Orthopaedics Vol3 No4


Page 32 SA Orthopaedic Journal  Winter 2016 | Vol 15 • No 2

Independent segmental bone transport of
the radius and ulna: A case report

FF Birkholtz1,2 MBChB, MMed(Orth), FCOrth(SA)
P Greyling1 MBChB(Pret), MMed(Orth)(Pret), FCS(Orth)SA

1 Department of Orthopaedics, University of Pretoria
2 Walk-A-Mile Centre for Advanced Orthopaedics, Centurion, Pretoria

Correspondence:
Dr Franz F Birkholtz

Tel: 012 6442641
Fax: 012 6442642

Email: franz.birkholtz@walkamile.co.za
Address: PO Box 11328, Centurion, 0046

Introduction

Significant segmental bone loss in the forearm is a difficult
clinical entity to treat. Strategies described in literature
include interposition grafting, double-barrel free fibula
reconstruction, induced membrane techniques, and
converting to a single bone forearm by establishing a cross-
union.

Although the continuity of bone can be restored, the
complex relationship of the radius and ulna may be
disturbed, leading to a limitation of pro- and supination.

Reconstructing the radius and ulna independently with
distraction osteogenesis bone transport has the theoretical
advantage of maintaining the complex relationship between
the radius and ulna in the forearm. In principle this should
provide the ability to maintain a measure of pro- and
supination after reconstruction.

Case report

A 34-year-old woman was involved in a motor vehicle
accident. She was a right-handed social worker at the time of
injury and was systemically healthy. The injury was limited
to the right upper limb, where she sustained severely
comminuted fractures of the right radius and ulna. Figure 1
shows the initial radiographic appearance. There was a large
dorsal wound overlying the distal forearm region,
measuring 5 × 8 cm.

Initially the patient presented to a regional hospital,
where a primary debridement was performed and intra-
venous antibiotic therapy was instituted. An open
reduction and internal fixation was performed with
plates and screws. Shortly afterwards she developed a
fulminant infection in the fracture sites. She was splinted
and referred to our unit for further management.

A thorough debridement and removal of instrumentation
was performed and the radius and ulna were fixed with a
temporary modular bar-to-pin external fixator. Three days
later a wound inspection was carried out and approximately
5 cm of necrotic bone was removed from the radius and ulna.

Abstract

Significant bone loss in the forearm involving both the radius and ulna is a difficult problem to manage. The
functional outcome may be limited due to loss of pro- and supination. 

We present a case where significant bone loss of both the radius and the ulna in an adult patient was successfully
reconstructed using segmental bone transport. The radius and ulna were transported independently from each
other to try and maintain function. A reasonable functional result was achieved.

Key words: bone transport, distraction osteogenesis, forearm bone loss, radius ulna transport, cement spacer

http://dx.doi.org/10.17159/2309-8309/2016/v15n2a4

Figure 1. radiograph depicting the patient’s initial

diaphyseal radius and ulna fractures. note the extent of

displacement, potentially indicating the severity of the

injury.



SA Orthopaedic Journal  Winter 2016 | Vol 15 • No 2 Page 33

An antibiotic cement spacer with gentamycin was created
using off-the-shelf bone cement and inserted into the bone
defect. Broad-spectrum intravenous antibiotics were
administered. Figure 2 shows the antibiotic cement spacer
in situ, as well as the stabilisation using the modular bar-
to-pin external fixator.

The patient was referred to the plastic and reconstructive
surgeon who provided durable soft tissue cover with a
radial forearm flap. 

Six weeks later the temporary external fixator and
polymethylmetacrylate cement spacer were removed. A
paediatric monorail fixator (LRS, Orthofix, Verona, Italy)
was applied with six hydroxyapatite-coated half pins on
each of the two forearm bones as depicted in Figure 3. A
predrilled osteotomy was done proximally for bone
transport in both the radius and ulna. After a waiting
period of 10 days, distraction progressed at a rate of 1 mm
per day. Throughout the distraction period, the patient
was seen by the rehabilitation team and progressed with
intensive hand therapy to maintain joint mobility and
hand function.

Once distraction was complete and the bone defects oblit-
erated by distraction osteogenesis, an open docking
procedure was performed on both the radius and ulna.
During this procedure, the bone ends at the docking site
were freshened, interpositional fibrosis removed and the
fragments compressed acutely using the external fixator. The
docking site was augmented with cancellous autograft
obtained from the right proximal tibia. Figure 4 demonstrates
the radiographic appearance after the docking procedure.

Approximately three months after docking, the LRS
external fixators were removed and locking nails inserted
into the radius and ulna. The ulna docking site was re-
grafted. Final time in external fixator was 142 days which
represents an external fixation index of just under 1 month
per cm of bone lengthening. 

Figure 2. radiograph depicting stabilisation of the

radius and ulna with a modular pin-to-bar external

fixator. Also note the antibiotic bone cement spacer

placed in the defect of the radius and ulna.

Figure 3. A clinical photograph showing the appearance

of the two external fixators on the forearm. note also

the presence of the radial forearm flap used to provide

durable soft tissue cover.

Figure 4. radiograph depicting the forearm after

distraction osteogenesis and subsequent open docking of

the radius and ulna.

Figure 5. these clinical pictures were taken at final

follow-up 4 years after the initial treatment and show a

reasonable range of motion of the forearm.



• SAOJ

Page 34 SA Orthopaedic Journal  Winter 2016 | Vol 15 • No 2

Two months later the fractures were radiologically and
clinically united.

The patient was followed up to 4 years after the index
procedure and has returned to her prior occupation. She
reported no chronic pain and has shown no evidence of
infection. At final assessment she had an elbow arc of motion
from 0 to 140 degrees of flexion. She was able to supinate to
neutral and had pronation of up to 60 degrees (Figure 5).

Discussion

The special anatomical relationship between the radius and
ulna require anatomical reduction to restore bone stability
and function of forearm pro- and supination. The radius and
ulna function as a unit together with the proximal and distal
joints and is viewed as a bicondylar joint. For these reasons
diaphyseal forearm fractures should be viewed as intra-
articular lesions.1

Most reconstruction techniques have been described for
the lower limb. Literature on treating forearm bone loss is
limited to a small series of case studies. Techniques that have
been described to treat forearm bone loss include interpo-
sition grafting, double barrel free fibula reconstruction,
induced membrane techniques, segmental bone transport
and the creation of a single bone forearm by establishing a
cross-union.2,3

These techniques do not replace the need for a thorough
debridement and excision of necrotic and infected bone and
tissue. Infection is not healed by the simple compression of
the fracture site alone.2-4

When dealing with forearm non-unions and bone loss, soft
tissue adhesions and scar tissue need to be addressed.4 As
was the case in this instance, meticulous attention to rehabil-
itation is needed to optimise the functional outcome. 

A cement spacer was used to manage the transport space.
Because it was preloaded with antibiotics, it provided an
added benefit of local infection control. Cement spacers have
the added benefit of membrane induction, which leads to a
bio-active pseudo-periosteum which can aid in bone recon-
struction.

Durable soft tissue coverage is an important determinant
in successful segmental bone transport.2 In this case it was
provided by a radial forearm flap, which is a pliable, low-
profile fasciocutaneous flap.

The monolateral frames used in this case provided the
advantage of independently but concurrently reconstructing
each of the two bones. The intention was to try and preserve
the ellipse of the forearm and to preserve elbow range of
motion in flexion, extension, pronation and supination.
Based on the range of motion at final assessment at 4 years’
follow-up, it seems that this philosophy was, in part,
successful.

An open docking procedure with an autologous bone graft
at the docking site is in accordance with the data reported in
the literature and important to prevent repeated fractures
and nonunion.2,5

Intra-medullary fixation provided stability maintaining
the radius and ulna length, while still allowing the radius
and ulna to function individually.3 In this instance it also
provided internal stability to the tenuous regenerates and
docking sites to facilitate rehabilitation and earlier external
fixator removal.

Summary

Significant bone loss in the forearm involving both the
radius and ulna is a difficult problem to manage. The
functional outcome may be limited due to loss of pronation,
supination and grip strength. This case report illustrates a
novel surgical approach to independently transport the
radius and ulna, and thus provide the best possible
functional outcome in this devastating condition.

Compliance with Ethics Guidelines
The content of the article is the sole work of the authors. FF
Birkholtz and P Greyling declare that no benefits of any form
have been or are to be received from a commercial party
related directly or indirectly to the subject of the article. The
procedures followed were in accordance with the ethical
standards of the Helsinki Declaration (1964, amended most
recently in 2008) of the World Medical Association. The
patient’s written consent was obtained for inclusion of her
data in this paper.

References
1.      Jupiter JB, Fernandez DL, Levin SL, Wysicki RW.

Reconstruction of Posttraumatic Disorders of the Forearm.
J Bone Joint Surg Am 2009;91:2730-39.

2.      Rigal S, Merloz P, Le Nen D, Mathevon H, Masquelet AC,
the French Society of Orthopaedic Surgery and
Traumatology (SoFCOT). Bone transport techniques in
posttraumatic bone defects. Orthopaedics and Traumatology:
Surgery and Research 2012;98:103-108.

3.      Gupta DK, Kumar G. Gap nonunion of forearm bones
treated by modified Nicoll’s technique. Indian J Orthop
2010;44(1):84-88.

4.      Liu T, Liu Z, Ling L, Zhang X. Infected forearm nonunion
treated by bone transport after debridement. BMC
Musculoskeletal Disorders 2013;14:273.

5.      Chunshen W, Zhaohua B, Chenxi Y, Cheng C, Huilin Y, Jun
Z. Bone transport combined with locking plate and bone
grafting for treatment of nonunion of the ulna: a case
report. Int J Clin Exp Med 2013;6(10):996-1000.

This article is also available online on the SAOA website
(www.saoa.org.za) and the SciELO website (www.scielo.org.za).
Follow the directions on the Contents page of this journal to
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