South African Orthopaedic Journal

ORTHOPAEDIC ONCOLOGY AND INFECTIONS

DOI 10.17159/2309-8309/2022/v21n2a5 Mugla W et al. SA Orthop J 2022;21(2)

Citation: Mugla W, Bauer HCF, Vogel J, 
Hosking KV, Campbell N, Hilton TL. 
Modular prosthetic reconstruction 
for primary bone tumours of the 
distal tibia in ten patients. SA Orthop 
J. 2022;21(2):95-99. http://dx.doi.
org/10.17159/2309-8309/2022/v21n2a5

Editor: Prof. Theo le Roux, University of 
Pretoria, Pretoria, South Africa

Received: May 2021

Accepted: November 2021

Published: May 2022

Copyright: © 2022 Mugla W. This is an 
open-access article distributed under 
the terms of the Creative Commons 
Attribution Licence, which permits 
unrestricted use, distribution and 
reproduction in any medium, provided 
the original author and source are 
credited.

Funding: No funding was received for 
this study.

Conflict of interest: Authors KVH 
and TLH are consultants for LRS. NC 
is the biomechanical engineer and 
managing director at LRS Implants. 
NC provided information based solely 
on the manufacturing of the implant. 
The remaining authors declare that 
they have no conflicts of interest that 
are directly or indirectly related to this 
research.

Abstract
Background
Below-knee amputation (BKA) is the safest treatment for benign aggressive and malignant 
bone tumours of the distal tibia, yielding good oncological and functional results. However, 
in selected patients where limb salvage is feasible and amputation unacceptable to the 
patient, limb salvage using a distal tibial replacement (DTR) can be considered. This study 
aims to present the oncological and functional results of the use of the latter treatment 
method in our unit.

Methods
A retrospective folder review was performed for all ten patients who received a modular DTR 
between 1 January 2005 and 31 January 2019 for a primary bone tumour, either benign 
aggressive or malignant. Six were female and the mean age was 31 (12–75) years. There 
were five patients with giant cell tumour of bone, four with osteosarcoma and one with a low-
grade chondrosarcoma. The patients with osteosarcoma had neoadjuvant chemotherapy 
before surgery. Function was assessed by the Musculoskeletal Tumor Society (MSTS) 
score.

Results
Two patients had local recurrence treated with a BKA and one other patient died of 
metastases three years postoperatively. At a mean follow-up of three years, the remaining 
eight patients had a mean MSTS score of 83% (67–93%). There were no radiological signs 
of loosening, and no revision surgeries.

Conclusion
Endoprosthetic replacement of the distal tibia for primary bone tumours can be a safe 
treatment option in very selected cases.
Level of evidence: Level 4
Keywords: distal tibia, endoprosthetic replacement, osteosarcoma, giant cell tumour, limb salvage, 
amputation

Modular prosthetic reconstruction for primary bone tumours 
of the distal tibia in ten patients 
Walid Mugla,¹  Henrik CF Bauer,² Jonathan Vogel,³ Keith V Hosking,⁴ Neil Campbell,⁵ Thomas L Hilton⁶*  

1 Sarcoma Unit, Groote Schuur Hospital; Faculty of Medicine and Health Sciences, Department of Surgery, Division of Orthopaedics,  
University of Cape Town, Cape Town, South Africa 

² Department of Molecular Medicine and Surgery, Karolinska Institute, Stockholm, Sweden; visiting professor in the Faculty of Medicine and Health 
Sciences, Department of Surgery, Division of Orthopaedics, University of Cape Town, Cape Town, South Africa 

³ Faculty of Medicine and Health Sciences, Department of Surgery, Division of Orthopaedics, University of Cape Town, Cape Town, South Africa 
⁴ Vincent Pallotti Life Orthopaedic Hospital, Cape Town; Faculty of Medicine and Health Sciences, Department of Surgery, Division of Orthopaedics, 

University of Cape Town, Cape Town, South Africa 
⁵ LRS Implants, Cape Town, South Africa
⁶ Groote Schuur Hospital and Life Vincent Pallotti Orthopaedic Hospital, Cape Town; Faculty of Medicine and Health Sciences, Department of Surgery, 

Division of Orthopaedics, University of Cape Town, Cape Town, South Africa

*Corresponding author: thomas@drthilton.com

Introduction
Limb-sparing surgery for primary bone tumours of the distal tibia 
is fraught with difficulties due to the paucity of soft tissue coverage 
and difficulties in creating a durable fixation of the prosthetic 
components.1 Wide surgical margins and acceptable function 
of the ankle joint can seldom be achieved.1,2 Therefore, below-
knee amputation (BKA) is the surgical method of choice. While 
oncologically safe, it also provides excellent function with the ever-

improving external prosthetics.3 In selected cases where a wide 
surgical margin is possible and amputation unacceptable to the 
patient, limb salvage may be attempted.3 With the advent of additive 
manufacturing and improvements in polyethylene components 
and manufacturing, distal tibial replacement (DTR) design has 
provided solutions to previous problems and reduced implant cost 
by creating an ‘off-the-shelf’ prosthesis rather than an expensive 
and time-consuming custom prosthesis.3,4 The aims of this study 

https://orcid.org/0000-0002-2961-7296
https://orcid.org/0000-0002-6178-5062


Page 96 Mugla W et al. SA Orthop J 2022;21(2)

are to present the oncological and functional assessment of ten 
patients treated with resection of the distal tibia and reconstruction 
with a DTR. Our objectives are to do this through a retrospective 
folder review of all patients treated in this manner in our unit.

Patients and methods
A medical record and image review was performed of ten patients 
who underwent a DTR between 1 January 2005 and 31 January 
2019 for Enneking benign aggressive or malignant primary bone 
tumour.5 No patient was excluded due to missing data or lost to 
follow-up.

Data capture included patient demographics, procedural 
complications, revision procedures, local recurrence, tumour 
metastases and death. The histological diagnosis was established 
by core needle biopsy using a JamshidiTM 12G needle.6 Functional 
outcome was assessed using the Musculoskeletal Tumor Society 
(MSTS) score. The MSTS scoring system is a specific scoring 
system to determine the physical and mental health of patients with 
extremity sarcoma. The system assigns numerical values (0–5) for 
six categories. A numerical score and per cent rating is calculated 
to allow for comparison of results.7 Recommendations regarding 
amputation and limb salvage were made at multidisciplinary team 
conferences. 

There were six females and four males, with a mean age of 
31 (12–75) years. Five patients had a giant cell tumour (GCT) 
of bone (Figure 1), four an osteosarcoma, and one a low-grade 
chondrosarcoma. The four osteosarcoma patients had neoadjuvant 
chemotherapy, and none of the GCT patients had preoperative 
demosumab.

Description of the prosthesis
The distal tibia replacement used in this study is an LRS Distal 
Tibia Replacement (www.lrs.com). It is a modular reconstruction 
system that allows for different resection lengths of the distal tibia 
in 10 mm increments. The implant is not side specific.

The talar side of the prosthesis creates a metal (titanium 
Ti6Al4V) talar dome. It is made up of two parts: the talar base 
plate, and the talar dome. The base plate is 3D printed in titanium, 
incorporating a trabecular mesh structure for bone ingrowth. It is 
based on cementless fixation. There are three 8 mm pegs which 
are impacted into the talus. All surfaces in contact with the talus 
contain the trabecular mesh structure to encourage bone ingrowth. 
The talar dome is attached to the base plate by a morse taper. 
The dome is titanium with a titanium oxide ceramic surface. It has 
a ‘saddle’ shape similar to that of a native talus, to provide tibial 

tracking and a degree of varus–valgus support. The orientation of 
the dome can be adjusted prior to impaction onto the talar base 
plate.

The talar dome articulates with an ultra-high molecular weight 
polyethylene (UHMWPE) bearing to replicate the natural range of 
motion of the ankle. The prosthesis is not constrained, except for 
the congruent ‘saddle’ fit of the talar dome and the polyethylene 
bearing surface. The bearing sizing is available in 3 mm increments 
to allow for balancing of the implant and soft tissues. The bearing is 
impacted onto a titanium mount which then attaches to diaphyseal 
extensions whose number and length are matched to fill the defect 
left by the resection.

The implant is secured into the tibia by a cemented titanium 
intramedullary stem, with additional fixation provided by a trabecular 
3D-printed extra-cortical fork to limit rotation of the implant in the 
bone and encourage bone ingrowth.

Surgical technique
The patient is positioned supine, and an above-knee tourniquet 
is applied. An anteromedial approach is performed to access the 
distal tibia and ankle joint (Figure 2). The biopsy site is included 
in the resected specimen. The tendons of tibialis anterior and 
extensor digitorum communis along with the neurovascular bundle 
are dissected away from the tumour, and the deltoid ligament, 
ankle syndesmotic ligament and capsule are cut. This allows for the 
distal tibia to be delivered from the leg. The remaining soft tissue 

Figure 2. Clinical picture showing endoprosthetic replacement through anteromedial approach

Figure 1. Sagittal MRI image of giant cell tumour of the distal tibia



Page 97Mugla W et al. SA Orthop J 2022;21(2)

is dissected off the tibia. The tibial diaphysis may be transected 
proximally before the ankle ligaments are cut to allow for easier 
manipulation of the distal tibia. Once the specimen is removed, 
it is placed nearby to assist with measurement of the length of 
prosthesis to be inserted. The talus is then cut transversely with an 
oscillating saw. A high-speed burr and a guide are used to create 
three peg holes which will accept the uncemented talar baseplate 
and titanium pegs (Figure 3). The articulation of the prosthetic 
ankle joint consists of the titanium tibial dome and polyethylene 
bearing. The distal tibia body and appropriately sized extra-cortical 
fork and diaphyseal extensions are attached to an intramedullary 
stem which is then cemented into the proximal tibia after sequential 
reaming of the proximal tibia shaft and trialling for length. Care 
must be taken during reduction not to fracture the fibula which is 
left intact and provides lateral support to the construct. The ankle 
is immobilised in a below-knee backslab for two weeks. The patient 
is then placed into a moon boot or below-knee plaster for a further 
four weeks (see Figure 4 for postoperative X-ray). Thereafter, 
the patient begins physiotherapy consisting of graduated weight 
bearing and active and passive ankle dorsiflexion and plantar 
flexion.

Results
One patient died three years after treatment due to metastatic 
disease. Two patients had local recurrence, one of whom also 
had a deep infection, and both were treated with a BKA. After 
amputation, both patients remain disease free (Table I). 

Functional outcome and complications
After a mean follow-up of 43 months (6–116), of the eight patients 
who did not undergo a BKA, the mean MSTS score was 83% 
(70–93). Two patients complained of mild ongoing pain around 
their lateral malleolus and had an antalgic gait on examination. 
There were no radiological signs of loosening, and no revision 
surgeries. They scored modestly in their MSTS assessment which 
has grades, none, modest and severe. The patients’ pain was 
controlled with oral analgesia only. 

 Figure 4. Anteroposterior and mortise X-rays showing distal tibia DTR

Cemented intramedullary 
stem (Ti6Al4V)

Cortical support fork 
(Ti6Al4V)

Diaphyseal extension 
(Ti6Al4V)

Distal tibial bearing mount 
(Ti6Al4V)

Ultra-high molecular 
weight polyethylene 
bearing (UHMWPE)

Talar dome (Ti6Al4V)

Talar base plate (Ti6Al4V)

Figure 3. Labelled assembly of the distal tibia construct 



Page 98 Mugla W et al. SA Orthop J 2022;21(2)

Discussion 
This retrospective study of ten patients with primary bone tumours 
of the distal tibia shows that acceptable oncological and functional 
results can be achieved in the short to medium period of follow-up. 
Nevertheless, BKA will remain the treatment of choice, providing 
safe oncological margin and excellent function.3 

In South Africa, the management of primary bone tumours of the 
appendicular skeleton with limb ablation is often met with strong 
opposition due to cultural and traditional beliefs. These usually 
preclude amputation, often with increased morbidity and mortality 
of the patient.8 Brown et al. described the challenges associated 
with cross-cultural communication in this regard, and highlighted 
the family-centred decision-making unit, which often refuses a 
limb ablation.8 In these circumstances, an alternative treatment, 
potentially with higher oncological risks, needs to be considered 
to prevent morbidity and possible mortality that may result from 
rejection of medical treatment. We, therefore, propose that in South 
Africa, and many other countries across the African continent, an 
attempt at limb-sparing surgery and distal tibial replacement may 
be considered.

In resource-limited countries like South Africa, BKA is often 
recommended as it is supposedly cheaper than megaprosthetic 
replacement, and also minimises complications and repeat surgery. 
However, in these countries adequate external prosthetics cannot 
be assured during the patient’s whole life span. Grimer et al. have 
also showed that in the long run, limb-sparing surgery, in general, 
is cost effective when compared to amputations due to the accrued 
cost of repair and replacement of artificial limbs.9 Furthermore, 
with modular systems of megaprosthetics, as reported here, unit 
costs should come down compared to custom-made implants.

There are only a few reports of DTR in primary bone tumours. 
Interestingly, none of the reports have more than six patients and 
all are at least ten years old.1,2,10,11 Similar to our study, they report 
a good functional outcome, reasonable complication rates and 
prosthesis longevity (Table II). Infection and recurrence were the 

most common causes of secondary amputation. Mechanical failure 
was reported, whereas we did not have any cases of mechanical 
failure in our series. 

In our series of ten patients, two were amputated because 
of tumour recurrence and infection. For comparison, the final 
amputation rate after limb-sparing surgery for tumours of the 
proximal tibia is around 10%.12 In the proximal tibia, there are similar 
problems to the distal tibia of soft tissue coverage and restoring 
active joint function. The reason why amputation is seldom the 
procedure of choice for the proximal tibia is probably that a knee 
disarticulation or through-thigh amputation is considered more 
debilitating than a below-knee amputation.

The most common mechanical complication of ankle joint 
replacement is aseptic loosening of the talar tray.11 We had no 
cases of mechanical loosening at final follow-up. Abudu et al. and 
Shekkeris et al. both described loosening of the tibial baseplate in 
one patient each, and Lee et al. reported talar collapse in one.1,3,13 
The uncemented, grown titanium design of the implant may prove 
to reduce the risk of talar prosthetic complications but the follow-up 
and number of patients is too small to be conclusive.10,11

Future research is needed to determine how this procedure can 
be of benefit in those instances where patients refuse amputation 
at any cost for cultural reasons but will accept limb-sparing surgery. 
This is difficult due to the small number of patients that may have 
this procedure and a national and international sarcoma registry 
would assist in providing more data on the subject. Engagement 
with cultural leaders would also help with earlier presentation of 
these patients to sarcoma centres and allow limb-sparing surgery.

Conclusion
Reconstruction of the distal tibia after resection for primary bone 
tumours with a distal tibial megaprosthesis yields good functional 
results with a high MSTS score and acceptable oncological 
outcomes with only a 20% local recurrence rate in the short to 

Table I: Details of results
Patient Age Sex Diagnosis Resection Follow-up 

(months)
MSTS (%) Complications

1 43 M GCT R0 29 - Local recurrence & infection – BKA

2 25 M GCT R0 116 27 (90%) -

3 29 F GCT R0 45 28 (93%) -

4 20 F GCT R0 39 21 (70%) Constant ankle pain

5 59 M GCT R0 35 26 (87%) Intermittent ankle pain

6 15 M Osteosarcoma R0 36 28 (93%) DOD

7 14 F Osteosarcoma R0 43 21 (70%) -

8 14 F Osteosarcoma R0 30 - Local recurrence – BKA

9 12 F Osteosarcoma R0 6 24 (80%) -

10 75 F Chondrosarcoma R0 54 28 (93%) -

Mean 31 43 25 (83%)

Table II: Summary of current literature describing DTR
Study and year Number of 

patients
Follow-up

(years) 
Local 

recurrence 
Metastases Infection Amputation Functional 

outcome

Shekkeris et al.3 2009 6 9.6 0 0 2 2 MSTS: 70%

Lee et al.13 1999 6 5.3 0 0 1 0 ISOLS: 80%

Natarajan et al.2 2000 6 3.4 2 0 1 3 MSTS: 80%

Abudu et al.1 1999 4 4.6 1 1 1 0 MSTS: 64%

Current study 2021 10 3.6 2 1 1 2 MSTS: 83%



Page 99Mugla W et al. SA Orthop J 2022;21(2)

medium term. Therefore, this procedure can be considered as an 
alternative to limb ablation in selected cases.

Ethics statement
The authors declare that this submission is in accordance with the principles laid down 
by the Responsible Research Publication Position Statements as developed at the 
2nd World Conference on Research Integrity in Singapore, 2010.
Ethical approval number HREC 734/2019. For this retrospective study, formal consent 
was not required. 

Declaration
The authors declare authorship of this article and that they have followed sound 
scientific research practice. This research is original and does not transgress 
plagiarism policies. 

Author contributions 
WM: study conceptualisation, study design, data capture, state patients’ follow-up and 
scoring, first draft preparation, manuscript preparation 
HCFB: data analysis, manuscript preparation 
JV: data capture, first draft preparation
KVH: private patients’ data capture and score
NC: description of the prosthesis and pictures
TLH: involved in all aspects of this article

ORCID
Mugla W  https://orcid.org/0000-0002-2961-7296
Bauer HCF  https://orcid.org/0000-0002-3557-0252
Vogel J  https://orcid.org/0000-0003-1156-6168
Hosking KV  https://orcid.org/0000-0002-3557-0252
Hilton TL  https://orcid.org/0000-0002-6178-5062

References 
1.  Abudu A, Grimer RJ, Tillman RM, Carter SR. Endoprosthetic replacement of the distal tibia 

and ankle joint for aggressive bone tumours. Int Orthop. 1999;23(5):291-94. https://doi.
org/10.1007/s002640050374.

 2.  Natarajan MV, Annamalai K, Williams S, et al. Limb salvage in distal tibial osteosarcoma 
using a custom mega prosthesis. Int Orthop. 2000;24(5):282-84. https://doi.org/10.1007/
s002640000172.

3.  Shekkeris AS, Hanna SA, Sewell MD, et al. Endoprosthetic reconstruction of the distal 
tibia and ankle joint after resection of primary bone tumours. J Bone Joint Surg Br. 
2009;91(10):1378-82. https://doi.org/10.1302/0301-620x.91b10.22643. 

4.  Hilton T, Campbell N, Hosking K. Additive manufacturing in orthopaedics: clinical 
implications. SA Orthop J. 2017;16(2):63-67. 

5.  Enneking WF, Spanier SS, Goodman MA. A system for the surgical staging of 
musculoskeletal sarcoma. Clin Orthop Relat Res. 2003;(415):4-18. https://doi.
org/10.1097/01.blo.0000093891.12372.0f.

6.  Kundu ZS. Classification, imaging, biopsy and staging of osteosarcoma. Indian J Orthop. 
2014;48(3):238-46. https://doi.org/10.4103/0019-5413.132491.

7.  Enneking WF, Dunham W, Gebhardt MC, et al. A system for the functional evaluation of 
reconstructive procedures after surgical treatment of tumors of the musculoskeletal system. 
Clin Orthop Relat Res. 1993;(286):241-46.

8.  Brown O, Goliath V, Van Rooyen R, et al. Communicating about prognosis with regard to 
osteosarcoma in a South African cross-cultural clinical setting: strategies and challenges. SA 
Orthop J. 2019;18(4):46-51.

9.  Grimer RJ, Carter SR, Pynsent PB. The cost-effectiveness of limb salvage for bone tumours. 
J Bone Joint Surg Br. 1997;79(4):558-61. https://doi.org/10.1302/0301-620x.79b4.7687. 

10.  Harris N. Total ankle arthroplasty. Pract Proced Elect Orthop Surg Pelvis Low Extrem. 
2013;6(8):269-72. 

11.  Gross CE, Palanca AA, DeOrio JK. Design rationale for total ankle arthroplasty systems: 
an update. J Am Acad Orthop Surg. 2018;26(10):353-59. https://doi.org/10.5435/jaaos-d-1 
6-00715.

12.  Summers SH, Zachwieja EC, Butler AJ, et al. Proximal tibial reconstruction after tumor 
resection: A systematic review of the literature. JBJS Rev. 2019;7(7):e1. https://doi.
org/10.2106/jbjs.rvw.18.00146.

13.  Lee SH, Kim HS, Park YB, et al. Prosthetic reconstruction for tumours of the distal 
tibia and fibula. J Bone Joint Surg Br. 1999;81(5):803-807. https://doi.org/10.1302/03 
01-620x.81b5.9588.

https://orcid.org/0000-0002-2961-7296
https://orcid.org/0000-0002-3557-0252
https://orcid.org/0000-0003-1156-6168
https://orcid.org/0000-0002-3557-0252
https://orcid.org/0000-0002-6178-5062

	_Hlk76063671