Panchoo P et al. SA Orthop J 2020;19(3)
DOI 10.17159/2309-8309/2020/v19n3a4

South African Orthopaedic Journal 
http://journal.saoa.org.za

FOOT AND ANKLE

Citation: Panchoo P, Wiegerinck JI, Boskovic V, Laubscher M, Maqungo S, McCollum G, Dey R. Outcomes of primary fusion in high-energy Lisfranc 
injuries at a tertiary state hospital. SA Orthop J 2020;19(3):150-155. http://dx.doi.org/10.17159/2309-8309/2020/v19n3a4

Editor: Prof. NP Saragas, University of the Witwatersrand, Johannesburg, South Africa

Received: October 2019  Accepted: March 2020  Published: August 2020

Copyright: © 2020 Panchoo P. 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 external funding was received for this study.

Conflict of interest: The authors declare they have no conflicts of interest that are directly or indirectly related to the research.

Abstract

Background: High-energy Lisfranc injuries are relatively uncommon but can lead to severe disability and morbidity. Primary fusion 
is a treatment option that can improve outcomes and reduce the reoperation rate. The aim of this study was to evaluate our series of 
primary fusions for high-energy Lisfranc injuries, looking specifically at type of fusion, time to union, non-union rates, reoperation rates 
and quality of reduction.

Methods: Patients who underwent surgery for Lisfranc injuries were identified from the REDCap surgical database and then retrieved 
from records. Only cases of primary fusion in adults were included. We excluded low-energy sprains and athletic injuries, ipsilateral 
lower limb injuries and cases where reduction and fixation were done. Radiographs were analysed from the iSite Enterprise PACS 
system (Philips®).

Results: Between 2013 and 2018, 12 cases of high-energy Lisfranc injuries were identified where primary fusion was done. Seven 
patients (58%) underwent fusion of the first, second and third tarsometatarsal (TMT) joints. The first and second TMT joints were fused 
in only one case (8%), and the second and third TMT joints were fused in four cases (33%). Only one patient (8%) had removal of 
implants. Compression plating was the technique of choice used for fusion. There was 100% union rate and average time to union was 
84 days. Acceptable reduction was observed in nine cases (75%). Three cases (25%) of malreduction were found, among which one 
patient had pre-existing hallux valgus. 

Conclusion: The majority of patients who underwent primary fusion of at least one TMT joint had good radiological outcome. Further 
studies with better clinical follow-up are needed.

Level of evidence: Level 4

Keywords: Lisfranc, tarsometatarsal, outcome, fusion

Outcomes of primary fusion in high-energy Lisfranc 
injuries at a tertiary state hospital
Panchoo P1 , Wiegerinck JI2, Boskovic V3 , Laubscher M4 , Maqungo S5 , 
McCollum G6 , Dey R7

1  MBChB; Orthopaedic Registrar, Department of Orthopaedics Surgery, Groote Schuur Hospital, University of Cape Town, South Africa 
² MD, PhD; Consultant, Department of Orthopaedics, Joint Research, OLVG Hospital Amsterdam, The Netherlands
3 MBChB; Orthopaedic Registrar, Department of Orthopaedics, Groote Schuur Hospital, University of Cape Town, South Africa
4 MBChB(UFS), Dip PEC, FC Orth(SA), MMed(Orth)(UCT); Consultant, Department of Orthopaedics, Groote Schuur Hospital, University of Cape Town, 
  South Africa
5 MBChB(Natal), FC Orth(SA), MMed(Orth)(UCT); Consultant, Department of Orthopaedics, Groote Schuur Hospital, University of Cape Town, 
 South Africa
6 MBChB, MMed(UCT), FC Orth(SA); Consultant, Department of Orthopaedics, Groote Schuur Hospital, University of Cape Town, South Africa
7 PhD; Post-doctoral Fellow, Faculty of Health Sciences, University of Cape Town, South Africa; Groote Schuur Hospital, University of Cape Town,  
 South Africa

Corresponding author: Dr P Panchoo, Department of Orthopaedics, Old Main Building, Groote Schuur Hospital, Anzio Road, Observatory,  
Cape Town, 7925, South Africa; tel: +27 (82) 815 0238; email: praveshpanchoo@gmail.com

https://orcid.org/0000-0003-1688-9214
https://orcid.org/0000-0001-9275-2151
https://orcid.org./0000-0002-5989-8383
https://orcid.org./0000-0002-8735-8341
https://orcid.org./0000-0002-1982-4654
https://orcid.org/0000-0002-3616-1995


Page 151Panchoo P et al. SA Orthop J 2020;19(3)

Introduction 

Lisfranc fracture dislocations also known as tarsometatarsal (TMT) 
fracture dislocation, consist of injuries to the bases of the five 
metatarsals, their articulations with the four distal tarsal bones, 
and disruption of the Lisfranc ligamentous complex.1-4 The main 
stabilising ligament of the midfoot (the Lisfranc ligament) runs 
on the plantar aspect of the foot from the lateral aspect of the 
medial cuneiform to the medial aspect of the base of the second 
metatarsal.1,3 It functions to stabilise the TMT articulation of the foot. 
Injury to the ligament and the TMT complex can lead to chronic 
pain, midfoot arthritis, decreased function, and loss of quality of 
life.1,5-7 These injuries include any combination of bony and ligament 
disruption to this complex, hence classifying the pattern of injury 
can be difficult. Computer tomography (CT) scans are therefore 
invaluable and virtually mandatory for all Lisfranc injuries. This is 
a relatively uncommon injury with an incidence of approximately 
0.2% of all fractures.1,6,8 Often Lisfranc injuries are missed in a 
polytraumatised patient, or in low-energy athletic injuries leading to 
poor functional outcomes.

Historically they have been associated with high-energy 
mechanisms such as motor vehicle accidents, falls or crush 
injuries.4,6,8 The treatment of these high-energy injuries has evolved 
over time with authors now agreeing that an anatomic reduction 
through open surgery is of critical importance.1-8

 
Recently, more 

research on Lisfranc injuries has focused on relatively low-energy 
mechanisms and Lisfranc injuries in athletes.7 

Anatomic reduction and rigid stabilisation are known to be the 
standard of care.1-8 Both open reduction and internal fixation (ORIF) 
and primary fusion have been evaluated as treatment options. 
With ORIF there is a high reoperation rate to remove the internal 
fixation or to perform a fusion of the midfoot due to ongoing midfoot 
arthritis.1-6 This has led some authors to believe that a primary fusion 
should be performed in the first setting. In a systematic review in 
2012, Sheibani-Rad et al.9 concluded that both methods were 
acceptable, but no consensus was reached as to which is superior. 

The aim of this study is to evaluate our series of primary fusions 
for high-energy Lisfranc injuries, looking specifically at time to 
union, non-union rates, reoperation rates and quality of reduction.

Methods 

After local institution review board approval, patients who under-
went primary fusion for Lisfranc injuries at Groote Schuur Hospital 
(GSH) between January 2013 and December 2018 were identified. 
Post-operative radiographs at six weeks, three months and six 
months were reviewed by two independent reviewers, JIW and PP, 
assessing quality of reduction, union rate and removal of implants. 
All radiographs were taken weight bearing and according to 
international standards. JIW is an orthopaedic surgeon from the 
Netherlands with two years of consultant experience. PP is a third-
year orthopaedic registrar at GSH. All measurements were further 
verified by the supervisor GM who is head of the foot and ankle 
department.

Figure 1. (a) First intermetatarsal angle (IMA) and medial cuneiform–first metatarsal angle; (b) coronal shift; (c) lateral Meary’s angle; and (d) sagittal shift 



Page 152 Panchoo P et al. SA Orthop J 2020;19(3)

Cases of high-energy Lisfranc injuries were retrieved from the 
orthopaedic surgery database REDCap®, and corresponding 
radiographs were analysed from our local picture archiving and 
communication system, iSite Intellispace® software. 

Injuries were classified using the Myerson classification of 
Lisfranc injuries.10 Union was assessed by the formation of cross-
trabeculation and the absence of fracture line on two views. 
Quality of reduction was assessed by measuring the following 
parameters11,12 on AP view: first intermetatarsal angle (IMA), medial 
cuneiform–first metatarsal angle, coronal shift. On lateral view: 
talus–first metatarsal angle (lateral Meary’s angle), sagittal shift 
(Figure 1). Any value outside of the normal range11,12 (Table I) was 
qualified as a malreduction/malunion. Cases of implant removal 
and reoperation were obtained from patients’ files. 

Surgical technique

A CT scan was performed prior to surgery in all patients to assess 
fracture displacement and intra-articular comminution. The surgical 
technique used is a dorsal two-incision approach to gain access 
to the medial and middle columns. The medial column incision is 
placed dorsally over the first TMT joint just medial to the extensor 
hallucis longus tendon. The lateral incision is centred between the 
second and third metatarsal to gain access to the second and third 
TMT joints and maintain an adequate soft tissue bridge. A third 
incision between the fourth and fifth metatarsal is used in case 
open reduction of the fourth and fifth TMT is needed. A single 
incision over the first TMT joint or between the second and third 

TMT joints is used in cases where the first and second, or second 
and third, TMT joints are fused. Our method of primary fusion was 
careful preparation of the joint by debriding the cartilage layer, 
reduction of the fracture dislocation, bone grafting of the defect 
with autograft taken from ipsilateral calcaneus followed by dorsal 
compression plating. The number of TMT joints fused depended 
on its involvement in the fracture pattern and its congruency. The 
first, second and third TMT joints were considered for fusion in the 
case of intra-articular comminution and joint incongruency. Fourth 
and fifth TMT joints were never considered for fusion; no cases 
of intra-articular fractures involving these joints were identified. 
Subluxation of the fourth and fifth TMT joints were addressed with 
temporary Kirschner wires removed at six weeks. All surgeries 
were performed by the foot-and-ankle consultant as primary 
surgeon. Patients were immobilised in a below-knee circular cast 
for six weeks and kept non-weight bearing for at least 12 weeks 
until radiological evidence of union.

Results

Between 2013 and 2018, 17 cases of Lisfranc injuries were iden-
tified. Twelve of them underwent primary fusion and five cases 
were excluded (in one case the file could not be retrieved, two were 
cases of closed reduction and percutaneous screw fixation, and two 
underwent open reduction and internal fixation). The study group 
comprised ten male and two female patients (Figure 2a), with a 
mean age of 38.9 years (range 18–60) (Figure 2b). All patients were 
involved in high-energy injury mechanisms, the commonest being 

Table I: Definition and normal range of measured parameters

Anteroposterior (AP) and lateral weight-bearing 
radiographs

Definition11,12 Normal range11,12

First intermetatarsal angle (AP view) Angle formed by the line drawn bisecting the first metatarsal and 
bisecting the second metatarsal

6–10°

Medial cuneiform–first metatarsal angle (AP view) Angle formed by the bisection of the medial cuneiform and the 
anatomic axis of the first metatarsal

16–20°

Lateral Meary’s angle (lateral view) Angle formed by the bisection of the talar neck and the anatomic 
axis of the first metatarsal 

2–10°

Sagittal shift (lateral view) Superior translation of second metatarsal with respect to the 
anterior cortex of the middle cuneiform

<2 mm

Coronal shift (AP view) Lateral translation of the second metatarsal with respect to the 
medial cortex of the middle cuneiform

<2 mm

Male

Female

a

18-30            31-40            41-50             51-60

7

6

5

4

3

2

1

0

b

Figure 2. (a) Sex demographics of the patient group used for this study; (b) distribution of patients in various age groups

17%

83%

N
u

m
b

e
rs

Age groups (years)



Page 153Panchoo P et al. SA Orthop J 2020;19(3)

fall from height, followed by pedestrian vehicle accident (Figure 3). 
Most of our cases were Myerson10 type A lateral, representing 

66%. The remaining were one case each of type A medial, B1, B2 
and C2 respectively.

Seven patients (58%) underwent fusion of the first, second 
and third TMT joints; the first and second TMT joints were fused 
in only one case (8%) and the second and third TMT joints fused 
in four cases (33%). Acceptable reduction was observed in nine 
cases (75%); three cases (25%) of malreduction were noted, 
among which one patient had pre-existing hallux valgus which can 
give false negative values in measuring the IMA. Our measured 
reduction parameters for all the patients is shown in Table II. 
Average reduction parameters in the well-reduced group were as 
follows (Table III): IMA of 8.05°, medial cuneiform–first metatarsal 
angle of 16.9°, lateral Meary’s angle 5.9°, coronal shift 0.7 mm. Only 

one patient had a sagittal shift of 1.6 mm; the remaining radiographs 
had no sagittal shift. Average time to union in our series was 84 
days, and no case of non-union was identified (100% union rate). 
We also compared the number of TMT joints fused to the quality of 
reduction (Table IV). We found better results in cases where either 
the first, second and third metatarsals (86%) or second and third 
metatarsals were fused (75%). There was one case of fusion of only 
first and second metatarsals which was malreduced. One patient 
(8%) had removal of implants for prominent hardware. 

Discussion 

The most common complication following ORIF is post-traumatic 
osteoarthritis (PTOA) with rates estimated between 20% and 
50%.13 Teng et al.14 performed gait analysis on patients following 
ORIF and demonstrated, despite restoration of normal anatomy 
and gait mechanics, patients still had poor American Orthopedic 
Foot and Ankle Score (AOFAS) midfoot scores. In the setting of 
PTOA and continued pain, secondary arthrodesis was used as 
a salvage procedure. In a prospective randomised study, Ly and 
Coetzee15 compared ORIF versus primary fusion in primarily 
ligamentous Lisfranc injuries. Seventy-five per cent of patients who 
underwent ORIF had some loss of correction and degenerative 
joint changes at the final follow-up visit at a mean of 42.5 months 
post-operatively. They concluded that primary fusion provides 

Fall from height

Pedestrian vehicle accident

Motor vehicle accident

Assault

Figure 3. Mechanism of injury

Table II: Measurements for all patients (the well-reduced cases are highlighted in blue and the malreduced cases in yellow)

 Patient no. IMA (degrees) Medial cuneiform–first metatarsal 
angle (degrees)

Meary’s angle (degrees) Sagittal shift (mm) Coronal shift (mm)

1 5.7 16.5 5.6 0 0

2 6.2 16.1 6.9 0 0

3 9.3 17.4 5.5 0 1.2

4 8.5 16.1 8.2 0 0.8

5 8.9 16.2 8.6 1.6 1.4

6 6.9 17.6 8.6 0 0

7 9.4 19.8 4.3 0 1.5

8 9.8 16.2 2.1 0 0

9 7.8 16.5 3.8 0 1.5

10 20.9 26.9 5.8 0 1.5

11 12.4 30.2 7.5 1.0 1.2

12 13.5 23.0 13.6 4.2 0

Table III: Average reduction parameters

Normal 
range10,11

Average measured value

First intermetatarsal 
angle 

6–10° 8.1°

Medial cuneiform–
first metatarsal angle

16–20° 16.9° 

Lateral Meary’s angle 2–10° 6.0°

Sagittal shift <2 mm Only one case of 1.6 mm shift

Coronal shift <2 mm 0.7 

Table IV: Effect of the number of bones fused on the quality of reduction

Fused bones Number 
of cases

Improper 
reduction

Proper 
reduction

First, second and third TMT 7 1 (14%) 6 (86%)

First and second TMT 1 1 (100%) 0

Second and third TMT 4 1 (25%) 3 (75%)

8%

42%

33%

17%



Page 154 Panchoo P et al. SA Orthop J 2020;19(3)

better short- and medium-term outcomes than ORIF for primarily 
ligamentous injuries. Sheibani-Rad et al.9 performed a qualitative, 
systematic review comparing primary fusion and ORIF and found 
six reports with a combined total of 193 patients. The one-year 
follow-up AOFAS score for the ORIF group was 72.5 versus 88.0 
for the primary fusion group. They concluded that both procedures 
yield satisfactory results, but primary fusion might have a slight 
advantage in clinical outcomes.9,16 In most of these studies, the 
complexity and energy of the injury has not been stated. Low-
energy athletic injuries have been grouped with high-energy 
injuries, which we believe have a different prognosis if a primary 
fusion is not performed.

Our study did not compare outcome of ORIF versus primary 
fusion, but we analysed the results of patients who had primary 
fusion in high-energy Lisfranc fractures. As described in the 
literature, our series of patients showed good results in terms of 
reduction (75%) and reasonable time to union (84 days). Twenty-
five per cent of malreduction was observed but this figure did not 
necessarily correlate with a poor clinical result. Despite much effort 
to trace the patients, only two responded and came for follow-up. 
We calculated the AOFAS scores for these two patients and both 
scored 90/100. The remaining patients were untraceable. Only one 
case of implant removal (8%) was identified due to symptomatic 
hardware. The latter correlated with the low revision or repeat 
surgery described in literature. Better quality of reduction was 
observed with fusion of the first, second and third TMT and second 
and third TMT joints (86% and 75% respectively). The first TMT 
joint frequently involves primarily ligamentous injury with minimal 
fractures of the first metatarsal base and medial cuneiform. Fusion 
of the first TMT joint stabilises the medial column and acts as a 
buttress to further stabilise adjacent fracture-dislocation injuries.16 

A reason for the 25% malreduction rate can be attributed to 
significant comminution, bone loss and gross instability. There may 
have been some cases where the medial column was unstable but 
not included in the fusion leading to worsening of the reduction 
parameters mentioned. Figure 4 illustrates a case of high-energy 
Lisfranc injury operated at GSH with fusion of the first, second and 

third TMT joints appropriately reduced.
In conclusion, our data suggests that primary fusion may be 

a viable option in these high-energy Lisfranc injuries with good 
radiological outcome, 100% union and low reoperation rate. 
The malreduction rate may be improved by including the medial 
column in the fusion construct. Our study was limited by a small 
population size and the lack of clinical parameters to compare 
with the radiological results. However, this is a short-term study 
and the long-term consequences of arthrodesis in young, athletic 
patients remain unknown. Long-term, prospective studies of high-
energy injuries with adequate clinical follow-up would be beneficial 
to establish and evaluate indications for primary fusion in this 
population. 

Ethics statement
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. Prior to commencement of the study, ethical 
approval was obtained from the following ethical review board: Human Research 
Ethics Committee, HREC REF: 446/2019. This article does not contain any studies with 
human participants or animals performed by any of the authors.

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 
PP: Study conceptualisation, manuscript preparation, data capturing, data analysis, 
manuscript revision
JIW: Data capture, manuscript revision
VB: Study conceptualisation, manuscript revision
ML: Data capture, manuscript preparation
SM: Data capture, manuscript revision
GM: Study conceptualisation, data capture, manuscript revision
RD: Data analysis, manuscript revisions

ORCID
Panchoo P  https://orcid.org/0000-0003-1688-9214
Boskovic V  https://orcid.org/0000-0001-9275-2151

Pre-operative

Six months post-operative

Figure 4. Pre- and post-reduction radiographic evidence of a well-reduced Lisfranc injury

https://orcid.org/0000-0003-1688-9214
https://orcid.org/0000-0001-9275-2151


Page 155Panchoo P et al. SA Orthop J 2020;19(3)

Laubscher M  https://orcid.org./0000-0002-5989-8383
Maqungo S  https://orcid.org./0000-0002-8735-8341
McCollum G  https://orcid.org./0000-0002-1982-4654
Dey R  https://orcid.org/0000-0002-3616-1995

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https://orcid.org./0000-0002-5989-8383
https://orcid.org./0000-0002-8735-8341
https://orcid.org./0000-0002-1982-4654
https://orcid.org/0000-0002-3616-1995
https://www.ncbi.nlm.nih.gov/pubmed/?term=Pigott%20MT%5BAuthor%5D&cauthor=true&cauthor_uid=30666884
https://www.ncbi.nlm.nih.gov/pubmed/?term=Shah%20R%5BAuthor%5D&cauthor=true&cauthor_uid=30666884
https://www.ncbi.nlm.nih.gov/pubmed/?term=Chan%20J%5BAuthor%5D&cauthor=true&cauthor_uid=30666884
https://www.ncbi.nlm.nih.gov/pmc/articles/PMC2989076/
https://www.ncbi.nlm.nih.gov/pubmed/26359620
https://www.ncbi.nlm.nih.gov/pubmed/26359620
https://www.ncbi.nlm.nih.gov/pubmed/26359620
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