Shaped graft for aneurysmal bone cyst of upper limb bones

Aneurysmal bone cyst (ABC) is an uncommon benign tumor-like lesion of unknown origin that may present a diagnostic and therapeutic dilemma [1]. There is controversy as to whether it is a distinct radiological and pathological entity or a pathophysiological change superimposed on a pre-existing lesion [2]. The original suggestion by Lichtenstein [3] favoring a local circulatory disturbance leading to the blow-out expansion of the bone is still popular. This suggestion is further emphasized by Mirra [4] who noted that the lesion is probably a periosteal to intraosseous arteriovenous malformation. The identification of a consistent t (16; 17) chromosomal translocation in primary cases suggests a de novo tumor [5].

Lack of understanding about its origin and growth makes treatment empirical. The most common treatment has been intralesional excision and bone grafting with a substantial rate of recurrence ranging from 10 to 44% [6‐8]. Abrasions of all surfaces using a high-speed burr and local adjuvant such as phenol, liquid nitrogen or polymethylmethacrylate (PMMA) have been tried to lower the rate of recurrence. However, the use of these adjuvants is much controversial because firm evidence that they are effective is lacking and their use entails considerable risk. Argon beam coagulation has been used as an adjuvant avoiding complications of other adjuvants [9‐11].

The commonly used filling materials such as autogenous cancellous or corticocancellous bone graft, allogenic freeze-dried cancellous and cortical bone graft, PMMA and bone substitutes usually take the shape of the lesion resulting in a deformed bone with the possible limitation of function especially in the upper limb [12‐14]. The current prospective study was conducted to evaluate the results of using bone grafts shaped to the original bone after extended curettage and argon beam coagulation of ABC in upper limb bones.

Between May 2005 and September 2011, 15 patients with ABCs of the upper limb bones were selected and treated at Orthopaedic Oncology Unit, Mansoura University Hospital, Egypt. For inclusion in the study which was approved by the institutional ethical research committee, all patients were briefed about the planned procedure and its possible complications and had to declare an informed consent to participate. Patients with acute pathological fracture through the cyst or secondary aneurysmal bone cyst were excluded from the study. Only patients with primary ABC of upper limb bones were included. There were 12 males and three females with an average age of 12 years (range 6–16 years) at time of surgery (Table 1). The diagnosis had been made on radiological and histological examination. Plain radiographs were performed for all cases to reveal the expanded multilocular lytic lesions. Computed tomography (CT) scan was done in 10 cases to evaluate the lesion for subtle cortical destruction or fracture. Additionally, magnetic resonance imaging (MRI) was performed in eight cases to identify the characteristic double density fluid levels and septations as well as the extension to the epiphysis. Tissue for histological examination was obtained by trephine biopsy. Two patients with recurrent lesions were biopsied preoperatively to confirm diagnosis. The presence of blood-filled cystic spaces separated by fibrous septa (membranes) of mononuclear stromal cells containing scattered multinucleated giant cells and less commonly reactive bone was suggestive of diagnosis.

The lesion was located in proximal humerus in eight patients, distal humerus in three, shaft humerus in two and distal radius in two. The approximate volume of the cyst was calculated using plain radiograph and more accurately CT scan by multiplying the maximum length and breadth in anteroposterior projection and the depth in lateral projection. Staging was accomplished using the criteria defined by Enneking [15]. Operative treatment consisted of a wide window, extended curettage, argon beam coagulation and graft insertion. Curved small curettes were helpful to reach small pockets and slits especially near the diaphyseal side. Care was taken while curetting the lesion close to the physis. A power burr was used to extend the margin of excision and to open the medulla in some cases but was avoided at the broached areas of physis. Argon beam coagulator (Birtcher 6000 Electrosurgical Generator + Argon Beam Coagulator, Irvine California, USA) was used like a paint brush throughout the entire inner wall and at a minimum near the physis. This produced a thin layer of eschar due to deposition of black carbonized debris (Fig. 1). Simultaneous irrigation and suction was helpful to clear debris and eschar, prevents contamination and allows for improved visualization. The sequence of curettage, argon beam coagulation and lavage was repeated three to four times before application of the graft.

After careful measuring the defect preoperatively and intra-operatively, the graft was harvested from the patient (proximal fibula = 9, shaft fibula = 2, iliac bone = 3) and from the patient’s mother (proximal fibula = 1). Proximal fibular grafts taken from the patients provided a smooth cancellous surface for the exposed areas of proximal humeral physis (Fig. 2). The proximal fibular graft harvested from the mother of a 6-year-old girl (case 1) was cleaned from soft tissue, washed thoroughly with saline and reshaped before placement in the defect caused by ABC of the distal third radius. In this case, the proximal smooth cancellous surface was applied against the growth plate and the distal cortical part was internally fixed to the radius with plate and screws (Fig. 3). The fibular shaft graft was inserted retrograde into the proximal humerus then impacted back into the distal part in cases with diaphyseal lesion (Fig. 4). One of the two patients with diaphyseal ABCs developed intraoperative humeral shaft fracture during graft insertion and required internal fixation with plate and screws. A composite of synthetic bone substitute (ceraform; calcium phosphate hydroxyapatite 65% and tricalcium phosphate 35%, Teknimed S.A. France) and bone marrow aspirate was used to fill the remaining gaps around the graft. The distal humeral lesions were eccentric involving medial condyle in two patients and lateral condyle in one patient. These patients were older enough to obtain autogenous bone graft from their iliac bone. The graft was shaped and placed with the thick portion of the iliac crest at the periphery representing the medial or lateral column and the thin portion centrally toward the thin area of distal humerus where olecranon and coronoid fossae meet (Fig. 5). Smooth Kirschner wires were used to stabilize the graft in two patients. The expanded outer shell was collapsed manually and gently over the graft.

Patients with humeral lesions were instructed to keep the limb in arm sling till suture removal then started early passive range of motion (ROM) of shoulder, elbow and wrist. Isometric strengthening exercises and active ROM were postponed till complete healing of the lesion. For cases with distal radial lesions, a below elbow plaster cast was applied for 5–6 weeks. All patients were allowed to start finger movement early after surgery guided by pain. The mean duration of follow-up was 45 months (range 24–68 months). Patients were evaluated radiologically by plain radiographs every 4–6 weeks for progression of healing, local recurrence and deformity resulting from partial fusion of the epiphysis. After radiographic healing, patients were assessed clinically every 3 months for the first year and every 6 months during the 2nd year then yearly thereafter. Clinical assessment was done for pain, deformity, limitation of joint movement and complications at the donor site. The modified Enneking scoring system [16] was used for functional evaluation at the time of final follow-up.

The main presenting symptoms were pain and discomfort associated with swelling in 11 patients. The remaining four patients had repeated pathological fractures of a stage 3 proximal humeral lesions. One of them had significant varus deformity with limitation of abduction and was corrected at the time of surgery. There were eight lesions stage 2 and seven stage 3 with a mean size of 78 cm³ (range 30–240 cm³).

All lesions healed uneventfully after a mean time of 17 weeks (range 12–22 weeks). Only one patient (case 5) developed partial recurrence at 6 months that required reoperation. The collapsed outer shell disappeared with the progress of healing. The rapid healing of the lesion was closely related to the young age of patients, the small size and the less aggressive (stage 2) lesions. Most of patients (83.3%) with open physis and juxta-physeal lesions had continued growth in length and width as evidenced by absence of deformity or shortening and maintained open physis. The patient who received fibular graft from her mother showed complete incorporation and remodeling of the graft with continued growth of the radius and no deformity. Only two patients (16.7%) developed shortening of the humeral segment (1 and 1.5 cm) due to premature fusion of the proximal humeral epiphysis but without angular deformity. These two patients had large size lesions (mean 195 cm³) of the proximal humerus with marked broaching of the physis.

There were no cases of deep infection, nerve deficit or pathological fracture. Superficial infection of the operative wound was seen in one patient and was controlled with repeated dressing and systemic antibiotics. The mean functional score (rating percentage of normal) at treatment completion was 97.3% (range 87–100%). There were no complications related to the donor site. Subperiosteal harvesting of the fibular graft allowed regeneration of a new fibula. Postoperative pain, abductor dysfunction and limping after harvesting iliac bone graft could be avoided by proper soft tissue repair.

ABC is one of the aggressive benign bone tumors. Despite being described for more than 60 years back, still there is controversy about its nature, pathophysiology and optimal treatment. Appropriate treatment can be made only after the exclusion of an underlying lesion particularly giant cell tumor [17]. The use of physical adjuvants such as phenol, liquid nitrogen and polymethylmethacrylate (PMMA) has been advocated to extend the surgical margin. These adjuvants produce chemical or thermal necrosis and microvascular damage to the walls of the physically excised cyst aiming to decrease the chance of recurrence. However, phenol and liquid nitrogen could penetrate tissues making the neurovascular structures at high risk. Also, liquid nitrogen can make the bone more brittle and increase the risk of fracture [6].

Lower recurrence rates can also be achieved by marginal or wide resection, but this entails loss of the supporting function of bone and the need for reconstructive surgery [18, 19]. Furthermore, others do not believe it is necessary to perform wide excision to eradicate the disease [20, 21]. In the current study, the cyst walls were not excised, instead allowed to collapse over the implanted graft to provide the new periosteum for growth in width. Local recurrence was seen only in one patient (7%) and was partial at the periphery of a large stage 3 proximal humeral lesion. In agreement with Gitelis and McDonald [22], local recurrence depends mainly on the adequacy of the tumor removal rather than the type of adjuvant used. This is achieved by making a large window to expose the whole cavity, using different sizes curettes, good visualization of the inner walls with the help of a small light source fixed to the suction nozzle and the use of power burr. The use of a high-speed burr has been suggested to reduce the rate of recurrence [23]. However, Lin et al. [21] detected no difference in recurrence rate with or without the use of high-speed burr. On the other hand, high-speed burr could not be used at the open physis, as this could destroy the growing cells and cause cessation of growth. It is believed that meticulous curettage with small curettes is preferred for the physeal borders.

Argon beam coagulator is a monopolar coagulator which utilizes a beam of argon gas to deliver a radiofrequency electric current to the tissues. The jet of gas blows blood and debris away and allows the inner surface of the cavity to be covered with a thin layer of eschar causing coagulation of blood in the lumen of small vessels and capillaries. The electrical current flows through the gas in arcs that are distributed uniformly across the tissue in depth and area, with tissue effects depending on the power setting and duration of application. The temperature of the tissue reaches a maximum of 205 °C when the spray passes over the tissues. The residual tumor cells in the cavity are destroyed by this thermal effect. Compared with other adjuvant treatments, the limited beam length and area and the directional nature of the beam make this technique simple to use, precise and safe if the nearby neurovascular bundles are protected [10]. Cummings et al. [9] in a preliminary study found that argon beam coagulation after curettage provided improved local control of ABCs compared with curettage without adjuvant or with phenol and not associated with an increase in the operative complications. In the current study, argon beam coagulation was used as an adjuvant in all cases and there were no difficulties with its use or postoperative complications related to it.

It is noted that the final shape of the new bone will correspond to the one developed by the cyst at the time of surgery. Stuffing the expanded lesion with the commonly used filling materials such as autogenous cancellous or corticocancellous bone grafts, allogenic cancellous or cortical bone graft or bone substitutes including PMMA usually result in a bulky and deformed bone with possible premature fusion of the nearby epiphysis and shortening [24]. In the present cases, bone graft was intra-operatively shaped with the smooth cancellous surface placed opposite the exposed area of the physis allowing a regular enchondral ossification. This was evidenced by the maintained open physis, continued growth in length and absence of deformity. Furthermore, the expanded outer cortex was collapsed gently providing the graft its new periosteum for increase in width.

Autogenous bone graft remains the gold standard as a filler for cavity defects. It demonstrates a high degree of osteoinduction from surface osteoblasts in the host bone, circulating osteoprogenitor cells and donor cells that survive transplantation. In addition fresh transplanted autogenous bone exhibits no immune response and undergoes rapid revascularization. However, autogenous bone graft is sometimes not available in sufficient quantity and its harvest has the potential complications of pain, blood loss, increased operative time, infection and donor site instability [25]. No perioperative or postoperative complications were encountered with harvesting bone graft in the current study. The morbidity could be avoided or minimized if the graft harvesting technique is properly planned and performed. In our study, one young girl received fibular strut graft from her mother and showed complete healing without any evidence of immunological reaction or rejection. The graft was transplanted fresh without processing other than removal of soft tissues and washing with saline. In agreement with Weber et al. [26], syngenesioplastic graft obtained from immediate relatives of the patient could be a reasonable alternative to autogenous bone graft for small children. The main weakness of this study was the limited sample size. Despite this recurrence rate, complications and functional results at the final follow-up were comparable to that of other studies using different methods of treatment and adjuvants (Table 2).

ABC remains an enigma not only regarding origin but also diagnosis and optimal treatment. The use of a shaped strut bone graft after meticulous curettage and argon beam coagulation is a reliable technique to obtain a well reconstructed and growing bone with minimal or no deformity and good function for ABCs of the upper limb bones. It is not necessary to perform wide excision to eradicate the disease. Great care should be exercised while removing the tumor near the physeal cartilage to avoid injury to the growing cells and premature epiphyseal fusion. Considering the limited quantity and the morbidities of harvesting autogenous bone graft, the author is looking forward for a shaped bone substitute that can be mixed with bone marrow as a source of osteogenic cells to aid in healing of such lesions.