) into the metacarpophalangeal transitional region and into the tendon sheaths of the extensor muscles. Different colors were used to distinguish one injected plastic solution from another. The spreading pattern of the injected medium was analyzed by careful dissection. To delineate the exact bordering structures and the topography of the injected spaces, two hands were plastinated using the E12/E6 technique (von Hagens et al., Anat Embryol 1987;175:411-421), and one hand was injected and embedded in Technovit 7100 for histological investigations. Injecting the plastic into the metacarpophalangeal transitional region of fingers II-IV in a disto-proximal direction, the solution spreads along the surface of the separate extensor tendons. It then coalesces 1-2 cm proximal to the injection points to form a continuous plastic plate, which protrudes between and on top of the previous injected tendon sheaths. In no case was a communication between the paratendinous tissue and the tendon sheaths observed. Laterally, the injected solution is delimited at the radial side of the extensor tendon of the second finger and at the ulnar side of the extensor tendon of the fourth finger. Using the described technique at the fifth finger yields a plastic plate that extends from the injection point to the tendon sheath. However, in two specimens a connection between the plastic injected into the tendon sheath of the fifth finger, and the distal injected solution was observed.

[The temporal periosteum: anatomical study and surgical implications]

The periosteum of the temporal area is mentioned at different places in the literature: either against the osseous plane like everywhere in the human body, or between the deep and the superficial temporal fascia. The subperiosteal subtemporal approach in craniofacial surgery in children is in favour of a juxta-osseous localization of the periosteum. Ten premature still-born neonates and two adults cadavers have been dissected for this study and, permit anatomical and histological (with HES coloration) studies. With every specimen, the authors concluded that the temporal periosteum is against the outer table of the calvarium. It became thinner in adults because of direct insertions of the temporalis muscle in the calvaria. An anatomical description of the layers of the temporal area is realised and discussed with an extensive review of the literature. The authors have proposed a subperiosteal subtemporal approach in craniostenosis surgery.

The use of latissimus dorsi muscle flap in the aesthetical reconstruction of heat-press injury of the hand

We present a successful case of aesthetic reconstruction utilizing free latissimus dorsi muscle flap transfer. A large quantity of skin of the dorsum of hand and finger was lost. The dorsum of the index, long and ring fingers was severely damaged, such that extensor tendons were necrotic and all digital bones and the second metatarsal bone were exposed with partial necrosis. In addition, the proximal interphalangeal joints (PIP) were also exposed. To cover exposed bones and the tendons of dorsum of the hand, a free latissimus dorsi muscle flap was transferred, and then meshed skin covered the muscle, resulting in a mitten-like condition. After cutting the grafted muscle and skin to divide fingers, the grafted muscle was shaved to create the contour of fingers and dorsum of the hand, and then sheet grafting was performed. Six years after the operation, although the movement of fingers was restricted, an acceptable contour of the hand was obtained. The patient is satisfied with the result and does not desire any further surgery. In conclusion, the use of latissimus dorsi muscle flap is a method of choice not only to cover damaged hand but also to give contour in the aesthetic reconstruction of a hand presenting after heat-press injury.