Autoclaved Tumor Bone for Skeletal Reconstruction in Paediatric Patients:  A Low Cost Alternative in Developing Countries

Umer, Masood; Umer, Hafiz Muhammad; Qadir, Irfan; Rashid, Haroon; Awan, Rabia; Askari, Raza; Ashraf, Shamvil

doi:https://doi.org/10.1155/2013/698461

BioMed Research International

On this page

Abstract Introduction Methods Results Discussion Conclusion References Copyright Related Articles

Clinical Study | Open Access

Volume 2013 | Article ID 698461 | https://doi.org/10.1155/2013/698461

Autoclaved Tumor Bone for Skeletal Reconstruction in Paediatric Patients: A Low Cost Alternative in Developing Countries

Masood Umer,¹Hafiz Muhammad Umer,¹Irfan Qadir,¹Haroon Rashid,¹Rabia Awan,¹Raza Askari,¹and Shamvil Ashraf¹

Academic Editor: Jeroen T. Buijs

Received20 Sept 2013

Revised13 Nov 2013

Accepted14 Nov 2013

Published18 Dec 2013

Abstract

We reviewed in this series forty patients of pediatric age who underwent resection for malignant tumors of musculoskeletal system followed by biological reconstruction. Our surgical procedure for reconstruction included (1) wide en bloc resection of the tumor; (2) curettage of tumor from the resected bone; (3) autoclaving for 8 minutes (4) bone grafting from the fibula (both vascularized and nonvascularized fibular grafts used); (5) reimplantation of the autoclaved bone into the host bone defect and fixation with plates. Functional evaluation was done using MSTS scoring system. At final followup of at least 18 months (mean 29.2 months), 31 patients had recovered without any complications. Thirty-eight patients successfully achieved a solid bony union between the graft and recipient bone. Three patients had surgical site infection. They were managed with wound debridement and flap coverage of the defect. Local recurrence and nonunion occurred in two patients each. One patient underwent disarticulation at hip due to extensive local disease and one died of metastasis. For patients with non-union, revision procedure with bone graft and compression plates was successfully used. The use of autoclaved tumor grafts provides a limb salvage option that is inexpensive and independent of external resources and is a viable option for musculoskeletal tumor management in developing countries.

1. Introduction

Skeletal reconstruction for large segmental defects following bone tumour extirpation has always been considered as a therapeutic challenge [1]. Most bone tumor patients are young and active; any given treatment must not only preserve the affected limb but also maintain function without major complications or reoperations over the long term [2]. After the resection of malignant tumors in children, a variety of reconstructive procedures have been used on a case-by-case basis, including rotationplasty [3, 4], arthrodesis, bonelengthening [5], extendable prostheses [6, 7], allografting [8], extracorporeal irradiated autografts [9, 10], vascularized or nonvascularized grafts [11], pasteurization [12], autoclaved bone [13], and amputations [14].

Prosthetic reconstruction allows rapid restoration of mobility and weightbearing. Its long-term results in pediatric patients are more controversial: infection and aseptic loosening occur commonly and require further surgery [15]. Biological reconstruction with an allograft or an autograft restores bone stock and allows better soft-tissue attachment compared with metal implants [16]. However, complications like risk of fracture (7% to 42%), nonunion (9% to 63%), and infection (5% to 30%) can be disturbingly high [17–19]. Moreover, allograft reconstruction depends on the availability of a bone bank so that the size of the allograft can be matched to that of the resected bone segment. In many Asian countries, bone allografts are often avoided for religious, social, and cultural reasons.

From a developing nation’s perspective, reimplantation of extracorporeally devitalized tumor bearing bone segments is an appealing option. It allows immediate and anatomical correct filling of the defect. It is technically and financially a simple, cost-effective, and viable solution for these difficult problems [20]. This procedure consists of wide en bloc resection of the tumour, curettage of tumour tissue from the resected bone, extracorporeal bolus single irradiation or autoclaving, followed by reimplantation into the recipient with a fixation device. Serious problems remain, however, including nonunion, infection, and fracture. Combined use of autoclaved bone and vascularised bone would seem to be the ideal graft for reconstruction because of the cumulative advantages arising from this approach.

From a pediatric perspective, all the above methods of reconstruction are associated with problems such as deformation, growth retardation, limb length discrepancy, measures to be taken to cope with high levels of physical activity in childhood, and problems related to social adaptation. In the present study, we reviewed forty pediatric patients from our institute who underwent resection for malignant musculoskeletal tumour and were then reconstructed using a combination of vascularised bone graft and autoclaved autograft. We report here the clinical outcomes including radiographic findings, functional analyses, and the complications arising, as well as a discussion of the advantages and disadvantages of this approach.

2. Patients and Methods

We retrospectively reviewed 40 consecutive pediatric patients, aged 16 years or younger, with locally aggressive or malignant bone tumors treated with tumor resection, autoclaving, and reimplantation of the orthotopic autograft. Patients with intra-articular extension of tumor were excluded. All patients came from pediatric population and underwent surgical management at the Aga Khan University Hospital from January 2008 through June 2012.

The demographic data and clinical characteristics of the study population were acquired from clinical chart review, tumor registry information, physicians’ records, patients’ correspondence, and telephone interviews.

Our population included 23 males and 17 females. All patients were of pediatric age group with age ranging from 6 to 16 years. Osteosarcoma (57.5%) was the commonest followed by Ewing’s sarcoma (37.5%). There were 2 cases of chondrosarcoma. Long bones were mainly involved with most common involvement of lower limb. There were 17 cases of femur and 14 of tibia. From upper limb, there were 5 cases of humerus and 3 of radius. Only one case involved calcaneum of left side. Mean resection length was 13.9 cm (range: 0–28.1 cm) and mean length of reimplanted autoclaved graft was 18.5 cm (range: 0–32.3 cm).

Full oncological staging of each patient was performed before planning surgery, including biopsy. Multidisciplinary protocol was used to determine timing of tumor resection. For those patients who had osteosarcoma and Ewing’s sarcoma, adjuvant and neoadjuvant chemotherapy were administered according to international protocols [21].

2.1. Surgical Procedure

An adequate margin of osteotomy was determined by radiography using magnetic resonance imaging. In case of metaphyseal tumors, osteotomy was performed just proximal/distal to the physis and also saving the intra-articular part of the involved bone thereby preserving the joint. The method used by the authors consists of (1) wide en bloc resection of the tumour; (2) curettage of tumour from the resected bone; (3) autoclaving at 130° for 8 minutes (4) bone grafting from the fibula (both vascularized and nonvascularized fibular grafts used); (5) reimplantation of the autoclaved bone into the host bone defect and fixation with plates and/or IM nail [22]. To ensure an adequate surgical margin, frozen sections of multiple relevant and representative biopsy specimens were obtained.

The specimens were heated in an autoclave machine at 130° for 8 minutes [22]. Upon removal from the autoclave, the remaining soft tissue was easily scraped off from the surface of the bone. The specimen was then soaked in antibiotic mixed normal saline for 5 minutes and prepared for reinsertion. The whole process was performed under sterile conditions, with sterile wraps used for transport between the surgical field and the autoclave machine. This autoclaved segment of bone was then supplemented with either a vascularised or nonvascularised fibular bone graft and fixed to the host bone with metal plates and screws. The fibular graft length was always 3-4 cm more than the resection length. This larger fibular strut was used for a two-centimeter overlap at both proximal and distal ends of involved bone.

2.2. Clinical Evaluation

After operation those patients who had undergone a femoral reconstruction used crutches with partial weight bearing initially until the graft had united and the limb was considered to be stable. In tibial reconstruction, where the patellar tendon had been reattached, the lower limb was immobilised in a cast, usually for six weeks. Only passive movements were allowed for six weeks to be followed by active range of motion at the knee. When radiological healing was present at the site of the osteotomy, unassisted walking with full weight bearing was allowed. Limb length assessment was done using standing scanogram (lower limb standing long film). In the humeral reconstruction, the upper limb was supported by a sling postoperatively. Passive movements of the shoulder and elbow were allowed after two weeks. Objects more than 2 kg were not lifted until there was radiological union at the osteotomy site.

The patients were followed up every six weeks to evaluate the healing of the osteotomy, functional recovery, and potential complications until union and then every three months thereafter. The site of the osteotomy was considered to be healed radiologically if callus was seen bridging the site in both the anteroposterior and lateral planes. Nonunion was defined as failure of union one year after operation. Functional evaluation was assessed using the Musculoskeletal Tumour Society (MSTS) scoring system [23] which includes pain, function, patient acceptance, need for external supports, walking ability, and gait.

3. Results

At the final followup of at least 18 months (mean 29.2 months), 31 patients had recovered without any complications. Thirty-eight patients successfully achieved a solid bony union between the graft and recipient bone. Bony union was initially achieved between recipient bone and vascularized bone graft, followed by vascularized bone graft and autoclaved bone, and finally between recipient and autoclaved bone. One patient died due to distant metastasis to pelvis and lungs. Overall, mean time to full weight bearing was 6 months whereas mean time to complete bony union was 9.5 months. Mean MSTS score was 22. Details on individual cases can be found in Table 1 and Figure 1.

3.1. Early Complications

Three patients had deep infection at surgical sites. They were treated with systemic antibiotics along with surgical debridement. Two of these patients also required a coverage procedure with a gastrocnemius flap. One patient had significant skin necrosis at the surgical site. The gastrocnemius flap also failed and a free latissimus dorsi flap was used successfully to cover the defect.

3.2. Late Complications

Two patients experienced pathological fractures at surgical site at the 23rd and 29th months. Both underwent intramedullary nailing for fracture fixation. Two patients experienced local recurrence at 25th and 32nd months. One patient had to undergo disarticulation at hip due to extensive involvement of adjacent neurovascular structures and soft tissue. An other patient underwent wide margin reexcision. Two patients had nonunion at osteotomy sites. Revision procedures were done in both cases after waiting for one year. The procedure included bone graft usage and compression plating for fixation (Figure 2).

Figure 2

A 10-year-old girl with Ewing’s sarcoma. (a) X-ray shows mass in mid and distal right femur. (b) Intraoperative picture showing autoclaved bone with fibular graft. (c) Immediate postoperative X-ray (d) 26-month postoperative X-ray shows graft and bone union at both distal and proximal ends; however, there is considerable shortening of right femur. (e) Breakage of locking compression plate (f) Considering the limb length discrepancy and plate breakage, patient underwent Ilizarov application to right femur. (g) One year post-Ilizarov X-ray showing 2.5 cm gain in right femur length.

4. Discussion

When deciding which reconstructive procedure is the best after resection of a tumour, the surgeon must consider the applicability of the procedure, the level of difficulty, the patient’s age and functional demands, and the morbidity and incidence of complications as well as durability of the reconstructive procedure [16].

From a developing nation’s perspective, where patients themselves are primary payers of medical services, the debate still moves around the most cost-effective method of treatment. The technique of excision, sterilization, and reimplantation has the advantage of being a biological reconstruction with the potential for long-term survival. It is cheap and convenient and requires only one surgeon, and the operating time is much shorter than other reconstructive procedures. In the present study, by autoclaving and reusing the patient’s own bone, we obviated the need to procure an allograft which poses substantial problems in a country like Pakistan. In Pakistan, bone banking facilities are not available and are unlikely to be established in the near future because of financial, religious, and cultural constraints.

Primary advantages of autoclaved reimplants are that the implanted bone segment is a “custom fit” being the patient’s, own bone; no bone banking techniques, costs, immunological response, or transmission risks are involved; and they provide anatomical reattachment of muscles and tendons and natural joint preservation, with a higher incidence of incorporation and peripheral healing than allografts [24]. Definite removal of all tumor tissue is the most important factor in the surgical treatment of bone tumors with curative intention. Therefore, conscientiously performed biopsies to ensure an adequate surgical margin are of crucial importance [25].

The only real requirement is that the bone that is excised should have sufficient structural strength to be reinserted after sterilization, when of course it will “fit perfectly” [26, 27]. On the other hand, reimplanting an autoclaved bone is like using cadaveric bone, which presumably has no biological activity. For our pediatric patients we reduced the autoclaving time to 8 minutes. Autoclaving tumor bones for 10 minutes, as we do for adults [22], was making their bones too soft and unable to provide any structural strength. Our recurrence rate has not been affected by reducing this autoclaving time. Over time, resorption will often result in a stress fracture or mechanical failure of the construct. The purpose of the vascularised fibular graft is to improve the blood supply to the osteotomy sites and thereby minimise the time to union, reduce bone resorption, and improve structural stability [28].

Other techniques that are capable of destroying tumour cells in resected bone include single dose bolus radiotherapy, pasteurization, and repeated freezing-thawing with liquid nitrogen. Singh et al. [29] conducted a study to evaluate the effect of several sterilization methods, including autoclaving, boiling, pasteurization, and irradiation, on the mechanical behavior of human cortical bone graft and histopathology evaluation of tumour bone samples. They concluded that all methods of sterilization gave rise to 100 percent tumour kill; however, main difference laies in their effect on mechanical properties of bone.

An alternative for reconstruction following skeletal tumour resection is allografting. Chen et al. [16] compared the clinical outcome between groups with segmental allografts and devitalized (irradiated) autografts. No significant difference between the groups was found; however, the complication rate was unexpectedly high. Nonunion and late fracture occurred in 7% and 20%, respectively, of the irradiated bone group and in 43% and 14%, respectively, of the allograft group. In an attempt to reduce these complications, the present study used fibular bone grafts with autoclaved bone. Due to technical reasons, we could not use vascularized fibula in all the patients. However, non-vascularized fibula also worked almost equally nicely and was incorporated quickly. Supplementing with a fibula led to early union and is recommended as an important adjunct to autoclaved bone.

To our knowledge, only a few studies have attempted to enhance the neovascularisation of necrotic autoclaved autogenic or allogeneic bone grafts by combining these with vascularized bone grafting. Chang and Weber [30] used vascularised fibula graft and allograft in 14 cases to reconstruct massive diaphyseal bone defects following tumour resection. In their study, all but one case achieved successful bony union without late fatigue fracture of the fibula graft. These workers concluded that combined use could prevent allograft nonunion and result in decreased time to bony union. Sunagawa et al. [31] have previously demonstrated a neovascularization effect of vascularised bone graft to necrotic bone autograft in a canine model. The rationale for a combined vascularised and devitalized bone autograft is the cumulative advantage provided by mechanical endurance from the latter with the biological properties of the former [32].

5. Conclusion

The management of primary malignant bone tumors in less developed countries is often a daunting task, strewn with a long list of complications. This study is limited by the small sample size and short followup; however, we conclude that use of autoclaved tumor grafts provides a limb salvage option that is inexpensive and independent of external resources without sacrificing appropriate oncologic principles. Longer followups are needed to assess the long-term complications such as limb length discrepancy and its subsequent management.

Conflict of Interests

The authors declare that they have no conflict of interests.

References

T. Jager, P. Journeau, G. Dautel, S. Barbary, T. Haumont, and P. Lascombes, “Is combining massive bone allograft with free vascularized fibular flap the children's reconstruction answer to lower limb defects following bone tumour resection?” Orthopaedics and Traumatology, vol. 96, no. 4, pp. 340–347, 2010.
View at: Publisher Site | Google Scholar
B. Poffyn, G. Sys, A. Mulliez et al., “Extracorporeally irradiated autografts for the treatment of bone tumours: tips and tricks,” International Orthopaedics, vol. 35, no. 6, pp. 889–895, 2011.
View at: Publisher Site | Google Scholar
R. Kotz and M. Salzer, “Rotation-plasty for childhood osteosarcoma of the distal part of the femur,” Journal of Bone and Joint Surgery A, vol. 64, no. 7, pp. 959–969, 1982.
View at: Google Scholar
J. Hardes, C. Gebert, A. Hillmann, W. Winkelmann, and G. Gosheger, “The value of rotationplasty today in the treatment of primary malignant bone tumors: possibilities and limitations,” Orthopade, vol. 32, no. 11, pp. 965–970, 2003.
View at: Publisher Site | Google Scholar
H. Tsuchiya, K. Tomita, K. Minematsu, Y. Mori, N. Asada, and S. Kitano, “Limb salvage using distraction osteogenesis: a classification of the technique,” Journal of Bone and Joint Surgery B, vol. 79, no. 3, pp. 403–411, 1997.
View at: Publisher Site | Google Scholar
J. J. Eckardt, J. M. Kabo, C. M. Kelley et al., “Expandable endoprosthesis reconstruction in skeletally immature patients with tumors,” Clinical Orthopaedics and Related Research, no. 373, pp. 51–61, 2000.
View at: Google Scholar
M. M. Lewis, “The use of an expandable and adjustable prosthesis in the treatment of childhood malignant bone tumors of the extremity,” Cancer, vol. 57, no. 3, pp. 499–502, 1986.
View at: Google Scholar
D. L. Muscolo, M. A. Ayerza, L. Aponte-Tinao, and G. Farfalli, “Allograft reconstruction after sarcoma resection in children younger than 10 years old,” Clinical Orthopaedics and Related Research, vol. 466, no. 8, pp. 1856–1862, 2008.
View at: Publisher Site | Google Scholar
D. Uyttendaele, A. De Schryver, H. Claessens, H. Roels, P. Berkvens, and W. Mondelaers, “Limb conservation in primary bone tumours by resection, extracorporeal irradiation and re-implantation,” Journal of Bone and Joint Surgery B, vol. 70, no. 3, pp. 348–353, 1988.
View at: Google Scholar
D. Sabo, L. Bernd, M. Buchner et al., “Intraoperative extracorporeal irradiation and replantation for local treatment of primary malignant bone tumors,” Orthopade, vol. 32, no. 11, pp. 1003–1012, 2003.
View at: Publisher Site | Google Scholar
S. Toh, S. Harata, Y. Ohmi et al., “Dual vascularized fibula transfer on a single vascular pedicle: a useful technique in long bone reconstruction,” Journal of Reconstructive Microsurgery, vol. 4, no. 3, pp. 217–221, 1988.
View at: Google Scholar
J. Manabe, N. Kawaguchi, and S. Matsumoto, “Pasteurized autogeneous bone graft for reconstruction after resection of malignant bone and soft tissue tumors: imaging features,” Seminars in Musculoskeletal Radiology, vol. 5, no. 2, pp. 195–201, 2001.
View at: Google Scholar
N. Asada, H. Tsuchiya, K. Kitaoka, Y. Mori, and K. Tomita, “Massive autoclaved allografts and autografts for limb salvage surgery: a 1-8 year follow-up of 23 patients,” Acta Orthopaedica Scandinavica, vol. 68, no. 4, pp. 392–395, 1997.
View at: Google Scholar
A. M. Davis, M. Devlin, A. M. Griffin, J. S. Wunder, and R. S. Bell, “Functional outcome in amputation versus limb sparing of patients with lower extremity sarcoma: a matched case-control study,” Archives of Physical Medicine and Rehabilitation, vol. 80, no. 6, pp. 615–618, 1999.
View at: Publisher Site | Google Scholar
E. Aldlyami, A. Abudu, R. J. Grimer, S. R. Carter, and R. M. Tillman, “Endoprosthetic replacement of diaphyseal bone defects: long-term results,” International Orthopaedics, vol. 29, no. 1, pp. 25–29, 2005.
View at: Publisher Site | Google Scholar
T. H. Chen, W. M. Chen, and C. K. Huang, “Reconstruction after intercalary resection of malignant bone tumours: comparison between segmental allograft and extracorporeally-irradiated autograft,” Journal of Bone and Joint Surgery B, vol. 87, no. 5, pp. 704–709, 2005.
View at: Publisher Site | Google Scholar
D. L. Muscolo, M. A. Ayerza, L. Aponte-Tinao, M. Ranalletta, and E. Abalo, “Intercalary femur and tibia segmental allografts provide an acceptable alternative in reconstructing tumor resections,” Clinical Orthopaedics and Related Research, no. 426, pp. 97–102, 2004.
View at: Publisher Site | Google Scholar
D. Donati, R. Capanna, D. Campanacci et al., “The use of massive bone allografts for intercalary reconstruction and arthrodeses after tumor resection: a multicentric European study,” La Chirurgia Degli Organi di Movimento, vol. 78, no. 2, pp. 81–94, 1993.
View at: Google Scholar
R. C. Thompson Jr., A. Garg, D. R. Clohisy, and E. Y. Cheng, “Fractures in large segment allografts,” Clinical Orthopaedics and Related Research, no. 370, pp. 227–235, 2000.
View at: Google Scholar
K. L. Pan, W. H. Chan, G. B. Ong, S. Premsenthil, M. Zulkarnaen, D. Norlida et al., “Limb salvage in osteosarcoma using autoclaved tumor-bearing bone,” World Journal of Surgical Oncology, vol. 10, article 105, 2012.
View at: Publisher Site | Google Scholar
J. S. Biermann, D. R. Adkins, M. Agulnik, R. S. Benjamin, B. Brigman, J. E. Butrynski et al., “Bone cancer,” Journal of the National Comprehensive Cancer Network, vol. 11, no. 6, pp. 688–723, 2013.
View at: Google Scholar
M. J. Khattak, M. Umer, H.-U. Haroon-Ur-Rasheed, and M. Umar, “Autoclaved tumor bone for reconstruction: an alternative in developing countries,” Clinical Orthopaedics and Related Research, no. 447, pp. 138–144, 2006.
View at: Publisher Site | Google Scholar
W. F. Enneking, W. Dunham, M. C. Gebhardt, M. Malawar, and D. J. Pritchard, “A system for the functional evaluation of reconstructive procedures after surgical treatment of tumors of the musculoskeletal system,” Clinical Orthopaedics and Related Research, no. 286, pp. 241–246, 1993.
View at: Google Scholar
P. Böhm, J. Fritz, S. Thiede, and W. Budach, “Reimplantation of extracorporeal irradiated bone segments in musculoskeletal tumor surgery: clinical experience in eight patients and review of the literature,” Langenbeck's Archives of Surgery, vol. 387, no. 9-10, pp. 355–365, 2003.
View at: Google Scholar
B. K. S. Sanjay, P. G. Moreau, and D. A. Younge, “Reimplantation of autoclaved tumour bone in limb salvage surgery,” International Orthopaedics, vol. 21, no. 5, pp. 291–297, 1997.
View at: Publisher Site | Google Scholar
A. W. Davidson, A. Hong, S. W. McCarthy, and P. D. Stalley, “En-bloc resection, extracorporeal irradiation, and re-implantation in limb salvage for bony malignancies,” Journal of Bone and Joint Surgery B, vol. 87, no. 6, pp. 851–857, 2005.
View at: Publisher Site | Google Scholar
K. Muramatsu, K. Ihara, T. Hashimoto, S. Seto, and T. Taguchi, “Combined use of free vascularised bone graft and extracorporeally-irradiated autograft for the reconstruction of massive bone defects after resection of malignant tumour,” Journal of Plastic, Reconstructive and Aesthetic Surgery, vol. 60, no. 9, pp. 1013–1018, 2007.
View at: Publisher Site | Google Scholar
S. Mottard, R. J. Grimer, A. Abudu, S. R. Carter, R. M. Tillman, L. Jeys et al., “Biological reconstruction after excision, irradiation and reimplantation of diaphyseal tibial tumours using an ipsilateral vascularised fibular graft,” Journal of Bone and Joint Surgery, vol. 94, no. 9, pp. 1282–1287, 2012.
View at: Google Scholar
V. A. Singh, J. Nagalingam, M. Saad, and J. Pailoor, “Which is the best method of sterilization of tumour bone for reimplantation? a biomechanical and histopathological study,” BioMedical Engineering Online, vol. 9, article 48, 2010.
View at: Publisher Site | Google Scholar
D. W. Chang and K. L. Weber, “Use of a vascularized fibula bone flap and intercalary allograft for diaphyseal reconstruction after resection of primary extremity bone sarcomas,” Plastic and reconstructive surgery, vol. 116, no. 7, pp. 1918–1925, 2005.
View at: Google Scholar
T. Sunagawa, A. T. Bishop, and K. Muramatsu, “Role of conventional and vascularized bone grafts in scaphoid nonunion with avascular necrosis: a canine experimental study,” Journal of Hand Surgery, vol. 25, no. 5, pp. 849–859, 2000.
View at: Publisher Site | Google Scholar
K. Muramatsu, K. Ihara, T. Miyoshi et al., “Stimulation of neo-angiogenesis by combined use of irradiated and vascularized living bone graft for oncological reconstruction,” Surgical Oncology, vol. 21, no. 3, pp. 223–229, 2013.
View at: Google Scholar

Copyright

Copyright © 2013 Masood Umer et al. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

PDF Download Citation

Download other formats

Order printed copies

Views

2675

Downloads

1170

Citations