OTR_Paediatric Orthopaedic Condition and Scoliosis 2023.pdf

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PHT2012 Orthopaedics Traumatology and
Rheumatology

Paediatric Orthopaedic
Conditions and Scoliosis

Dr. Rufina Lau
2023

Content
Paediatric MSK
Development

MSK Examination

Dysplasia/ Deformity

Fractures

2

Scoliosis

Paediatrics
•

Medical care of infants,
children, adolescents and
young adults

•

Not miniature of adults

•

Growth and development –
immature MSK system

•

Susceptible to abnormal forces
and stresses

3

Common Paediatric Bone & Joint Disorders
• Congenital and hereditary disorders
• Growth-related disorders
• Skeletal trauma - fractures
• Inflammatory and infectious disorders
• Cancer – osteosarcoma, Ewing’s sacroma

4

Musculoskeletal Development
• Vulnerable to external influence at various stages
• Dependent on the interplay of multiple factors including
hormones, nutrition and mechanical forces
• Prenatal: susceptible to morphologic abnormalities due to
exposure to pharmacologic agents, position constraints and
abnormal mechanical forces
e.g. Torticollis and clubfeet may result from position constraints late in the
pregnancy

• Postnatal: fast rate of bone remodelling at 50% annually vs adult
5% annually
5

Musculoskeletal Development
• Bone growth in
• Length: endochondral
ossification (also known as
epiphyseal growth)
• Diameter: appositional growth
by compressive force

• Increase weight bearing
results in increased
thickness and density of the
shaft of long bones
6

Musculoskeletal Examination
• History
• Obtained from caregiver and the child
• For juvenile and adolescents, questions regarding sexual maturation e.g.
Tanner staging for male and females and onset of menarche to provide
information related to bone age and development
• Postural screen & observation
• Posture, play, spontaneous movement and activity
• Note asymmetries and difficulty with age-appropriate skills
• ROM, muscle length and strength measurements

7

• Muscle tone, sensation and developmental skills
• Standardized testing both criterion and norm-reference tools for
evaluating developmental skills

Musculoskeletal Examination
• Limb alignment (rotational
and angular)
• Foot progression angle (A)
• Hip rotation (B, lateral
rotation; C medial rotation)
• Thigh-foot angle (D)
• Transmalleolar axis (E)
• Configuration of the foot
• Varus/ valgus posture

8

Leg Length Discrepancy
• Shortening or overgrowth of one or more bones of the leg
• Caused by
•
•
•
•
•
•

Congenital conditions such as limb deficiencies or hemihypertrophy
Infections
Fractures that involve the physis (often asymmetric and also cause angular deformities)
Neuromuscular disorders
Tumours
Trauma results in overgrowth and disease processes

• Significant LLD >2cm can lead to cosmetic and functional issues
• Less efficient gait and postural compensations of the leg, pelvis, and spine
often develop
• Postural compensations may not lead to a structural deformity
• Functional compensatory mechanisms include toe walking or foot and ankle
supination on the short side or vaulting, circumduction, persistent knee
9
flexion, or foot and ankle pronation on the longer side

Management of LLD
• Difference of 1 – 2 cm: A lift inside
the shoe or a custom-fabricated
external heel-sole
• Greater than 2 – 2.5cm:
• may suggest surgical treatment
options
• guided growth and growth restriction
of the longer limb or lengthening of
the shorter limb, or combined
approaches

• Devices: external fixators
(unilateral or circular) and internal
medullary lengtheners
10

Adapted from Hosny, 2020

Physiotherapy Management of LLD
• Physiotherapy intensity varies during the latency, distraction,
consolidation (fixator removal, healing and rehabilitation phase)
• Immediately after surgery: gait-training activities and promoting
early weight bearing if permitted (to facilitate bone growth), pin
care to prevent infection (wrapped with gauze to provide soft
tissue compression for reducing pain), stretching

11

Physiotherapy Management of LLD
Distraction phase:
• Frequent and focused on ROM (esp knee and ankle) and stretching along
with corresponding strengthening activity
• Maintaining the same ROM measurement over the duration of the distraction
phase actually represents increased muscle and soft tissue length i.e.
considered as successful ROM intervention progress
• Splinting
• Strengthening exercises (+ electrical stimulation and hydrotherapy)
• Tissue mobilization

12

Physiotherapy Management of LLD
Consolidation phase:
• Continue strengthening and tissue mobilization exercises
• For children who have undergone internal lengthening, increasing weightbearing progression through gait training as well as other activities will
be included in the PT program.
• Once ossification has reached an appropriate level, a cast or controlled
ankle motion (CAM) boot is placed following a tibial fixator removal, and
a knee immobilizer is placed following a femoral fixator removal to
protect the new bone during continued healing
• HEP to promote continued allowable stretching and strengthening of nonimmobilized joints
13

Physiotherapy Management of LLD
Rehabilitation phase:
• May last up to 1 year
• Aggressive stretching to achieve as much functional ROM as possible
• Flex casting and dynamic splinting as a stretching adjunct to address knee
flexion or extension and ankle plantar flexion contractures
• ROM status often regresses, so PT should remain steadfast and utilize soft
tissue mobilization techniques to maintain progress
• Strengthening activities are progressed as muscles and soft tissue are
further lengthened
• Functional activities and gait normalization as bone healing progresses and
muscle strength and ROM increase
• Postural reactions and balance training as the body accommodates to the
new limb length, limits of stability, base of support, and center of gravity
14

Legg–Calvé–Perthes Disease
• Self-limiting disease of the hip initiated by
avascular necrosis of femoral head
• Caused by vascular abnormalities and
dysfunction but precise cause of AVN
unknown
• Typically occurs between 3 – 13 years old
• Affected more boys than girls (3-5:1)
• Bilateral presentation is seen in 10-20%
of children with the disease

15

Clinical Presentation of LCPD
• Clinical presentation:

• a limp and pain referred to the
groin, thigh, or knee
• Hip F, IR and Abd ROM
limitations may develop
• Hip flexion contracture & a
Trendelenburg-type gait
frequently observed
• Muscle spasm of the hip
adductors and iliopsoas

• 4 defined stages
•
•
•
•

16

Necrosis (initial)
Fragmentation
Reossification
Remodelling (healed)

Adapted from https://perthesdisease.org/2016/09/08/getting-to-know-the-four-stages-of-perthes/

Management of LCPD
• Aims: to relieve the symptoms of pain and
muscle spasm, prevent or minimize femoral
head deformity, contain the femoral head in the
acetabulum while bone remodeling occurs, and
restore ROM
• Pain relief with anti-inflammatory medications
and traction

• Use of orthotic device such as a Petrie cast,
Scottish-Rite orthosis, or A-Frame orthosis or
surgical procedures such as a femoral or
innominate osteotomy

Petrie cast

• Post-operative physiotherapy
• restoration of hip ROM, muscular flexibility, and
strength esp. hip extensors and abductors due to longterm immobility
• gait training PWB → FWB
17

Scottish-Rite orthosis

Torticollis
• Latin word of “twisted neck”
• Noted in the first 2-3/52 after birth
• Unilateral shortening of
sternocleidomastoid (SCM) muscle
• a mass or fibrotic pseudotumor may be
observed or palpable within the belly of the
SCM muscle
• Ipsilateral cervical SF towards and
contralateral Rot away from the shortened
SCM
• May develop cranial and facial asymmetry
cause by plagiocephaly (skull flattening)
due to persistent asymmetric positioning of
the head
18

Clinical Presentation of Torticollis

19

Clinical Groups of Torticollis
• Aetiology unknown
• Possible causative factors include intrauterine malposition and
birth trauma
• Occlusion of blood vessels with resultant anoxic injury to SCM may
cause fibrotic changes
• 3 clinical groups
• Sternocleidomastoid tumour – definite mass or tumour is palpable within
SCM muscle
• Muscular torticollis – contracture of SCM muscle but no palpable mass
• Positional torticollis – both contraction of SCM muscle and a palpable
mass are absent but alteration in resting head position exists
20

Management of Tortillcolis
• APTA Clinical Practice Guideline (2018)
• Conservative management

• Infants aged 12 months or under
• Passive ROM and SCM stretching
• Active cervical ROM exercise e.g. Rot to involved side

•
•
•
•

• Visual tracking objects or respond to stimuli
• Equilibrium and right reaction
• Developmental play promoting UL weight bearing, weight shifting and reaching

Encourage mid-position
Tummy time
Caregiver education
Orthotic device e.g. Symmetry Through Active Remolding (STARband®) orthosis, the Dynamic
Orthotic Cranioplasty system (DOC band®)

• Injection of botulinum toxin in conjunction with physiotherapy
• Surgical release of SCM muscle
21

Righting exercises

Tummy time

Clubfoot

TEV

• Aka congenital talipes equinovarus
• Complex deformity
• CAVE: cavus (midfoot, high arch), adductus (forefoot adduction), varus
(hindfoot varus and pronation), equinus (ankle plantar flexion)
• Incidence 1-3:1000 live births, 50% bilateral involvement, male: female – 2:1
• Causative factors
• intrauterine positioning or neuromuscular impairment such asspina bifida,
myelomeningocele or arthrogryposis (decreased or absent fetal movement lead to
prolonged abnormal fetal positioning)
• A defect in mesenchymal cells forming the template for cartilaginous model of the
hindfoot structures (dysplasia) → pathologic deformities of bony and cartilaginous
structures and overall smaller appearance to involved foot and lower leg
• Genetic and chromosomal abnormality
22

Management of Clubfoot
• Aims:

• To restore alignment and correct the deformity
• To provide a mobile foot for normal function and weight
bearing

• Physiotherapy for mild postural clubfoot

• Passive mobilisation, splinting, strapping and active
correction with facilitation

• Ponseti treatment method

• Corrective phase (Weekly for 4-8 weeks) : serial casting with
manipulation to correct the forefoot adduction and pronation
and hindfoot varus along with percutaneous Achilles tenotomy
to correct equinus.
• Maintenance phase (for 4-5 years): long-term brace use to
maintenance correction

23

Clubfoot stretches

Developmental Dysplasia of the Hip
• Hip anomalies in infants and young children resulting from abnormal
growth and development of the joint
• Screening of all newborn for signs of hip instability
• 90% dislocatable hips can be stabilised by 9 week of age
• Aetiology likely multifactorial - malposition and mechanical factors in
utero such as a small intrauterine space, hormone-induced
ligamentous laxity, genetics, and cultural or environmental factors
• Risk factors include breech position, female gender, first-born child and
a positive family history of DDH
• Higher incidence of DDH with other congenital deformities such as
torticollis or metatarsus adductus
24

Clinical Presentation of DDH
• Types: Subluxatable, dislocatable, subluxed, or dislocated
• Clinical Presentation:
• Ortolani test and Barlow maneouvers (reliable before 2 months of age)
• Asymmetry of thigh, gluteal or labial folds, limitation of or asymmetric hip
abduction ROM (due to adductor longus shortening), apparent unequal
femoral lengths (Galeazzi sign)
• Positive Trendelenburg sign with unilateral involvement or waddling gait/
hyperlordosis with bilateral involvement for older children

• Imaging: US (radiography less preferred and usually for children >
6 months)
25

US Features of DDH

Adapted from https://leodonnan.com.au/the-stable-but-dysplastic-hip/

US Anatomy of Congenital Hip Dysplasia
26

(Kang & Koo, 2017)

Ortolani’s Test
• To detect the presence of a dislocated hip
• Procedures:
• Hips and knees 90F
• Thumbs on the medial side of the knee and index fingers over the greater
trochanters
• Abduct hip smoothly and gently to 90 degree

• +ve sign: palpable sensation or click sound of the femoral head
slipping into the acetabulum (indicates dislocated but reducible
hip)
• Restriction of hip abduction – irreducible hips
27

Barlow’s Test
• To identify unstable hip that lies in the reduced position but can
passively dislocated – dislocatable
• Procedures
• Examine one hip at a time
• Hip flexed and thigh adducted while pushing posteriorly in line of the shaft
of femur causing femoral head to dislocate posteriorly from acetabulum
• Palpable dislocation when femoral head slip out of acetabulum

28

Demo of Ortolani’s & Barlow’s Tests

Management of DDH
• Aims:

• To return the femoral head to its normal relationship within the acetabulum
• To maintain the alignment until the abnormal changes reverse

• <6 months old:

• Use of orthosis e.g. Pavlik harness (23-24h/day) to maintain hips in a flexed and abducted
position until hip is stable
• Possible complications include avascular necrosis of femoral head, femoral nerve palsy and
inferior dislocation
• Regular monitoring, caregiver education (e.g. positioning to facilitate prone skill), proper fit/
donning and doffing of the harness

• > 6 months old:

• Abduction orthosis or Closed reduction under anesthesia with application hip spica cast

• Surgical intervention for child older than 12 months

• May require femoral osteotomy or acetabular osteotomy to aid in relocating the femoral head
• Casting, regaining ROM, strengthening, gait training after operation

29

Anatomy of Paediatric Long Bone
1. Epiphysis: end of a long bone with
associated joint cartilage
2. Physis (growth plate): hyaline
cartilage plate to permits growth of
solid bone after birth and before
reaching maturity,
translucent(dark) in X-ray
3. Metaphysis: wide area below
physis, closest to the diaphysis/
shaft
4. Diaphysis: midshaft
30

Adapted from https://radiologykey.com/pediatric-skeletal-trauma-2/

Bone Healing in Children
• Rapid healing rate
• Strong and active periosteum which much more osteogenic
• Fast bone remodelling and physeal plate growth
• Spontaneous correction
• Bone healing timeframe for fracture shaft of femour
•
•
•
•
31

At birth: 3 weeks
8 years old: 8 weeks
12 years old: 12 weeks
20 years old: 20 weeks

Buckle/ Torus Fracture
• Common in children between 5-10 years of age due to the
elasticity of the bone
• Incomplete fracture
• Caused by compressive force
• Broken at one side and buckled outward at cortex on the other
without fully breaking
• Usually involving distal radial or tibia metaphysis
• Management: self-limiting, manipulation if angulation is severe,
cast/ splint for rest/ immobilization
32

Radiographic
features of Torus
Fracture
• Distinct fracture lines
are not seen
• Subtle deformity or
buckle of the cortex
• Angulation is the only
diagnostic clue in some
cases

33
Adapted from https://radiopaedia.org/articles/torus-fracture-1

Greenstick fracture
• Usually seen in young children <10 years old
• Incomplete unicortical fracture commonly at mid-diaphyseal region
• Force to side of the bone
• Broken at one side and bent at the other

34

Radiographic features
of Greenstick Fracture
• Usually mid-diaphyseal
• Occur in tandem with
angulation
• Incomplete fracture,
with cortical breach of
only one side of the
bone

35

Adapted from https://radiopaedia.org/articles/greenstick-fracture

Epiphyseal Fracture
• Common and up to 15% - 30% of fractures
in children
• Calcifying cartilage – weakest zone
• Blood supply enter from epiphyseal
surface
• Loss of blood supply to epiphysis will result
in necrosis and cessation of bone growth
• Salter-Harris Classification

Adapted from https://www.rch.org.au/fractureeducation/growth_plate_injuries/Physeal_growth_plate_injuries/

o Type I - S – straight across (incidence 6%)
o Type II - A – above (75%)
o Type III - L – lower or beLow (8%)
o Type IV - T – two or through (10%)

o Type V - ER – erasure of grow plate or cRush (1%)

36

o Type VI – avulsion: displacement of the
perichondral ring (added by Rang, 1969)

Type ?

Challenges in Diagnosis & Treatment
for Epiphyseal Fractures
• Cooperation during examination
• Radiation protection for children
• X-ray appearance
• Epiphysis may be mistaken as fracture line
• Comparison between two limbs required

• Reduction
•
•
•
•
37

Gentleness
Best to reduce on the day of injury
Method e.g. Type I & II managed mostly by casting
Period e.g. Double the time for Type IV epiphyses fracture

Complications of Paediatric Fractures
• Similar to adult – malunion, nonunion, neurological complications
• Physical plate injury may affect growth
• Osteomyelitis tends to be more extensive
• Joint stiffness is less common
• Fat embolism, pulmonary embolism and accident necrosis are
rarer
• Less tolerant to major blood loss
• Average blood volume ~75ml per kg body weight
• 500ml blood loss in a 20 kg child vs 60kg adult?
38

PT Management for Paediatric
Fractures
• Early mobilisation
• Prevent joint stiffness
• Gait training
• Prevent complications and deformities during bone growth

39

Scoliosis
• A complex, three-dimensional structural deformity of the
spine characterized by lateral curvature in the front plane,
vertebral rotation in transverse plane and possible
abnormal alignment in the sagittal plane
• Classified based on
• aetiology: congenital, neuromuscular, neural, iatrogenic,
idiopathic (unknown origin, 80% of cases) etc
• age of onset: infantile (0-2 years old), juvenile (3 – 9 years old),
adolescent (10-17 years old) and adult (≥ 18 years old)
• curve severity: low (up to 20˚), moderate (21˚-35˚), moderate to
severe (36˚- 40˚), severe to very severe (41˚-55˚) and very
severe (≥56˚)
• curve type: cervical, cervicothoracic, thoracic, thoracolumbar,
lumbar, Lenke system, Rigo system
40

Schematic illustrations of the
curve types of The Lenke
Classification
(Adapted from Lenke et al, 2001)

41

The Rigo Classification
The three-curve scoliosis pattern
described by The Rigo
Classification using clinical and
radiological criteria (Adapted from
Rigo et al, 2010).

42

Right thoracic curve

Left lumbar curve

Double major curves

Adolescent Idiopathic Scoliosis (AIS)
• Complex three-dimensional spinal deformity
• Predominantly occurs in females during peri-pubertal growth spurt
• Prevalence
• 1-4% globally (Cheng et al, 2015)
• 4.7% with curve ≥10° in Hong Kong (Fong et al, 2015)
• Girl-to-boy ratio of 2.2:1 for curves ≥10˚, 3.6:1 for curves ≥20˚, 5.5:1
≥40˚

• Indefinite etiopathogenesis
• Untreated or improperly treated AIS, the curve may deteriorate
leading to functional disabilities and morbidities in the severe
curves in adulthood
46

AIS: A Multifactorial Condition
Genetic

Skeletal
growth

Bone density
and qualities

47

Body
composition

Hormonal &
metabolic

Biomechanics

Central
nervous
system

Respiratory
system

Environmental
& lifestyle

Abnormal Bone Density and Qualities in
AIS
Deranged bone qualities

Lower areal BMD
•

Osteopenia which
persists to early
adulthood (Cheng et al, 2000 &

•

•

2006)

•

↓ Cortical bone area &
vBMD
↓ Trabecular number &
separation (Yu et al, 2014 & 2016)
↓ Stiffness, failure load &
apparent modulus (Cheuk et al,
2015)

aBMD & cortical vBMD identified as
prognostic factors for curve progression
Normal
48

AIS

Osteopenic AIS

(Hung et al, 2005 & Yip et al, 2016)

Abnormal body composition & muscle
dysfunction in AIS
•

Lower skeletal mass, body fat mass and body
mass index (BMI) associated with curve
progression in AIS (Ramirez et al, 2013; Clark et al, 2014 & Tam et al,
2016)

•

Larger muscle volume (Jiang et al., 2016) and increase
muscle activity at convex (Stetkarova et al., 2016)
→ secondary adaptation to ↑ load demand and
related to curve progression

49

Genetic & Hormonal Factors in AIS
Hormones related
to muscle deficits
& dysfunction
Leptin
Melatonin
Ghrelin
Calmoulin

(Lowe et al, 2002;Qiu et al, 2007; Girardo
et al, 2011; Zhong et al, 2013;Sales de
Gauzy et al, 2015; Yu et al, 2018; Favero
et al, 2019 &Liu et al, 2019)

Gene loci related to
muscle/ soft tissue
LBX1
BNC2
Fibrillin and collagen genes

(Londono et al, 2014;
Ogura et al, 2016;
Cheung et al, 2003 &
Tang et al, 2021)

Primary bone disease or primary soft tissue anomalies?
(Tang et al, 2021)
50

Biomechanical Factors in AIS
•

Imbalance skeletal growth and soft tissue
maturation altered mechanical loading exert to the
spine

•

Upright bipedal posture with spinal curvatures
predisposed an imbalance shearing forces in
thoracic and lumbar regions (Smit, 2002 & Kouwenhoven
et al, 2007)

•

Low bone density and low muscle mass reduced
skeletal loading exerting to the spine (Mehlman et al,
1997 & Smit, 2020)

51

Screening and Diagnosis of AIS
in Hong Kong
• School screening programme
• Uses Adam’s forward bending test (FBT), scoliometer
measurement of angle of trunk rotation (ATR) to assess students
in grade 5, 7 and 9 (mostly 10, 12 and 14 years of age)
• ATR > 5˚ or obvious signs of trunk or shoulder asymmetry, further
assessed by Moiré topography

SRS Scoliosis Screening Exam
52

Adam’s Forward Bending Test
• Useful in detecting rotational
deformity
• For initial screening of scoliosis is
often done
• Assess the angulation of rib hump
during forward bending
• Angle of trunk rotation (ATR)
measured with a scoliometer

53

Moiré Topography
• Useful in assessing rotational
deformity
• 3-D description of the shape of the
back
• Straight spine: Moiré shadow pattern
is equal on both halves of the back
• Structural scoliosis: asymmetry
pattern (indicating rotational
deformity) , the pattern differs more
with increasing deformity

54

Cobb Method
• Useful in measuring lateral deviation
• Cobb angle is commonly measured in
coronal plane (y-axis) by drawing a line
that is parallel with the angle of the
top border of the upper vertebra and
the bottom of the lower vertebra
involved in the curve
• The angle formed by the intersection
of these two lines is the Cobb angle
55

(Adapted from Cheng et al, 2015 & Lee et al, 2018)

Management of AIS
•
•
•
•

Close observation (Cobb angle <20˚)
Bracing (Cobb angle >20˚)
Physiotherapy Scoliosis- Specific Exercises (PSSE)
Surgical intervention (Cobb angle >50˚)

Treatment strategies based on remaining growth potential:
• Radiological method (assess skeletal maturity or bone age): Risser sign, Sanders
Classification System, Thumb Ossification Composite Index etc
• Anthropometric parameters: change in body height, arm span
• Biological milestones: status of puberty, onset of menarche (period)
• Degree/ location of curvature
• Gender
56

Bracing Treatment for AIS
• For patient with immature skeleton and high risk of
curve progression
• Aims

• to prevent curve progression reaching surgical threshold
• To restore normal contours and alignment of the spine by
means of external forces

• Most common to have rigid bracing
(thoracolumbosacral orthosis) made of thermoplastic
material (from elastic to very rigid materials)
• HK: 20h/ day (best up to 23h/ day) until skeletally
mature
• Monitor brace compliance with sensor (e.g. thermal
sensor)

57

Type of Bracing
(Adapted from Dunn et al, Screening for Adolescent Idiopathic
Scoliosis: A Systematic Evidence Review for the U.S. Preventive
Services Task Force [Internet]. Rockville (MD): Agency for Healthcare
Research and Quality (US); 2018 Jan. (Evidence Synthesis, No. 156.)
Table 1, Types of Braces for AIS. Available from:
https://www.ncbi.nlm.nih.gov/books/NBK493369/table/ch1.t1/ )

58
Charleston

Skeletal Maturity
• Risser’s Sign ≥ 4 and fused distal radius growth plate
• TOCI ≥ 8 (ossified sesamoid bone and fused phalangeal epiphysis)
• < 1cm change in standing height in the past 6 months and
• > 2 year post-menarche

Possible Complications with Bracing
• Unable to correct 3-D deformities (newer design try to improve 3-D
correction)
• May worsen thoracic hypokyphosis
• Muscle wasting
• Stiffness
• Pressure sore
• Allergy
• Psychological self-esteem
• Esophagitis from increase intra-abdominal pressure
• Poor compliance

Physiotherapy Scoliosis Specific Exercise
(PSSE)
• Early active intervention
• Endorsed by SOSORT observation, PSSE and bracing as interventions for
managing AIS during growth
• Different approaches or “schools” aims to treat 3-D scoliosis by realigning the
spine, rib cage, and shoulders and pelvis to “normal” anatomical postures
• Self-correction of curve and stabilization in correction
• Evidence supported the use of PSSE to treat mild-to-moderate curves e.g.
reduce Cobb and rotational angle, improve strength and vital capacity in AIS
and prevent surgery in majority of patients in combination with braces
• Requires expert training e.g. Schroth Method, Barcelona Scoliosis Physical
Therapy School (BSPTS), Scientific Exercise Approach to Scoliosis (SEAS) etc
61

Surgical Intervention
• Cobb angle >50 ˚
• Aims to prevent severe curve
progression
• Spinal fusion
• Instrumental surgical intervention
(e.g. vertebral body tethering)
• use of implant rods to straighten
and stabilize the curve

• Complications and morbidities

• Loss of motion at the fused spinal
segments
• Back pain
• Gastrointestinal complications
• Neurological complications
• Pulmonary dysfunction
• Infection
• Surgical failure

62

Key References & Further Reading
• Spearing, Pelletier, E. S., & Drnach, M. (2022). Tecklin's pediatric physical therapy (6th edition). Wolters Kluwer.
• Dysplasia/ deformities:
• Galloway, A. M., van-Hille, T., Perry, D. C., Holton, C., Mason, L., Richards, S., ... & Comer, C. (2020). A systematic review of the
non-surgical treatment of Perthes’ disease. Bone & joint open, 1(12), 720-730.
• Hosny, G.A. Limb lengthening history, evolution, complications and current concepts. J Orthop Traumatol 21, 3 (2020).
https://doi.org/10.1186/s10195-019-0541-3
• Yagdiran A, Zarghooni K, Semler JO, Eysel P. Hip Pain in Children. Dtsch Arztebl Int. 2020 Jan 31;117(5):72-82. doi:
10.3238/arztebl.2020.0072. PMID: 32070474; PMCID: PMC7054595.
• Paediatric fractures:
• Gimigliano F, Liguori S, Moretti A, Toro G, Rauch A, Negrini S, Iolascon G; Technical Working Group. A systematic review of
Clinical Practice Guidelines for the management of fractures in children to develop the WHO's Package of Interventions for
Rehabilitation. Eur J Phys Rehabil Med. 2022 Apr;58(2):236-241. doi: 10.23736/S1973-9087.21.06916-1. Epub 2021 Jul 12.
PMID: 34247473.
• Congenital muscular torticollis:
• Kaplan SL, Coulter C, Sargent B. Physical Therapy Management of Congenital Muscular Torticollis: A 2018 Evidence-Based
Clinical Practice Guideline From the APTA Academy of Pediatric Physical Therapy. Pediatr Phys Ther. 2018 Oct;30(4):240-290.
doi: 10.1097/PEP.0000000000000544. PMID: 30277962; PMCID: PMC8568067.
• Scoliosis:
•
Weinstein, S.L., et al., Adolescent idiopathic scoliosis. The Lancet, 2008. 371(9623): p. 1527-1537.
•
Cheng, J.C., et al., Adolescent idiopathic scoliosis. Nat Rev Dis Primers, 2015. 1: p. 15030.
•
Smit, T.H., Adolescent idiopathic scoliosis: The mechanobiology of differential growth. JOR Spine, 2020. 3(4): p. e1115.
•
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