South African Orthopaedic Journal

TRAUMA AND GENERAL ORTHOPAEDICS

DOI 10.17159/2309-8309/2021/v20n2a1 Gerafa M et al. SA Orthop J 2021;20(2)

Citation: Gerafa M, Jakoet S, 
Van Heukelum M, Le Roux N, 
Van der Merwe S, Makhubalo O, 
Du Preez G, Burger M, Ferreira 
N. Treatment outcomes of civilian 
gunshot tibia fractures at a major 
trauma centre. SA Orthop J 
2021;20(2):71-75. http://dx.doi.
org/10.17159/2309-8309/2021/
v20n2a1

Editor: Prof. Leonard C Marais, 
University of KwaZulu-Natal, 
Durban, South Africa

Received: July 2020

Accepted: November 2020

Published: May 2021

Copyright: © 2021 Gerafa M. 
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: The authors 
declare they have no conflicts 
of interest that are directly or 
indirectly related to this research.

Abstract
Background
The aim of this retrospective longitudinal study was to describe the overall burden and outcomes 
of surgically managed gunshot tibia fractures at a major trauma centre. Secondary objectives 
were to identify possible risk factors for complications including non-union and infection and to 
highlight any differences in outcomes between treatment modalities.

Methods
All consecutive patients who sustained gunshot injuries to the tibia between January 2014 and 
December 2017 including children and multiple gunshots injuries were considered for inclusion. 
Information related to patient demographics, injury characteristics, treatment information and 
treatment outcomes with respect to rate of fracture union and occurrence of infection were 
obtained from patient records. All patients with insufficient medical records were excluded.

Results
The records of 197 patients who sustained gunshot tibia fractures were reviewed. The mean 
follow-up was 4.1 months (interquartile range [IQR] 2.5–6.8). The majority of cases were young 
males (89%) with a mean age of 29.2±10.2 years. Extra-articular diaphyseal fractures were 
observed in the majority of cases (91%). Definitive treatment included formal debridement in 
theatre and plaster cast immobilisation (44%), intramedullary nail fixation (27%), circular external 
fixation (22%) and plate fixation (7%). The study revealed an overall fracture-related infection 
(FRI) rate of 11% and bone union rate of 91%. Circular external fixation showed the lowest 
fracture union rate (86%) and highest FRI rate (21%) of the modalities included in this study. No 
associations between independent risk factors and presence of complications were identified.

Conclusion
The study reports encouraging outcomes for tibia fractures caused by civilian gunshot injuries. 
Various definitive surgical stabilisation techniques showed high proportions of union and low 
burden of FRI.

Level of evidence: Level 4

Keywords: tibia, gunshot, fracture, outcome

Treatment outcomes of civilian gunshot tibia fractures at  
a major trauma centre 
Muaad Gerafa,  Shafique Jakoet, Marcus van Heukelum, Nicholas le Roux, Simone van der Merwe,  
Obakeng Makhubalo, Gian du Preez, Marilize Burger, Nando Ferreira*

Division of Orthopaedic Surgery, Department of Surgical Sciences, Faculty of Medicine and Health Sciences, Stellenbosch University, Cape Town,  
South Africa

*Corresponding author: drferreiran@gmail.com 

Introduction
Trauma accounted for 8.5% of global deaths as indicated in the 
2015 Global Burden of Disease study.1 Trauma, specifically, can 
be classified into intentional injuries that occurred due to inter-
personal or collective violence and self-inflicted injury, as well as 
unintentional injuries including motor vehicle collisions, falls and 
burns. The United Nations Office on Drugs and Crime (UNODC) 
has ranked South Africa (SA) 11th in terms of violence, with a 
homicide rate of 31.1 per 100 000 people.2 A 2019 study by Zaidi  
et al. highlighted the high monthly load of trauma at a district 
hospital in the Western Cape province of South Africa in which 
44.4% of trauma cases were attributed to interpersonal violence, 
where 7.2% of these were firearm-related.3 

Insight into the South African burden of gunshot-related injuries 
on orthopaedic services was reported by Engelmann et al. who 
reviewed 294 extremity gunshot injuries seen at a tertiary trauma 
centre in Cape Town over an 11-month period between June 2015 
and April 2016, and reported that tibia fractures accounted for 
the majority (42.2%) of lower extremity injuries.4 A retrospective 
study by Martin et al. reviewed 111 patients at a tertiary level 
hospital who had sustained 147 gunshot-induced fractures over a 
12-month period. The authors reported that the majority of these 
injuries involved the lower extremity, and 95% of these patients 
inflicted with lower extremity gunshot-induced fractures required 
orthopaedic procedures at an average cost exceeding 13 times the 
annual average per patient afforded by the South African public 
health sector.5 In agreement with this, a recent study from a tertiary 

https://orcid.org/0000-0002-6028-0759
https://orcid.org/0000-0002-0567-3373


Page 72 Gerafa M et al. SA Orthop J 2021;20(2)

hospital in South Africa reported a total of 1 449 gunshot-related 
orthopaedic fractures over a four-year period, resulting in a total 
cost of more than ZAR 50 million to the healthcare system.6

Gunshot-induced tibia fractures are often associated with a 
myriad of complications presenting greater challenges to clinicians. 
Gunshots involve the transfer of blast energy to the bone and 
soft tissue resulting in cavitary tissue damage and a large zone 
of injury.8 Further, the risk of infection, compartment syndrome, 
nerve palsies, delayed union or non-union are increased due to 
the subcutaneous location of the tibia. Moreover, poor correlation 
between external wound size and degree of underlying tissue 
damage may lead to an underestimation of the injury severity.8

Several controversies regarding the management of gunshot-
induced tibia fractures persist as a result of the heterogeneity 
of these injuries. Management of these injuries can range from 
conservative management to formal debridement and skeletal 
stabilisation either in a single setting, or as a staged approach.9 
Advantages of temporary monolateral external fixation include 
bone stabilisation, and easy access for wound care.10 Conversely, 
problems associated with monolateral external fixation include 
pin-site infection and loss of stability during long-term use.10 In 
comparison, studies have reported the efficacy of formal debride-
ment and internal fixation in the same sitting, demonstrating the 
advantages such as access to soft tissue and low risk of deep 
infection.11 These reports add to the controversy regarding the 
management of gunshot-induced fractures and highlight the lack 
of evidence-based treatment guidelines.

The present study aims to describe the treatment outcomes 
of civilian gunshot tibia fractures at a major trauma centre.12 
Secondary objectives were to identify possible risk factors for 
complications, including non-union and fracture-related infection 
(FRI).

Methods
A retrospective review of clinical records and serial radiographs of 
all patients who sustained gunshot tibia fractures between January 
2014 and December 2017 was conducted. Institutional ethics 
committee approval and hospital board approval was obtained 
prior to commencement of data collection. 

Medical records of all adult and paediatric patients presenting 
with tibia fractures as a result of gunshot injuries in the study 
period were reviewed by the authors. Demographic information 
of all included patients was recorded, and patient records were 
assessed to identify the extent of soft tissue injury and presence 
of associated injuries. Patients that did not require surgical inter-
vention, as well as all patients with incomplete medical records, 
were excluded. Tibia fractures were classified according to the 
Muller AO Classification13 as intra-articular (AO 41B-C and 43B-C), 
metaphyseal (AO 41A and 43A) and diaphyseal (AO 42A-C) for 
analysis purposes.

As per international protocol, intravenous antibiotics (cephazolin) 
were administered on presentation14 and the treatment modality 
used, as well as the timing thereof, was recorded. Temporary 
external fixation was used for damage control and patients with 
vascular injuries. For definitive management, interlocked in-
tramedullary nailing (IMN) was used for diaphyseal tibia fractures 
where the soft tissue envelope was amenable to primary closure, 
while intra-articular and metaphyseal fractures were most often 
managed with plate fixation. Fine wire circular external fixation was 
used for metaphyseal and intra-articular fractures with extensive 
soft tissue damage or where delays to surgery were encountered, 
due to the trauma burden at our institution.

Radiographs were reviewed to determine time to radiological 
union based on the Radiographic Union Score for Tibia fractures 

(RUST Score).15 The presence of an FRI was deemed ‘suggestive’ 
or ‘confirmed’ using the guidelines outlined in the consensus 
document of Metsemakers et al.16 Minor complications, such as the 
presence of cast-associated pressure sores or pin-site infections, 
were not recorded. 

Data was analysed using STATISTICA version 13.5 (StatSoft 
Inc., Tulsa, OK, USA) and data is presented as means ± standard 
deviations or median (interquartile range [IQR]), depending on the 
distribution, while categorical data is presented as frequencies 
and counts. Associations between risk factors, including age, sex, 
HIV status, injury location and delay to surgical management, 
and known outcomes, specifically presence of i) non-union or  
ii) infection, were investigated using an independent t-test or 
Mann–Whitney U test for continuous data, while a Pearson’s chi-
square test or a Fisher’s exact test was used for categorical data. 

Table I: Demographic information of included patients 

  n=197

Age (years) (28.8±10.4) (197)

Sex

Male 89% (175)

Female 11% (22)

HIV status

Positive 34% (67)

Negative 28% (56)

Unknown 38% (74)
Data is expressed as means ± standard deviations or as frequencies, with counts 
indicated in parentheses. 

Table II: Injury characteristics of included patients

  n=197

Affected side

Left 50% (99)

Right 50% (98)

Anatomical site

Tibia 96% (189)

Tibia and fibula 4% (7)

Tibia and patella 0.5% (1)

Intra-articular

No 95% (187)

Yes 5% (10)

AO classification (tibia fracture)

Diaphysis 91% (179)

    42B3 71% (140)

    42A3 15% (30)

    42B2 5% (9)

Proximal metaphysis 8% (16)

    41C2 4% (8)

    41A3 4% (8)

Distal metaphysis 1% (2)

    43C2 0.5% (1)

    43C3 0.5% (1)

Data is expressed as frequencies with counts in parentheses.



Page 73Gerafa M et al. SA Orthop J 2021;20(2)

Results
A total of 213 patients who sustained gunshot tibia injuries were 
reviewed. Sixteen patients who did not require surgery or had 
incomplete medical records were excluded. The final cohort 
therefore included 175 male patients (89%) and 22 female patients 
(11%) with a mean age of 28.8±10.4 years (Table I). Isolated tibial 
injures represented 96% of cases (n=189). The majority of injuries 
(91%, n=179) were diaphyseal fractures while 9% (n=18) were 
peri-articular injuries (Table II).

Patients underwent surgery at a median of 2.0 (IQR 2.0–5.0) 
days following admission. The majority of fractures were managed 
by fixation including IMN fixation (27%, n=53), circulator external 
fixation (22%, n=44), and plate fixation (7%, n=14) while remaining 
fractures were managed through formal debridement and plaster 
cast immobilisation (44%, n=86). Definitive soft tissue and fracture 
management was performed during a single theatre visit in all 
patients. Median length of stay in hospital was 6.0 (IQR 4.0–9.0) 
days. Patients were followed up for a median of 4.1 (IQR 2.5–
6.8) months. Five (3%) patients were lost to follow-up prior to 
confirmation of union (Table III).

Bony union was achieved in 179 patients (91%) after the initial 
fixation. A total of 21 patients (11%) in the entire cohort developed 
FRIs (Table IV). No associations between demographic or 
treatment-related risk factors and treatment outcomes were 
observed (Table V).

All definitive fixation procedures showed high proportions of 
union, with circular external fixators having the lowest union rate 
(86%). Similarly, the presence of FRI was highest in the circular 
fixation group (21%) (Table VI).

Discussion
The first finding of this study was the demographic sample and the 
predominant involvement of young males (89% male with a mean 
age of 29.2±10.2 years), which is similar to previous published 
reports on orthopaedic injuries following civilian gunshots.3,6,8 
A recent study conducted in South Africa reported a higher rate 
of intentional and gang-related violence together with the use of 
alcohol and illegal drugs among young, gunshot-injured males.5 
While we did not test patients for alcohol or illegal drugs in the 
present study, our finding, together with the previous reports, 
again highlights this group of individuals to be a potential target for 
intervention in the future.

The second important finding relates to our individualised ap-
proach to fracture management that produced an overall union  

Table III: Treatment information of included patients 

 n=197

Time delay (admission to surgery) (days) 2 (2–5) (186)

Admitted to hospital 100% (197)

Admitted to ICU 3% (6)

Temporary external fixator 8% (15)

Definitive procedure

        Debridement and plaster cast 44% (86)

        Intramedullary nail 27% (53)

        Circular external fixator 22% (44)

        Plate fixation 7% (14)

Hospital stay (days) 6 (4–9) (186)

Follow-up (months) 4.1 (2.5–6.8) (166)

Lost to follow-up before confirming union 3% (5)
Non-missing data is reported as medians (interquartile ranges) or as frequencies, 
with counts indicated in parentheses. ICU: intensive care unit

Table IV: Treatment outcomes of included patients 

  n=197

Fracture healing

Union 91% (179)

Non-union 7% (13)

Unknown 3% (5)

Fracture-related infection

No 87% (172)

Yes 11% (21)

Unknown 2% (4)
Non-missing data is reported as medians (interquartile ranges) or frequencies, 
with counts indicated in parentheses. Outcomes of patients that were lost to 
follow-up are reported as ‘unknown’.

Table V: Demographic-, clinical- and treatment-specific risk factors for non-union and infection
Risk factor Union* (n=179) Non-union* (n=13) p-value No infection** (n=172) Infection** (n=21) p-value

Patient demographics

Age (years) 28.4±10.4 (179) 32.7±10.1 (13) 0.153 28.5±10.1 (172) 32.3±10.0 (21) 0.113

Sex (% male) 88.3 (158) 100.0 (13) 0.367 87.2 (150) 100.0 (21) 0.139

HIV status  
% pos 
% neg 
% unknown

32.4 (58) 
29.6 (53) 
38.0 (68)

 
53.9 (7) 
15.4 (2) 
30.8 (4)

0.263
 

31.4 (54) 
30.8 (53) 
37.8 (65)

 
476 (10) 
14.3 (3) 
38.1 (8)

0.197

Injury characteristics

Injury location 
% proximal 
% midshaft 
% distal

 
7.8 (14) 

91.6 (164) 
0.56 (1)

 
0.0 (0) 

92.3 (12) 
 7.7 (1)

>0.999#
 

7.6 (13) 
 91.9 (158) 

 0.6 (1)

 
9.5 (2)  

85.7 (18) 
4.8 (1)

0.406#

Intra-articular (% yes) 5.0 (9) 7.7 (1) 0.513 5.2 (9) 4.8 (1) >0.999

Treatment characteristics

Time delay (days) 2.0 (2.0–5.0) (174) 3.0 (2.0–5.0) (13) 0.361 2.0 (2.0–4.0) (166) 3.0 (2.0–5.0) (21) 0. 457
Non-missing data is reported as mean ± standard deviations, medians (interquartile ranges) or frequencies with counts in parentheses. *Five patients had an unknown union 
outcome; **Four patients had an unknown infection outcome – patients with unknown outcomes were excluded from the analysis. #Fisher’s exact test for proximal and distal vs 
midshaft fractures



Page 74 Gerafa M et al. SA Orthop J 2021;20(2)

rate of 91% and an FRI rate of 11%. A recent retrospective study 
by Metcalf et al. investigated the surgical outcome of tibia fractures 
managed with intramedullary nail fixation and observed a 30% non-
union rate and 9% infection rate for civilian gunshot tibia fractures 
which was comparable to our findings.17 In terms of length of stay, 
the current study results (median of 6.0 days) were slightly less 
than that reported by Abghari et al. who investigated the outcome 
of civilian gunshot injuries and reported a median length of stay 
of 7.1 days for patients who sustained lower extremity fractures.18

There were no associations noted between the demographic 
or treatment-specific risk factors and the clinical outcomes. No 
associations between clinical outcome and HIV status were 
observed. Very few studies have investigated the association 
between HIV and bone healing and this relationship remains 
poorly understood and unclear. An ongoing study investigating the 
association between union and HIV infection is nearing completion, 
and should provide important information on the effect of HIV on 
bone healing.19

Patients in the present study waited a median of two days for 
surgery (IQR 2–5 days). This delay is attributed to the high burden 
of trauma cases at South African hospitals which hampers the ability 
of providing immediate surgery on admission.3 Interestingly, the 
delay to surgery was not associated with an increased complication 
rate. Kale et al. had previously reported an infection rate of 11.4% 
for patients with open fractures, most commonly arising from motor 
vehicle accidents, that received wound closure within a week of 
admission, compared to 77.8% for patients suffering infection 
when they had wound closure after two weeks, suggesting an 
association between delay in surgery and rate of infection.20 The 
lack of an association in the present study could potentially be as 
a result of the different injury mechanism, faster median time to 
surgery, or the fact that all surgeries were performed in a single 
setting, rather than in a staged process. Ultimately, it is important to 
keep in mind that risk of infection is influenced by multiple factors.

Various definitive skeletal stabilisation procedures were included 
in this study. Formal debridement followed by cast immobilisation, 
as well as plate fixation, showed the optimal union and lowest 
infection rates in the present study. There was no association of 
FRI and union rates with length of stay. Minor complications, such 
as the presence of pressure sores, were not recorded as part of 

this investigation. Obvious selection bias for cast immobilisation 
of stable fracture patterns, isolated fractures, low energy transfer 
injuries and lower grade wounds should, however, be borne in 
mind when interpreting these results. For this reason, no statistical 
analysis was performed to investigate associations between 
treatment modality and outcome, because this relationship 
would be confounded by the differences in injury characteristics 
which guides clinical decision-making with regard to treatment 
modalities. IMN fixation showed outcomes comparable to a 
previous publication by Hilton et al. who reported a 76.9% initial 
union rate following intermedullary nailing for gunshot tibial shaft 
fractures, with three patients developing osteomyelitis.8 The union 
rate observed in the present study for IMN was 91%. 

Circular external fixation was generally reserved for patients 
who had complex fractures, significant soft tissue damage and 
delays to surgery, and showed lowest union rate when compared 
to other definitive fixation methods. A study conducted by Van der 
Walt and Ferreira however reported higher union rates of 100% 
using circular external fixators in their gunshot-induced tibia 
fracture sample.21 The lower union rate with the use of circular 
external fixation observed in the present study may be attributed 
to the injury characteristics and delay in treatment for patients who 
were managed with this fixation modality. Furthermore, circular 
external fixation showed the highest FRI rates when compared 
to other definitive fixation methods, keeping in mind that circular 
fixation was reserved for patients with significant soft tissue injury 
or delay to surgery. FRI rates were higher in the IMN group (13%) 
compared to plate fixation (7%), but it is important to keep in mind 
that nail fixation was generally reserved for diaphyseal fractures 
compared to plate fixation, which was typically employed for 
metaphyseal injuries. Unfortunately, there is very limited clinical 
data specifically investigating tibial plate fixation following low-
energy gunshot injuries. Sitnik and Beletsky reported an 8.75% 
infection rate in plate fixation in an investigation of 80 patients. This 
series, however, only included a single gunshot wound case and is 
therefore not directly comparable to the result of the present study, 
where a 7% infection rate was observed.22 It is again important to 
emphasise that risk of infection is influenced by multiple factors 
and as such, future experimental studies, where bias is largely 
removed, should investigate this finding further.

The major study limitations include the retrospective design 
and single centre cohort which resulted in, albeit a large cohort 
compared to previous reports, too small a sample to detect large 
differences between sub-groups. The short follow-up period 
reported in this investigation is another limitation: we report a 
median follow-up time of 4.1 months, while these injuries should 
ideally be seen over a longer follow-up period. Lost to follow-up 
is however a notorious problem in our setting that has previously 
been described by Badenhorst et al.,23 and we believe that the 
results of the study are still meaningful, regardless of this limitation. 
Finally, the observational nature of the study includes an inherent 
selection bias in the outcomes observed for the different treatment 
modalities used where some modalities were more likely to be used 
in more complex fractures than others. Subsequently, we could not 
comment on the risk of specific outcomes following treatment with 
specific devices. 

Conclusion
Tibial fractures caused by civilian gunshots remain challenging in-
juries to manage. This study found that an individualised approach 
to the treatment of these fractures can produce a satisfactory union 
rate with minimal complications if managed during a single stage 
by intramedullary nails, plate fixation or cast immobilisation. While 
the complications were higher in patients managed with circular 

Table VI: Outcomes related to union and infection of all patients per 
type of definitive treatment

Definitive procedure
Union
% (n)

Infection
% (n)

Debridement and POP (n=86)

Yes 93% (80) 5% (4)

No 4% (3) 92% (79)

Unknown 4% (3) 4% (3)

Intramedullary nail (n=53)

Yes 91% (48) 13% (7)

No 6% (3) 85% (45)

Unknown 4% (2) 2% (1)

Circular fixator (n=44)

Yes 86% (38) 21% (9)

No 14% (6) 80% (35)

Plate fixation (n=14)

Yes 93% (13) 7% (1)

No 7% (1) 93% (13)
Data is presented as frequencies with counts indicated in parentheses. POP: 
plaster of Paris



Page 75Gerafa M et al. SA Orthop J 2021;20(2)

external fixation, these devices were generally reserved for more 
severe injuries. 

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 for this study was obtained from the Stellenbosch University Ethics 
Committee, S18/07/139.
All procedures were in accordance with the ethical standards of the responsible 
committee on human experimentation (institutional and national) and with the Helsinki 
Declaration of 1975, as revised in 2008. 

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 
MG: Study conceptualisation, data capture, data analysis, first draft preparation, 
manuscript revision and approval of final manuscript 
SJ: Data capture and approval of final manuscript
MvH: Data capture and approval of final manuscript
NlR: Data capture and approval of final manuscript
SvdM: Data capture and approval of final manuscript
OM: Data capture and approval of final manuscript
GdP: Data capture and approval of final manuscript
MB: Data analysis, manuscript revision and approval of final manuscript 
NF: Study conceptualisation, data analysis, first draft preparation, manuscript revision 
and approval of final manuscript 

ORCID
Gerafa M  https://orcid.org/0000-0002-6028-0759
Jakoet S  https://orcid.org/0000-0002-0009-2203
Van Heukelum M  https://orcid.org/0000-0001-9160-7796
Le Roux N  https://orcid.org/0000-0001-9115-7254
Van der Merwe S  https://orcid.org/0000-0001-6892-4582
Makhubalo O  https://orcid.org/0000-0003-0085-0876
Burger M  https://orcid.org/0000-0003-2831-4960
Ferreira N  https://orcid.org/0000-0002-0567-3373

References
1. Nunes ED. United Nations Office on Drugs and Crime (UNODC). Global study 

on homicide: trends, context, data. Vienna: UNODC; 2011. Ciência & Saúde 
Coletiva. 2012;17:3447-9.

2. Haagsma JA, Graetz N, Bolliger I, et al. The global burden of injury: incidence, 
mortality, disability-adjusted life years and time trends from the Global Burden 
of Disease study 2013. Inj Prev. 2016;122:3-18. https://doi.org/10.1136/
injuryprev-2015-041616.

3. Zaidi AA, Dixon J, Lupez K, et al. The burden of trauma at a district hospital in 
the Western Cape Province of South Africa: prospective observational study. 
Afr J Emerg Med. 2019:191:4-20. https://doi.org/10.1016/j.afjem.2019.01.007.

4. Engelmann EW, Maqungo S, Laubscher Μ, et al. Epidemiology and injury 
severity of 294 extremity gunshot wounds in ten months: a report from 
the Cape Town trauma registry. SA Orthop J. 2019;182:31-6. https://doi.
org/10.17159/2309-8309/2019/v18n2a3.

5. Martin C, Thiart G, McCollum G, Roche S, Maqungo S. The burden of gunshot 
injuries on orthopaedic healthcare resources in South Africa: retrospective 
review. S Afr Med J. 2017;107:626-30. https://doi.org/10.7196/SAMJ.2017.
v107i7.12257.

6. Jakoet MS, Burger M, Van Heukelum M, et al. The epidemiology and 
orthopaedic burden of civilian gunshot injuries over a four-year period at a level 
one trauma unit in Cape Town, South Africa: a retrospective review. Int Orthop. 
2020;121:8. https://doi.org/10.1007/s00264-020-04723-6.

7. Sathiyakumar V, Thakore RV, Stinner DJ, et al. Gunshot-induced fractures 
of the extremities: a review of antibiotic and debridement practices. 
Curr Rev Musculoskelet Med. 2015;182:76-89. https://doi.org/10.1007/
s12178-015-9284-9.

8. Hilton TL, Kruger N, Wiese KR, Martin CW, Maqungo S. Gunshot tibia fractures 
treated with intramedullary nailing: A single centre retrospective review. SA 
Orthop J. 2017;163:2-8. https://doi.org/10.17159/2309-8309/2017/v16n1a4.

9. Cross III WW, Swiontkowski MF. Treatment principles in the 
management of open fractures. Indian J Orthop. 2008;37-7. https://doi.
org/10.4103/0019-5413.43373.

10. Fang X, Jiang L, Wang Y, Zhao L. Treatment of Gustilo grade III tibial fractures 
with unreamed intramedullary nailing versus external fixator: a meta-analysis. 
Med Sci Monit. 2012;18(4):49-56. https://doi.org/10.12659/msm.882610.

11. Su CA, Nguyen MP, O’Donnell JA, Vallier HA. Outcomes of tibia shaft fractures 
caused by low energy gunshot wounds. Injury. 2018;49(7):1348-52. https://doi.
org/10.1016/j.injury.2018.05.006.

12. Hardcastle T. The 11 P’s of an Afrocentric trauma system for South Africa: time 
for action. S Afr Med J. 2011;101(3):160-2. https://doi.org/10.7196/SAMJ.4578.

13. Müller ME, Nazarian S, Koch P. The comprehensive classification of fractures 
of long bones. Springer-Verlag: Berlin; 1990.

14. Papasoulis E, Patzakis MJ, Zalavras CG. Antibiotics in the treatment of 
low-velocity gunshot-induced fractures: a systematic literature review. 
Clin Orthop Relat Res. 2013;471-12:3937-44. https://doi.org/10.1007/
s11999-013-2884-z. 

15. Whelan DB, Bhandari M, Stephen D, et al. Development of the radiographic 
union score for tibial fractures for the assessment of tibial fracture healing 
after intramedullary fixation: retrospective review. J Trauma Acute Care Surg. 
2010;168:629-32. https://doi.org/10.1097/TA.0b013e3181a7c16d.

16. Metsemakers WJ, Morgenstern M, McNally MA, et al. Fracture related 
infection: a consensus on definition from an international expert group. Injury. 
2018;149:505-10. https://doi.org/10.1016/j.injury.2017.08.040.

17. Metcalf KB, Smith EJ, Wetzel RJ, Sontich JK, Ochenjele G. Comparison of 
clinical outcomes after intramedullary fixation of tibia fractures caused by blunt 
trauma and civilian gunshot wounds: a retrospective review. J Orthop Trauma. 
2020;134:208-13. https://doi.org/10.1097/BOT.000000000000170.

18. Abghari M, Monroy A, Schubl S, Davidovitch R, Egol K. Outcomes following 
low-energy civilian gunshot wound trauma to the lower extremities: results of a 
standard protocol at an urban trauma center. Iowa Orthop J. 2015;35:65-9.

19. Graham SM, Harrison WJ, Lalloo DG, et al. HOST Study—HIV in Orthopaedic 
Skeletal Trauma Study: protocol for a multicentre case-cohort study. SA Orthop 
J. 2018;17:53-8. https://doi.org/10.17159/2309-8309/2018/v17n3a7.

20. Kale AR, Sonawane CS, Waghmare VU, Kalambe H. Open fractures and 
incidence of infection in tertiary care government hospital. Int J Sci Stud. 
2017;5(5):24-8. https://doi.org/10.17354/ijss/2017/386.

21. Van der Walt N, Ferreira N. An audit of circular external fixation usage in a 
tertiary hospital in South Africa: retrospective review. SA Orthop J. 2018;17:14-
21. https://doi.org/10.17159/2309-8309/2018/v17n4a1.

22. Sitnik AA, Beletsky AV. Minimally invasive percutaneous plate fixation of tibia 
fractures results in 80 patients: retrospective review. Clin Orthop Relat Res. 
2013;1471:2783-9. https://doi.org/10.1007/s11999-013-2841.

23. Badenhorst DH, Van der Westhuizen CA, Britz E, Burger MC, Ferreira N. Lost 
to follow-up. Challenges to conducting orthopaedic research in South Africa: 
retrospective review. S Afr Med J. 2018;108:917-21 https://doi.org/10.7196/
SAMJ.2018.v108i11.13252.

https://orcid.org/0000-0002-6028-0759
https://orcid.org/0000-0002-0009-2203
https://orcid.org/0000-0001-9160-7796
https://orcid.org/000-0001-9115-7254
https://orcid.org/0000-0001-6892-4582
https://orcid.org/0000-0003-0085-0876
https://orcid.org/0000-0003-2831-4960
https://orcid.org/0000-0002-0567-3373

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