Paediartic Orthapaedics PDF

Summary

This document is a presentation on paediatric orthopaedics, covering topics like the young musculoskeletal (MSK) system, bone formation, growth, and various pediatric injuries. It discusses different conditions, examinations, and treatments.

Full Transcript

Ms Kezia Brown
Senior clinical lecturer
Consultant orthopaedic surgeon

Body in Motion
MBChB The young MSK system
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Summary Young MSK

The growing skeleton
Paeds MSK
Sports injuries
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Young MSK

The growing skeleton
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Mechanisms of bone formation Young MSK

Intramembranous ossification
Osteoid laid down by osteoblasts
within loose fibroconnective tissue of
a fibrous membrane

Endochondral ossification
Osteoid deposited on cartilage
scaffolds

Related video: “Bone growth”
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EO – Secondary centre of ossification Young MSK

Related video: “Bone growth”
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Cessation of skeletal growth Young MSK

Related video: “Bone growth”
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Cessation of skeletal growth Young MSK

Genetics
Altering factors
Systemic disease
Nutrition
Endocrine
Infection
Trauma

Related video: “Bone growth”
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What is a physis Young MSK

Hyaline cartilage plate at ends of
long bones
Responsible for growth
Physis longitudinal
Perichondrium
Endochondral ossification

Case courtesy of Dr Matt Skalski, Radiopaedia.org, rID: 29729

Related video: “The physis”
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Microscopic structure Young MSK

Resting zone

Proliferative zone

Hypertrophic zone

Metaphyseal bone

Related video: “The physis”
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Young MSK

Paeds MSK
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Limping child - Age Distribution Young MSK

Related video: “The limping child”
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Limping child – Exclude Sepsis Young MSK

Full blood count
ESR, CRP
X rays – AP & frog lateral
Ultrasound
MRI, bone scan, etc

Related video: “The limping child”
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Developmental dysplasia (DDH) Young MSK

1-5/1000 births
5 ‘F’s
Female (F:M ratio 5:1)
First born
Feet first (breach or c-sec)
Family history (hereditary influence)
Fluid (oligohydramnios)

Related video: “The limping child”
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DDH examination Young MSK

Barlows
Ortolani
Skin crease asymmetry
Leg length discrepancy
Reduced abduction

Related video: “The limping child”
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DDH radiographs Young MSK

Related video: “The limping child”
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DDH treatment Young MSK

Related video: “The limping child”
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Perthes disease Young MSK

Osteonecrosis of femoral epiphysis
Aetiology poorly understood but likely non-genetic factors
Male:female ratio 4:1
4-8 years in majority
Lower social class = increased risk

Related video: “The limping child”
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Perthes - Radiographs Young MSK

Related video: “The limping child”
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Slipped Upper Femoral Epiphysis Young MSK

Males (3:1) 13-16 years
In females younger, not after menarche
Bilateral in 42%
Obese or tall and slender
Rapid growth
7% risk of a 2nd family member involved

Related video: “The limping child”
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SUFE - Radiographs Young MSK

Related video: “The limping child”
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SUFE – Clinical Young MSK

Acute / Chronic / Acute on Chronic
Pain groin, thigh, knee
Limp
Antalgic gait
Externally rotated and adducted limb

Related video: “The limping child”
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SUFE - Treatment Young MSK

Related video: “The limping child”
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Red flags Young MSK

Neonate with painful paralysed SEPTIC
looking arm or leg ARTHRITIS/INFECTION

Asymmetry of spine or limbs SCOLIOSIS/DDH
PERTHES DISEASE
School age child with limp
SUFE OR TUMOUR
Knee pain in adolescent
DISCITIS
Back pain
Non accidental injury

Related video: “The limping child”
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NAI - High index of suspicion Young MSK

Injury in the non-ambulatory/totally dependant child
Injury and history given are inconsistent
Delay in seeking medical attention
Multiple fractures with no family history of osteogenesis imperfecta
Retinal haemorrhage
Torn frenulum
History of household falls resulting in fracture
despite falls being common, fractures are uncommon

Related video: “Non-accidental injury”
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Young MSK

Paeds MSK trauma
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Plasticity/elasticity Young MSK

Less rigid
Plastic deformity

Incomplete fractures
Greenstick (tension)
‘Buckle’ or torus (compression)

Related video: “Paeds trauma”
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Plasticity/elasticity Young MSK

Less rigid
Plastic deformity

Incomplete fractures compression tension
Greenstick (tension)
‘Buckle’ or torus (compression)

Related video: “Paeds trauma”
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Plasticity/elasticity Young MSK

Less rigid
Plastic deformity

Incomplete fractures
Greenstick (tension)
‘Buckle’ or torus (compression)

Related video: “Paeds trauma”
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Plasticity/elasticity Young MSK

Less rigid
Plastic deformity

Incomplete fractures
Greenstick (tension)
‘Buckle’ or torus (compression)

Related video: “Paeds trauma”
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Plasticity/elasticity Young MSK

Less rigid
Plastic deformity

Incomplete fractures
Greenstick (tension)
‘Buckle’ or torus (compression)

Related video: “Paeds trauma”
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Remodelling Young MSK

Greatest potential
Young age
When near a joint
Deformity is in same plane as joint

Wolf’s law
Bone deposited on compression
side
Bone absorbed on tension side

Related video: “Paeds trauma”
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Physeal considerations Young MSK

What is a growth plate?
Allows longitudinal growth
Fuse at around 14-16

Why is a fracture here important?
Risk of growth problems
Partial or complete arrest
+/- articular involvement

Related video: “Paeds trauma”
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Salter-Harris classification Young MSK

Illustration courtesy of Dr Matt Skalski, Radiopaedia.org, rID: 27144 Related video: “Paeds trauma”
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Growth deformities Young MSK

Related video: “Paeds trauma”
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Growth deformities Young MSK

Related video: “Paeds trauma”
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Paediatric fractures Young MSK

Very different management to adults
Good news
Thick periosteum aids conservative management
Ability to remodel with time and limb growth
Heal rapidly
Non-union very rare
Less morbidity with bed rest vs adult population
Bad news
Physeal plate injuries before skeletal maturity can cause growth abnormalities
and arrests
Can be difficult to diagnose

Related video: “Paeds trauma”
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Manipulation under anaesthetic Young MSK

Related video: “Paeds trauma”
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K-wires and flexible nails Young MSK

Related video: “Paeds trauma”
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Bed traction Young MSK

Related video: “Paeds trauma”
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Young MSK

Sports injuries
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Types of injury Young MSK

Acute traumatic
Bruising, cuts, abrasions
Head injuries
Cartilage/meniscal injuries
Muscle/tendon/ligament injuries
Dislocations
Fractures

Related video: “Sports injuries intro”
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Types of injury Young MSK

Acute traumatic
Bruising, cuts, abrasions
Head injuries
Cartilage/meniscal injuries
Muscle/tendon/ligament injuries
Dislocations
Fractures

Related video: “Sports injuries intro”
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Types of injury Young MSK

Acute traumatic Chronic overuse
Bruising, cuts, abrasions Tendonitis
Head injuries Stress fractures
Cartilage/meniscal injuries Back pain
Muscle/tendon/ligament injuries
Dislocations Instability
Fractures

Related video: “Sports injuries intro”
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Preventing injury Young MSK

Causes Prevention
Conditioning Improve fitness
Technique Gradual build up
Equipment Warm up/warm down
Anatomy Train correctly
Luck Get the right equipment
Avoid overstressing

Related video: “Sports injuries intro”
Mr Mark Gaston
Consultant orthopaedic surgeon
Royal Hospital for Sick Children, Edinburgh

Body in Motion
MBChB The limping child
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Tutorial content MBChB Limping child

Gait in children
Transient synovitis
DDH
Perthe’s disease
SUFE
Red flags
Infection
Discitis
Malignancy
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The limping child Limping child

Common presentation in paediatric orthopaedics

Often atraumatic

Incidence 180 / 100,000
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Normal Gait in Children Limping child

Early Walking
Short Stride length
Fast cadence
Low Velocity
Widened base of support

Until 30-36 months – poor balance and abductor strength so cannot
maintain single leg stance

Mature gait age 7

THE LIMPING CHILD | GAIT PRESENTATION SYNOVITIS DDH PERTHES SUFE RED FLAGS
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Abnormal Gait Limping child

Pain

Mechanical problem

Neuromuscular problem

THE LIMPING CHILD | GAIT PRESENTATION SYNOVITIS DDH PERTHES SUFE RED FLAGS
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Age Distribution Limping child

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History – Pain characteristics Limping child

Acute – trauma, infection
Constant - malignancy, chronic infection
Morning pain / pain after inactivity – Inflammatory joint disorders
Night Pain
Malignancy, osteoid osteoma,
Benign “growing pains”

THE LIMPING CHILD | GAIT PRESENTATION SYNOVITIS DDH PERTHES SUFE RED FLAGS
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Examination Limping child

Gait
Spine
Asymmetry
Deformity
Swelling
Tenderness
Examine all joints
Rotational profile

THE LIMPING CHILD | GAIT PRESENTATION SYNOVITIS DDH PERTHES SUFE RED FLAGS
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Irritable Hip (Transient Synovitis) MBChB Limping child

Non-specific, short term
inflammatory synovitis with
synovial effusion of the hip joint

THE LIMPING CHILD | GAIT PRESENTATION SYNOVITIS DDH PERTHES SUFE RED FLAGS
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Transient Synovitis - clinical Limping child

Painful hip / thigh / knee
Often associated with viral infection
Synovial fluid effusion
Hip held in flexion, lateral rotation and abduction
Exclusion of other conditions

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Investigations – Exclude Sepsis Limping child

Full blood count
ESR, CRP
X rays – AP & frog lateral
Ultrasound
MRI, bone scan, etc

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Developmental Dysplasia (DDH) Limping child

1-5/1000 births
Hereditary Influence
Breach after 32 weeks or Caesarian
1st Born
Oligohydramnios
Female : male 5:1

THE LIMPING CHILD | GAIT PRESENTATION SYNOVITIS DDH PERTHES SUFE RED FLAGS
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DDH - Examination Limping child

Barlows
Ortolani
Skin crease asymmetry
Leg length discrepancy
Reduced abduction

THE LIMPING CHILD | GAIT PRESENTATION SYNOVITIS DDH PERTHES SUFE RED FLAGS
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DDH - Radiographs Limping child

THE LIMPING CHILD | GAIT PRESENTATION SYNOVITIS DDH PERTHES SUFE RED FLAGS
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DDH – Treatment as infant Limping child

THE LIMPING CHILD | GAIT PRESENTATION SYNOVITIS DDH PERTHES SUFE RED FLAGS
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DDH – Treatment as infant + Limping child

THE LIMPING CHILD | GAIT PRESENTATION SYNOVITIS DDH PERTHES SUFE RED FLAGS
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Perthes Disease Limping child

Osteonecrosis of femoral epiphysis caused by poorly understood
non-genetic factors

Boys > Girls 4:1

4-8 years in majority

Lower social class increased risk

THE LIMPING CHILD | GAIT PRESENTATION SYNOVITIS DDH PERTHES SUFE RED FLAGS
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Perthes - Radiographs MBChB Limping child

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Perthes - Treatment Limping child

Principles are
prevention of stiffness
contain femoral head in acetabulum
surgical treatment required in certain circumstances
outcome depends on how well femoral head remodels

THE LIMPING CHILD | GAIT PRESENTATION SYNOVITIS DDH PERTHES SUFE RED FLAGS
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Perthes - Treatment Limping child

THE LIMPING CHILD | GAIT PRESENTATION SYNOVITIS DDH PERTHES SUFE RED FLAGS
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Slipped Upper Femoral Epiphysis Limping child

Males (3:1) 13-16 years
In females younger, not after menarche
Bilateral in 42%
Obese or tall and slender
Rapid growth
7% risk of a 2nd family member involved

THE LIMPING CHILD | GAIT PRESENTATION SYNOVITIS DDH PERTHES SUFE RED FLAGS
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SUFE - Radiographs MBChB Limping child
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SUFE – Clinical Limping child

Acute / Chronic / Acute on Chronic
Pain groin, thigh, knee
Limp
Antalgic gait
Externally rotated and adducted limb
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SUFE - Treatment MBChB Limping child

THE LIMPING CHILD | GAIT PRESENTATION SYNOVITIS DDH PERTHES SUFE RED FLAGS
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Red flags Limping child

Neonate with painful paralysed SEPTIC ARTHRITIS /
looking arm or leg INFECTION

Asymmetry of spine or limbs SCOLIOSIS/DDH
PERTHES DISEASE
School age child with limp
SUFE OR TUMOUR
Knee pain in adolescent
DISCITIS
Back pain
Non accidental injury

THE LIMPING CHILD | GAIT PRESENTATION SYNOVITIS DDH PERTHES SUFE RED FLAGS
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Infection Limping child

Cellulitis
Osteomyelitis
Septic arthritis
Usually requires
emergent referral for
investigation +/-
aspiration

THE LIMPING CHILD | GAIT PRESENTATION SYNOVITIS DDH PERTHES SUFE RED FLAGS
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Discitis Limping child

Presentation can be subtle

MRI usually required

Epidural abscess is surgical
emergency

THE LIMPING CHILD | GAIT PRESENTATION SYNOVITIS DDH PERTHES SUFE RED FLAGS
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Swellings Limping child

Beware of atraumatic,
painless swellings

THE LIMPING CHILD | GAIT PRESENTATION SYNOVITIS DDH PERTHES SUFE RED FLAGS
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Swellings Limping child

Beware of atraumatic,
painless swellings

THE LIMPING CHILD | GAIT PRESENTATION SYNOVITIS DDH PERTHES SUFE RED FLAGS
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Swellings Limping child

Beware of atraumatic,
painless swellings

THE LIMPING CHILD | GAIT PRESENTATION SYNOVITIS DDH PERTHES SUFE RED FLAGS
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Non accidental injury Limping child

What should raise suspicion?
Pre-existing disability
Vague history from parents
Injury inconsistent with history
Delay in presentation
Multiple bruises of varying age
Multiple fractures
Burns

THE LIMPING CHILD | GAIT PRESENTATION SYNOVITIS DDH PERTHES SUFE RED FLAGS
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Tutorial content MBChB Limping child

Gait in children
Transient synovitis
DDH
Perthe’s disease
SUFE
Red flags
Infection
Discitis
Malignancy
Welcome to the lecture on non-accidental injury in the paediatric population.

1
In this lecture we will discuss the epidemiology of NAI, talk about some of the injuries
that children could sustain, some susceptible conditions that make them more likely
to have injuries, and talk about the role of doctors in NAI cases.

2
Although non-accidental injury is relatively uncommon, with an incidence of around 4
cases per 10k children, A 2001 study in the united states estimated that there are
around 903k children per year who are victims of maltreatment. Neglect is the most
common maltreatment, accounting for just under 60% of cases, but physical abuse is
found in around 20% of cases with soft tissue injuries being the most common.

3
Non-accidental injury is the second most common cause of death in children, after
accidental injury, and has some sobering statistics associated with it. If the abuse
goes unreported, there is a 30-50% chance of further abuse and a 10% chance the
child will die from subsequent injury. This means it is imperitive that healthcare
professionals have a high index of suspicion for abuse in paediatric trauma.
There are a few risk factors that, although in no way guarantee it, increase a child’s
likelihood of suffering abuse. We should therefor be careful to keep risk factors in
mind but remain non-judgemental when assessing a child with injuries. There are also
subtleties to understand with each risk-factor, for example a child with a disability
may not be able to communicate fully, akin to a child of a much younger age.

4
As previously mentioned, soft tissue injuries account for the majority of NAIs. Young
children are clumsy and lack many of the self-preservation instincts of most adults, as
anyone with kids will agree, so are highly susceptible to accidental injury. There are
patterns of injury, however, that can help to differentiate a genuine accident from a
abusive one. It’s rare for children younger than 18 months to suffer head or facial
injuries but they are present in around 60% of NAI cases. Young children who are
learning to walk or run can suffer multiple bruises of different ages to their hand, feet
and legs due to simple trips and falls. These need to be assessed on an individual
basis to look for other worrying signs, which we’ll come back to later on.
We’ll now look at a few injuries which are difficult to sustain accidentally and strongly
suggest abuse. Some of the images in the next five slides can be distressing so you
may wish to listen to the audio alone.

5
Human bitemarks have a characteristic appearance to them and can cause significant
pain to a child, with a risk of infection higher than animal bites. The dimensions of
bitemark can be used to estimate the size of the person who bit the child. This is
important as it is not uncommon for young children to bite classmates in nursery if
upset and therefor may be a true accident. Adult bitemarks or multiple injuries, as
shown in the image on the left, should be investigated fully.

6
Again, children may suffer burns from true accidents, such as pulling a cup of hot
coffee over themselves or touching a lit stove. Many burns have characteristic
appearances, such as this cigarette burn or this lighter burn.
This 9 month old was held down on the hot plastic of a buggy which had been heated
by the sun. He suffered burns over the backs of his calves and required skin grafting.
Neglect can also cause injury, as demonstrated by this young boy who was left
outside in direct sun without suncream or a shirt.

7
Specific patterns of bruising can be pathognomic of NAI, such as the facial bruising
shown here. Grip marks either side of the mouth from force feeding can be seen as a
round thumb imprint on one cheek with 3 or 4 finger-tip bruises on the other. Careful
examination for intra-oral injuries can often find a torn frenulum, which is the small
bridge of tissue from the top lip to the gums.
After the initial redness has faded following a slap, petechial bruising, which is small
red spots from ruptures blood vessels, appears in a pattern between the fingers of
the assailant, as illustrated here.

8
These clinical pictures show some injuries from corporal punishment of children.
The child on the left has been spanked with great force, leaving a typical pattern of
bruising. You can see how the finger marks are white, with the red areas between the
fingers.
The child on the right has been punished by repeated blows with a belt, leaving long
straight-edged bruises across the buttocks.

9
Bruising can also be a sign of more significant injury, especially when around the
abdomen. This infant was punched repeatedly in the abdomen, causing multiple
bruises and a liver laceration, as shown in the CT scan.

10
Although soft tissue injuries are most common, fractures account for a significant
percentage of injuries. A historical paper from Nottingham looked at fracture
incidence by age, comparing accidental to non-accidental injuries.

11
This paper found that 80% of NAI cases occur in children younger than 18 months,
while only 2 and half% of accidental injuries occur in the same age group. Children
older than 18 months have a much lower annual incidence of NAI but a higher
incidence of accidental injury, when compared to the younger age group.

12
The paper also found that children who suffer from non-accidental injuries are also
significantly more likely to have multiple injuries, including burns and bruises to
multiple areas.

13
We’ll now look at the fractures that are most likely to be due to NAI and can often be
viewed as pathognomic.
A small fracture as the corner of a bone’s metaphysis, as shown here, is indicative of
forceful shaking. As a child’s trunk is shaken back and forth, the limbs move back and
forth rapidly with a resultant whiplash or shear force. Multiple microfractures across
the metaphysis, with an orientation perpendicular to the long axis of the bone, occur
in the immature mineralised bone. These can be very subtle and need careful
examination of radiographs.
They are the most specific fracture for NAI and occur in around 50% of NAI cases.
They occur almost exclusively in children younger than 2, as they are small enough to
be picked up to shake and don’t have the muscle tone to protect their own limbs.

14
Rib fractures are also very common in NAI, present in around 50% of cases and often
diagnosed by skeletal survey. Multiple posterior rib fractures in particular, as shown
here, are highly suspicious that a child has been crushed while being shaken.

15
Although femoral fractures are reasonably common as an accidental injury, they are
less common in younger children. Below the age of 3, around 30% of femur fractures
are due to NAI and this climbs to almost 100% in children who are non-ambulatory, ie
those who are not walking yet. A femur fracture in a non-ambulatory child can still
occur by accident, for example by rolling off a nappy-changing table, but should be
viewed a NAI until proved otherwise.

16
There are a number of conditions that increase the likelihood of a child to sustain
bony injuries which can be a source of great distress to parents who, until diagnosis,
are viewed with suspicion of NAI. Osteogenesis imperfecta, known as brittle bone
disease to the public, is a group of genetic disorders that lead to defects in type 1
collagen. This gives them extremely fragile bones that are highly susceptible to
fracture from very minor trauma. They may have several fractures already by their
first birthday and can be easily misattributed to abuse, until a diagnosis is made.
Careful consideration is needed here as, due to the risk factors mentioned previously,
they may still be vulnerable to abuse.

17
Other susceptible conditions include prematurity and copper deficiency which further
complicate assessment due to the former being an independent risk factor for NAI
and the latter possibly due to neglect.

18
As doctors, we have a duty to be aware of the problem and how prevalent it is in
society. We should be able to recognise unusual injury patterns and know our local
guideline for initiating investigation, including liaison with child protection services.

19
We must have a high-index of suspicion when assessing a child with a traumatic
injury and even in cases when children present with other non-trauma related
conditions. For example, a child who presents with a chest infection may be found to
be a victim of abuse when bruises are identified on his abdomen during chest exam.
This slide lists a number of features that are highly suspicious for NAI and can be read
at your leisure.

20
This final slide is an excellent infographic from the British Dental Association,
summarising normal injury patterns on the left, and NAI patterns on the right.

21
Non accidental injury is a distressing presentation that all doctors should be vigilant
about. A fine balance is needed to avoid causing unnecessary distress to parents in
the absence of abuse but a child’s safety takes priority over this at all times and it’s
often better to err on the side of caution. The majority of caring parents will not be
upset about procedures to rule out NAI and are often thankful that staff are actively
looking out for it.
If you would like to read more about NAI, there are links to relevant content below.

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1
2
The specialty of orthopaedics gets it’s name from the ancient Greek words orthos
meaning straight and paedia meaning child, combined in the word orthopaedia. An
orthopods goal when managing paediatric fractures and growth deformities is to allow
normal skeletal growth and make bones grow straight, although this simplifies things
a bit as we like bendy bones to be bendy if they are meant to be.

3
As we’ve already found, kids bones have quite a few important differences to adult
bones, including the overall number of bones, which is greater than an adult skeleton
when a number of separate bones, for example the illium ischium and pubis, fuse
together at the end of adolescent growth to form a single bone, in this example the
pelvis. The most obvious difference when looking at a child’s bone on a radiograph is
the presence of open physes, which appear as darker lines, and ossicifaction centres,
which usually appear as lighter circular areas, both in predictable places depending on
the age of the child.

4
Adult bones are rigid and brittle, meaning that when they suffer trauma they can
withstand a lot of force but when they fail it is usually in a sudden, catastrophic way.
That is the bone breaks completely or even shatters in many bits. You can think of this
a bit like breaking a stick of chalk – it suddenly snaps into 2 pieces without any visible
bending before it fails.
Kids bones on the other hand, have much more elasticity to them, meaning they can
bend a little bit then spring back into the position they were in. They also demonstrate
considerable plasticity, which is a mechanical property meaning the bone changes
shape permanently, ie doesn’t go back to it’s original shape, but doesn’t break into
separate bits. You can see a combination of plasticity and elasticity if you bend a paper
clip. The metal doesn’t break and it springs back a little bit but not to the same shape
it started as.

5
These mechanical properties mean that paediatric fractures have different patterns to
adult ones, which we’ll discuss in the trauma videos. The image on the right shows a
long bone, for example a radius, with a bending force applied to the top of it. The
cortices of the bone experience different forces depending on their orientation to the
force. The bone on one side, shown in red, is pulled apart when the bone is bent,
meaning it is under tension. The bone on the other side, shown in blue, is forced
together and hence is under compression. This leads to different fracture patterns
occurring due to the different forces.

6
On the tension side, the bone is pulled apart so much that it can’t hold together and a
crack forms. If the force isn’t too great, this crack will only go part way across the bone,
ie it is an incomplete fracture, and is known as a greenstick fracture. This name comes
from young tree branches, which demonstrate similar incomplete breakages as they
are more flexible than larger, more mature branches.

7
On the compression side, the bone is squashed together and, when the force the gets
too great, buckles under the pressure and bulges out to the side forming a visible ridge
on a radiograph.

8
These 2 different patterns can be seen in a single bone, for example a humerus, or on 2
bones that experience the same bending force. This radiograph shows a radius failing
under tension with a buckle fracture highlighted in blue, and an ulna failing under
tension, showing a greenstick fracture highlighted in red.
Here’s a zoomed view of both fractures.

9
Another major difference between kids bones an adult
bones is that the periosteal that covers the surface of
the diaphysis is much thicker. It's a bit like a leathery
coating on the surface.

10
This has clinical implications as it's much easier to reduce
a fracture in children
When the bone breaks and the periosteum remains
intact that the bones generally don't displace as much
and when trying to reduce it the periosteum can act like
a hinge so that the bone goes back into him more
anatomical position

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Kids bones have a huge potential for remodelling that is
correcting deformity in the bone as it grows. The
greatest potential for remodelling happens with young
age mainly because the child has a lot of growth left and
before their fisies fuse and therefore a lot more time
before a lot more time through the growth correction to
occur

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Other factors that affect at the potential for remodelling
our how close the fracture is to a joint so the closer it is
to a joint the greater potential for remodelling and also
the plane of the fracture so if the fracture occurs in the
same plane as the movement of the joints so here we've
got a diagram that perhaps representing a wrist

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if the fracture breaks and the angulation of it is in the
plane of movements reflection extension of the wrist
and it's much more likely to remodel completely

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We've already found out about wolff's law during the
bone Physiology videos but it's worth mentioning again
here because this remodelling potential that relies on
wolf's law. You remember that wolf's law states that
bone remodels according to mechanical stresses placed
upon it

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in this case when a fracture happens and there's a residual angular angular deformity
like here , bone will be deposited on the compression side cause that's where most of
the mechanical forces going through as it's loaded
For example by load bearing in a limb. On the side of the bone that's under tension
where least forces are going through it that bone will be resourcd sorry absorbed

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This means that overtime a quite markedly angulated deformity can straighten out to
the extent that it's difficult to tell that there ever was a deformity to begin with.

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Importantly, because rotational movement doesn’t put much force through the bone
at the fracture, there is no potential for remodelling rotational deformities.

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Here we've got some examples of the remodelling
potential of paediatric bones on the left.
The first series of images show the tibial shaft fracture
assertable Darcy or fracture with the fool tibia and view
on the left and zoomed in views of it on the right the trio
of images in each section show the time of fracture
followed by about six months later and then a year down
the line. You can see that with 100% displaced fracture
of the tibial shaft in this child who I think was around
5:00 or six years old this has healed completely by six
months or there's a bone going right the way across the

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fracture and it's united and then by a year down the line
that quite marked deformity and displacement has been
remodelled successfully and restored the and is on its
way to restoring the medullary canal

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Similarly in this image sorry in this set of images of a
paediatric femoral fracture we can see again another
100% displaced fracture that's also short
By around three months the bone is uniting that's in the
second image and in the third image the bonus fully
united and is well on its way to uniting at into is well on
its way too remodelling into a street femur

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This last clinical example of remodelling she is a really
very displaced distal radius fracture this is a lateral view
here with the joint of the wrist at the top of the screen
showing that the fracture has displaced 100% and that
has shortened and in the final image of this the bone has
remodelled very nicely, helped along by the fact that the
deformities in the plane of the joint ie the flexion
extension access of the wrist

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A final and possibly the most important differences
between paediatric and adult fractures is the fact that
children have fisies as we've mentioned. Just two beat
the reinforce the concept once again the faces of the
part of the bone that allow longtitudinal growth and
they usually fuse at the age of 14 and females and 16 in
males.

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So what is fracture surprise fracture here so important.
Well there's two main reasons one is that there's the risk
of growth problems as we'll see in a moment and the
other is that because the price is right next to the joint
surface any articular involvement so we call these intra
articular fractures will lead to a step in the articular
surface. If we don't address this step in the articular
surface then it can very quickly lead to damage to the
cartilage of the other side of the joint and post traumatic
arthritis.

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We're lucky that we have a very useful classification
system in the Salter Harris classification system which
describes these fractures based on the pattern around
devices it's very useful because it gives us a very definite
management plan depending on the grade of the injury
that which is something that can be said for all trauma
classification systems. It can be remembered by the
mnemonic SA ltr or which witch is Salter of the Salter
Harris classification and when you're doing this it's
easiest to orientate the bone in your mind with the
articular surface at the bottom Because we start to refer

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to the fractures as being above or lower than the devices

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Type one sorta Harris fractures are the S4 street and that
the fracture line goes straight across the vicis these
fractures can be quite difficult to diagnose especially if
they're completely undisplaced as there's really no
evidence that the fracture has been there apart from
perhaps some soft tissue swelling around them that this
is because the fracture doesn't actually involve any the
bone itself and merely goes through the cartilage of the
vice itself at. The are the their fractures with a very good
prognosis and they are the least likely head of growth
abnormality at. Most of these fractures can be treated

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that conservatively with closed reduction he putting the
bone back into place if it's displaced and immobilisation
with a cast. Some of these injuries are a bit more severe
Some of these injuries have a bit more severe
displacement and if they can't be reduced closed then
they may need open reduction that is with a surgical
incision and fixation usually with wires holding them into
place coz they're not unstable when they're reduced.

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Type 2 fractures are known as a for above in the fracture
line exits above the fisis into the metaphysis and they
have a wedge of metaphysis still attached to the
epiphyseal fragment the most common Salter Harris
fracture accounting for probably around 70% of cases
and they have a low chance of growth arrest. Treatment
again is often with closed reduction and casting and but
some of these can be quite unstable or difficult to
reduce and they require surgery to open reduce and
then fix them with usually a wire across the fracture if
they are deemed to be unstable

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Type 3 fractures or the first of the intra articular type
fractures are either the fracture line exits into the joint
itself and therefore we need to be worried about a
particular step at the fracture line goes out below the
fisis so it's L for lower and they have an epiphany or
fragment these ones have a chance of growth deformity
and therefore need on an atomic reduction with surgery
and then monitoring afterwards for growth deformity
meline newlight
The growth deformity here occurs when the fisis there's
been disrupted shown here by the red bar that confuse

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and I close if it's not reduced properly or if the injuries
being particularly severe and this leads to an asymmetric
growth where the growth is tethered at the portion
that's that's fused and runs away with greater growth
the further from that few section you get. You'll see a
clinical example of this in a moment. The other intra
articular

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The other intra articular type of fracture is the type 4
furniture which is T for through as the fracture passes
through the vice itself With a combined metaphyseal
and epiphyseal fragment. Again this Inter articular
nature means that the fracture needs to be anatomically
reduced and the patient needs to be monitored for a
growth deformity as that's reasonably common with this
type of injury. Like the sorter Harris 3 the growth
deformity happens when the injured area that can be
fused leading to growth both on the remaining at
metaphyses opificio fragment and the rest of the normal

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bone shown here

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The final type in the Salter Harris classification is the
ruined typographer ruin which is a crush injury to fisis.
This can happen with a fall from height onto the. This
has by far the worst prognosis of all of the grades
because it often leads to complete growth arrest at the
vicis the younger the patient is when they have this
injury the worst the prognosis then because the other
limb will grow at the normal rate whereas the injured
limb that will have a significantly reduced growth.
Because of this the treatment for a type 5 is to monitor
the growth arrested for occurs and plan epiphyseal
thesis which is Fusion of the same vices in the

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contralateral limb at a point in future to prevent a
significant leg length discrepancy

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This slide summarises all the different types with norm
on the top left type one which is straight across across
the fisis tattoos above the vices type 3 is lower than the
fisis witches into articular type 4 is through the vicis
which is Inter ticular as well and type 5 is the crush
injury ruined injury to the the fisis which has the worst
prognosis due to complete growth arrest.

30
Speaking of growth arrest and deformity here we've got
an example of a distal tibial Salter Harris for fracture you
can see the fracture lines still on the radiograph here
outlined in red and the faces on the medial ankle had
fused leaving the fisis laterally in the tibia and the
uninjured part which is shown in green to continue
growing this has led to an angular deformity and you can
see this quite clearly by drawing a line parallel to the
ground which is where the talus should be aligned with
and actually it's around 15 to 20 degrees in a varus
angulation

31
On the right you can see an example of a complete
growth the rest of the distal femoral fisis shown and the
redline here and this has led to a very significant leg
length discrepancy I'm probably around there 5 to 10
centimetres in this five year old girl. This would have
been a delayed presentation becausr certainly as an
orthopaedic surgeon this would have been hopefully
picked up sooner. The treatment for this girl will likely
involve Fusion of the controversial fisis and possibly a leg
lengthening procedure.

32
So to summarise about paediatric fractures in general
their management is very different different 2 adult
fractures. The good news about paediatric paediatric
fractures is that they have a thick Perry Perry ostium that
aids conservative management they have an ability to
remodel with time unlim growth. They also heal much
quicker then adults for the same fracture patterns. For
example a one year old who has a femoral fracture may
heal fully in a matter of weeks whereas an adult may
take months for the fracture to Unite this means that not
only is nonunion very rare and kids but were able to

33
treat fractures with bed rest and traction there for a
couple of weeks where we'd have to use traction for
three months in an adult.
An added benefit in kids is that they don't tend to get as
much morbidity with bed rest and immobilistaion as
adilts so they don't get joint stiffness and muscle atrophy
as much and don't experience the significant sequalae of
immobilisation that such as pulmonary emboli
pneumonia and bed sores.

33
The bad news about that paediatric fractures is that
facial injuries before the child is skeletally mature can
cause quite significant growth of abnormalities and
arrests meaning care needs to be given to treat these
correctly.

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As clinicians paediatric fractures can be sometimes
difficult to diagnose due to the presence of faeces and
ossification centres. It's quite common for inexperienced
clinicians to diagnose a fracture on a radiograph by not
recognising a completely normal physis or ossification
centre. For this reason there's often robust safety net set
up in hospitales with expert laid trauma triage clinics or
on site radiology reports that can advise on ambiguous
diagnoses.

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