South African Orthopaedic Journal

PAEDIATRIC ORTHOPAEDICS

DOI 10.17159/2309-8309/2021/v20n2a5 Ben Salem KA et al. SA Orthop J 2021;20(2)

Citation: Ben Salem KA, 
Maré PH, Goodier M, Marais 
LC, Thompson DM. Polio-like 
deformity: a diagnostic dilemma. 
SA Orthop J 2021;20(2):93-97. 
http://dx.doi.org/10.17159/2309-
8309/2021/v20n2a5

Editor: Prof. Jacques du Toit, 
Stellenbosch University, South 
Africa

Received: July 2020

Accepted: October 2020

Published: May 2021

Copyright:© 2021 Ben Salem 
KA. 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 secured 
for this research.

Conflict of interest: The authors 
have no conflict of interest to 
declare.

Abstract
Background
Significant advances have been made in the global effort to eradicate polio. Vaccine-associated 
poliovirus, or other enteroviruses, may still affect the anterior horn cell and cause acute 
flaccid paralysis. Following the acute disease, residual paralysis results in lower motor neuron 
weakness, altered growth and deformity. Our study aims to describe the clinical manifestations 
of a group of children that mimic that of classic paralytic poliomyelitis.

Methods
We identified six children from our paediatric orthopaedic database that presented with polio-like 
deformities. Their clinical and imaging records were reviewed and described, together with the 
clinical manifestations of paralytic poliomyelitis.

Results
Limb hypoplasia, pathological gait patterns and foot deformities were consistent features. 
The median leg length discrepancy was 2.5 cm (range 2–4 cm). The gait patterns observed 
included a Trendelenburg gait in 33% (n=2), a short limb gait in 50% (n=3), and one case with 
a combination of Trendelenburg, short limb and steppage gait. Tensor fascia lata contracture 
was present in 50% (n=3) of our patients. Foot deformities ranged from calcaneo-cavo-valgus to 
equino-cavo-varus deformities. 

Conclusion
Despite significant advances made in the global fight to eradicate polio, we still see children with 
clinical manifestations reminiscent of the disease. Orthopaedic surgeons should remain familiar 
with the assessment and diagnosis of the sequelae of paralytic poliomyelitis.

Level of evidence: Level 5

Keywords: poliomyelitis, vaccine-associated paralytic poliomyelitis, polio-like deformity, acute 
flaccid paralysis

Polio-like deformity: a diagnostic dilemma 
Khaled A Ben Salem,¹  Pieter H Maré,¹*  Matthew Goodier,² Leonard C Marais,³ David M Thompson¹ 

¹ Department of Orthopaedic Surgery, Grey’s Hospital, School of Clinical Medicine, University of KwaZulu-Natal, South Africa
² Department of Radiology, Grey’s Hospital, School of Clinical Medicine, University of KwaZulu-Natal, South Africa 
³ Department of Orthopaedic Surgery, School of Clinical Medicine, University of KwaZulu-Natal, South Africa

*Corresponding author: phmare@gmail.com

Introduction 
The last case of wild-strain poliomyelitis in South Africa was re-
ported in 1989.1 Despite this, we still see patients with clinical 
deformities resulting from paralysis reminiscent of that caused by 
the poliovirus (so-called polio-like deformity). Most orthopaedic 
surgeons familiar with the assessment and management of polio 
are nearing the end of their careers.2 Current orthopaedic reference 
textbooks have removed sections on polio. As availability bias may 
limit our ability to consider and diagnose uncommon conditions, 
it is essential that orthopaedic surgeons remain familiar with the 
clinical manifestations of paralytic polio.3

The most common viral motor neuronopathy in children pre-
senting as acute flaccid paralysis (AFP) results from enterovirus 
infections. These viruses include coxsackievirus, enterovirus 68 
and 71, echovirus and polio.4 Previously the focus was mainly 
on poliovirus. Significant strides have been made in the fight to 
eradicate polio globally. However, this goal has not been achieved 
yet and polio may still be imported from endemic areas. South 

Africa lost its ‘polio-free’ status in 2017 due to insufficiencies in 
its vaccination programme and surveillance systems.5 This was 
reinstated by the WHO’s African Regional Certification Committee 
(ARCC) in September 2019. Limitations in surveillance may 
result in some cases of AFP being missed. Vaccine-associated 
paralytic polio (VAPP) and circulating vaccine-derived poliovirus 
(cVDPV) remain a risk with the use of the oral attenuated polio 
vaccine (OPV). There has recently been a resurgence of interest 
in virus strains other than polio that have caused outbreaks of a 
febrile paralytic illness initially described as ‘polio-like illness’.6 This 
syndrome was eventually named acute flaccid myelitis (AFM) to 
differentiate it from disease caused by the poliovirus. Residual 
lower motor neurological deficit was noted in 84% of cases at 
median nine-month follow-up.6

While several causes of polio-like paralysis remain, the entity 
itself and its clinical characteristics in particular, remains poorly 
characterised. We could find no previous reports on the orthopaedic 
manifestations of paralytic enterovirus infection. This study aims to 
describe a cohort of patients presenting with polio-like deformities. 

https://orcid.org/0000-0003-2778-3140
https://orcid.org/0000-0003-1599-7651


Page 94 Ben Salem KA et al. SA Orthop J 2021;20(2)

Methods
We retrospectively reviewed data from cases who presented to our 
tertiary level paediatric orthopaedic unit over the seven years from 
January 2011 to December 2018. The unit serves a population of 
approximately 4.3 million people, of which 1.6 million are children 
between the ages of 0 and 14 years.7 

Following ethical approval, cases were identified from our 
paediatric orthopaedic database. All patients, below the age of 18 
years, presenting with polio-like deformity were included. ‘Polio-
like deformity’ was defined as the combination of asymmetric 
lower motor neuron (LMN) paralysis, deformity and altered growth 
consistent with that seen with poliomyelitis. Spine MRI investigation 
was routinely performed to identify features suggestive of pre-
vious neuroinvasive viral infection. Patients with deformity and 
neurological deficit due to other causes were excluded. The 
differential diagnosis for this presentation includes other causes 
of lower motor neuropathy, such as hereditary motor sensory 
neuropathies, congenital spinal abnormalities (spinal dysraphism), 
previous traumatic or toxic neuritis as well as neuroinvasive viral 
infection. 

The records were reviewed for vaccination history, any previous 
significant febrile illness (with or without signs of meningism) and 
history of AFP. Clinical records were reviewed for the pertinent 
findings during neurological evaluation, as well as documentation 
of joint contractures, deformities and leg-length discrepancy (LLD). 
X-ray and MRI records were reviewed from our institution’s PACS 
and included in our analysis. Motor function was assessed by 
testing and grading power according to the Medical Research 
Council (MRC) grading.8 Decreased or absent tone and reflexes 
were findings consistent with an LMN lesion.

The indication for MRI was any child who presented with 
unexplained LMN weakness and deformity or altered growth in 
keeping with the typical findings of poliomyelitis.

All MRI scans were performed using a 1.5 Tesla Phillips Intera 
MRI machine. Standard spine sequences included STIR, T2 and T1 
sagittal acquisitions and T2 and T1 axial acquisitions. Intravenous 
gadolinium was not routinely used. Five of the MRI scans were 
evaluated by a specialist radiologist with seven years’ experience 
and a postgraduate diploma in neuroradiology. Axial images were 
evaluated for the presence of ventral nerve root atrophy which was 

considered to be present if the ventral (motor) nerve roots of the 
cauda equina were markedly smaller in calibre than the dorsal 
(sensory) roots at the same level. One of the scans (patient 4) did 
not have MRI images available for review, and the MRI report from 
the patient records was used. 

Results
We identified six patients that met the clinical criteria for polio-like 
deformity. MRI findings consistent with previous neuroinvasive viral 
infection were present in 67% (n=4). Their mean age was 8 years 
(range of 2–14). Their presenting complaints and clinical findings 
are summarised in Table I. 

All patients had some degree of limb hypoplasia with LLD of 
median 2.5 cm (range 2–4). Limp was another consistent feature 
with 33% (n=2) presenting with Trendelenburg gait, a short limb 
gait was present in 50% (n=3), and one child presented with a 
combination of Trendelenburg, short limb and steppage gait. 
Tensor fascia lata (TFL) contracture is a classic feature of polio 
and was present in 50% (n=3) of our patients. Foot deformities 
were present in all cases. These ranged from mere hypoplasia to 
calcaneo-cavo-valgus (Figures 1 and 2) at one end, and equino-
cavo-varus deformity at the other end of the spectrum. 

VAPP was confirmed in one patient who presented to the pae-
diatric service with AFP after OPV administration during infancy. 
She presented at our orthopaedic unit at the age of 8 years with an 
LMN paresis affecting the left lower limb and classic deformities of 
polio in the hip, knee and foot and ankle (Figure 3). No clear history 
of AFP could be elicited in any of the other cases.

Two of the MRI scans were normal. Three of the patients had a 
clear subjective reduction in the calibre of the ventral nerve roots 
of the cauda equina (Figure 4). In one patient, this finding was 
present bilaterally, and in two patients, this finding was unilateral. 
One patient had long segment signal abnormality involving the 
entire spinal cord. 

Discussion
Polio is caused by three related enteroviruses (types 1, 2 and 
3). Fewer than 1% of polio infections in children result in AFP.9 
A recovery phase follows AFP during which the muscle recovers 
rapidly in the first six months and slower over the subsequent 

Table I: Summary of clinical findings

Patient
Age 

(years)
Sex Presenting complaint Gait Hip Knee Foot and ankle LLD

1 4 M Hypoplastic left lower limb Short limb gait - - Calcaneo-cavo-valgus 
deformity (Figures 1 
and 2)

2 cm 

2 10 F Limp and hypoplastic left 
lower limb 

Trendelenburg gait Left hip dislocation 
(Figure 6)

- Equino-cavo-varus 
deformity

3 cm

3 2 M Limp and foot deformity Trendelenburg gait ITB contracture 
(Figure 5)

- Hypoplastic left foot 
(Figure 7)

2 cm 

4 8 F Lower limb paralysis and 
deformity (Figure 3)
History of AFP post OPV 
at age 1 year

Paralytic gait 
(combined)

ITB contracture
Hip flexion power 
3/5

Quadriceps 
power 3/5

Tibialis anterior paralysis 
0/5
Equino-cavo-varus 
deformity

4 cm 

5 14 F Hypoplastic left lower limb Short limb gait ITB contracture Normal, 
thigh 
muscles 
wasting

Equinus deformity 4 cm 

6 7 F Right lower limb 
weakness and shortening

Short limb gait Hip flexion power 
4/5

Hypoplastic 
thigh 
musculature

Fixed forefoot adduction 2 cm 



Page 95Ben Salem KA et al. SA Orthop J 2021;20(2)

months until up to two years. No recovery occurs after this in the 
residual paralysis phase. Residual paralysis following enterovirus 
infection may be mild. Asymmetric weakness and incomplete 
recovery of paralysis result in muscle imbalance. In the growing 
child, active muscles shorten, and paralysed muscles overlengthen. 
Over time this results in altered bone growth and joint contractures. 
A greater disparity in strength will result in earlier deformity. A 
mild discrepancy, however, over a long period, will also result in 
deformity, altered growth and joint development. These deformities 
often manifest years after the initial paralysis and are recognised 
as the typical manifestations of paralytic polio.10

Our study describes a cohort of patients with the typical clinical 
features of paralytic polio. 

The typical joint contractures and deformities seen in polio occur 
during growth as a result of the muscle imbalance in the residual 
paralysis phase after neuroinvasive viral infection. A shortened 
limb is due to interference with growth.11 The pattern of paralysis 
is classically asymmetric. All our patients had asymmetric growth 
disturbance and presented with varying degrees of limb hypoplasia 
and shortening. Sharrard published detailed and extensive 
analyses of the pattern of cell destruction in the spinal cord, as well 
as muscle recovery in poliomyelitis.12,13 Muscles most frequently 
completely paralysed have their anterior horn cells located in a 
narrow zone in the spinal cord (e.g. tibialis anterior).14 Muscles 
that have their anterior horn cells in a wider region may still be 
frequently affected (e.g. the quadriceps femoris), but will seldom 
be completely paralysed.10 This pattern was seen in the child with 
confirmed VAPP who had complete paralysis of tibialis anterior, 
(0/5 power) but paresis of the quadriceps (3/5 power). Sensory 
loss is infrequent. Subsequent motor dysfunction and deformity will 
depend on the pattern of paralysis.15 

A Trendelenburg gait is a common feature due to abductor 
paralysis. Gluteus maximus paralysis may result in an extensor 
lurch during the stance phase of gait. Three children in our series 

Figure 1. Clinical images in the frontal and sagittal plane demonstrating 
calcaneo-cavo-valgus foot deformity

Figure 2. Lateral X-ray demonstrating calcaneo-cavus deformity with 
calcaneal pitch measured at 49°

Figure 3. AP pelvis X-ray showing left hip dislocation with acetabular 
dysplasia and hypoplastic proximal femur

Figure 4. T2-weighted axial MRI image showing atrophy of the ventral 
nerve roots most marked on the left (white arrow) compared to the right 
(white arrowhead) and left dorsal nerve roots (white open arrow)

Figure 5. Clinical picture of a positive Ober’s test in patient 3; this test 
confirms tensor fascia lata (TFL) and ilio-tibial band (ITB) contracture



Page 96 Ben Salem KA et al. SA Orthop J 2021;20(2)

had a Trendelenburg gait due to abductor weakness. We did not see 
any children with gluteus maximus paralysis. Hip contractures are 
typically into an abducted, externally rotated and flexed position.2 
Abduction contracture is in part the result of TFL contracture. 
Ober’s test identifies TFL contracture (Figure 5). Less frequently, 
hip instability and dislocation may occur due to paralysed gluteal 
muscles and strong hip adductors and flexors. This is associated 
with coxa valga, persistent anteversion and acetabular dysplasia.10 
ITB contracture was found in three children in our series. One child 
presented with a paralytic dislocation (Figure 6).

Quadriceps weakness makes a ‘hand on thigh’ gait necessary 
to lock the knee during stance.2 Genu recurvatum deformity may 
develop if a child bears weight on a flail limb by locking the leg 
into hyperextension during every stance phase.10 Fixed flexion 
deformity of the knee occurs more frequently due to quadriceps 
weakness and strong knee flexors.10 Contracture is often severe. 
TFL contracture also results in external tibial torsion. Quadriceps 
weakness was found in one child, while in two children thigh 
hypoplasia was present without weakness. None of the children in 
our series had knee flexion or recurvatum deformities.

Tibialis anterior is one of the most frequently completely paralysed 
muscles.10 This results in a foot drop and fixed equinus deformity. 
Depending on the pattern of paralysis, a range of deformities may 
occur. These include equinus, calcaneus, hindfoot varus or valgus, 
pes cavus or pes planus, or any combination of these.2 Foot 
deformities were present in all children in our series. These ranged 
from calcaneo-cavo-valgus deformity in one child (Figures 1 and 2) 
to equino-cavo-varus deformities in two children. One child each 
had forefoot adduction, pure equinus and hypoplasia (Figure 7). 

MRI findings consistent with previous poliomyelitis were present 
in 69% (n=4). This is consistent with a report by Teoh et al., which 
found 75% (n=3) abnormal spine MRIs in cases of AFP due to 
neuroinvasive viral infection.16 Only one of our cases had a 
clear history of AFP. This was confirmed as VAPP. It is possible 
that the other cases may have been the result of undiagnosed 
enterovirus infection, causing lower motor neuronopathy. Once 

the child presents with the late sequelae of paralytic enterovirus 
infection, no serological test or imaging investigation can confirm 
the diagnosis definitively. Spine MRI investigation may strengthen 
the clinical suspicion. During the acute phase of the disease, MRI 
features could include diffuse signal abnormality in the cord (as 
was present in patient 4). In the chronic phase the only changes 
may be that of ventral root atrophy (these features were observed 
in patients 1–3).

Significant progress has been made since 1988 by the 
Global Polio Eradication Initiative (GEPI) and the World Health 
Organization. Since 2000, 13 million cases of polio have been 
prevented by the oral polio vaccine (OPV), and the disease has 
been reduced by more than 99%.17 Only wild poliovirus (WPV) type 
1 remains endemic in Pakistan and Afghanistan. The last case of 
WPV type 2 was recorded in 1999, and WPV type 3 in 2012.18 
South Africa has a well-established vaccination programme which 
has been massively successful in eradicating wild polio infection. 
In rare instances the attenuated Sabin poliovirus administered as 
the OPV may undergo genetic drift during replication, developing 
neurovirulent properties. This may cause AFP identical to that 
caused by WPV. The rate has been reported between 3.8 and 4.7 
cases per million live births.19 These viruses may be transmitted as 
circulating vaccine-derived poliovirus (cVDPV). The small risk of 
VAPP and cVDPV is offset by the immense public health benefit of 
OPV. Ironically, the management of a cVDPV outbreak is ensuring 
efficient vaccination in the area to stop the spread of the mutated 
neurovirulent viral strain. While there are advantages to OPV, 
it is being phased out as wild polio is eradicated to prevent the 
occurrence of VAPP and cVDPV. This started in April 2016 as a 
global coordinated effort to change from trivalent OPV (containing 
types 1, 2 and 3) to bivalent OPV (type 1 and 3).17 

Several limitations of our study warrant consideration. Due to 
the rarity of the syndrome we were able to identify only a small 
number of cases. We were unable to confirm a history of AFP in 
all but one child. This may be explained by a situation where the 
meningitic nature of a febrile illness was not appreciated. A mild 
neurological deficit, especially in young children, can easily be 
missed. As the subsequent clinical course is that of progressive 

Figure 6. Clinical picture in the frontal plane 
demonstrating hypoplasia of the left lower limb, genu 
valgus and equinovarus foot deformity, all classic 
features of polio Figure 7. Clinical picture showing hypoplasia of the left foot in patient 3



Page 97Ben Salem KA et al. SA Orthop J 2021;20(2)

recovery, healthcare opinion may not have been sought. This 
is supported by the 2016 report that South African national AFP 
surveillance was below the heightened WHO target for 2015/16 of 
4/100 000 with several districts reporting 0 or 1/100 000 cases.18 
Electrophysiological testing would have been useful but was not 
available for paediatric patients at our hospital during the study 
period. Despite these shortcomings, the classic clinical findings of 
paralytic polio, supported by MRI findings in most cases, prompted 
us to compile this report. We could not find any previous published 
reports of this clinical entity. Clinicians should remain familiar with 
sequelae of paralytic polio because, to quote the philosopher 
George Santayana, ‘those who cannot remember the past are 
condemned to repeat it’.20

Conclusion
While major strides have been made towards worldwide polio erad-
ication, non-polio enteroviruses, VAPP and cVDPV may still cause 
a polio-like deformity. AFP surveillance should be strengthened 
to ensure all cases are identified early and deformities prevented 
or treated early. If the child presents years later, thorough 
clinical evaluation should exclude other causes of lower motor 
neuronopathy. Typical features include asymmetric limb hypoplasia 
combined with LMN weakness and TFL contracture. MRI may be 
useful to identify features of previous neuroinvasive viral infection. 

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. 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. Ethical approval was granted by the University of KwaZulu-Natal 
Biomedical Research Ethics committee (BE380/18).

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 
KABS: Data capture, first draft preparation, manuscript revision 
PHM: Manuscript revision and review 
MG: Manuscript preparation and review 
LCM: Manuscript revision and review 
DMT: Study design, data capture, manuscript review

ORCID
Ben Salem KA  https://orcid.org/0000-0003-2778-3140
Maré PH  https://orcid.org/0000-0003-1599-7651
Goodier M  https://orcid.org/0000-0002-6091-1768
Marais LC  https://orcid.org/0000-0002-1120-8419 
Thompson DM  https://orcid.org/0000-0003-2607-3999

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https://orcid.org/0000-0003-2778-3140
https://orcid.org/0000-0003-1599-7651
https://orcid.org/0000-0002-6091-1768
https://orcid.org/0000-0002-1120-8419
https://orcid.org/0000-0003-2607-3999