8.1 - Management of specific fractures

Question 1

What is trauma?

Answer 1

Emergency broken bone support

Question 2

What is a fracture?

Answer 2

Break in the structure of bone associated with a soft tissue injury

Question 3

What is orthopaedics?

Answer 3

More longer-term conditions e.g. osteoarthritis

Question 4

How do we assess and manage trauma in hospitals?

Answer 4

• fracture usually the least important bit
• advanced trauma life support - keep patient alive first
  
  • airway, breathing, circulation, disability
  • occasionally treat as part of ‘C’
• reduce fracture
• hold fracture (plaster, external fixator, internal fixation)
• rehabilitate (normally 6 weeks later)

Question 5

What are the principles of orthopaedics?

Answer 5

• history and examination
• look –> feel –> move
• investigations e.g. X-ray

Question 6

What are the clinical signs of a fracture? (5)

Answer 6

• pain
• swelling
• crepitus
• deformity
• collateral damage - adjacent structural injury –> nerves/vessels/tendons/ligaments

Question 7

How do we investigate fractures? (3)

Answer 7

• X-ray (radiograph) - in most cases
• CT sometimes indicated (to make diagnosis, to assess pattern)
• MRI if unsure

Question 8

How do we describe fracture radiographs?

Answer 8

• demographics (ABC - adequacy, bones, cartilage)
• location - which bone, which part of bone? (proximal, distal, midshaft, intra-articular if extends into joint surface)
• pieces - simple/multifragmentary (comminuted)?
• pattern - transverse/oblique/spiral?
• displaced/undisplaced?
  
  • translated/angulated?
  • X/Y/Z plane?
  • rotation
  • impaction
• stable/unstable?

Question 9

What two types of bone movements can we have in a displaced fracture?

Answer 9

• translation
• angulation

Question 10

What direction is the movement of bone in translation?

Answer 10

Straight line movements where you can have:

• medial/lateral translation (X)
• proximal/distal translation (Y)
• anterior/posterior translation (Z)

Question 11

What direction is the movement of bone in angulation?

Answer 11

Rotation movements:

• varus/valgus movement (X) is in coronal plane towards/away from midline
• internal/external movement (Y) in axial plane
• dorsal/volar movement (Z) in sagittal plane

Question 12

What is direct fracture healing?

Answer 12

• anatomical reduction (ends of bone very close, often stable fracture)
• absolute stability/compression
• no callus
• (primary bone healing - intramembranous, mesenchymal SC–>osteoblast = direct formation of woven bone)

Question 13

What is indirect fracture healing?

Answer 13

• sufficient reduction
• micromovement (needed to heal)
• callus
• (secondary bone healing - endochondral, involves periosteum and external soft tissues, relatively stable fracture, mesenchymal SC–>chondral precursor–>bone cells produced)

Question 14

What is the process of indirect fracture healing?

Answer 14

1. haematoma formation (bleeding between bone ends)
2. inflammation –> cytokines released –> granulation tissue and blood vessel formation
3. repair - chondroblasts/osteoblasts make soft callus (type II collagen - cartilage) which is converted to hard callus (type I collagen - bone)
4. remodelling - callus responds to activity, external forces, functional demands and growth (osteoblasts); excess bone is removed

Question 15

What is Wolff’s law?

Answer 15

Bone grows and remodels in response to the forces that are placed on it

Question 16

How long does it take fractures in different bones to heal?

Answer 16

• 3-12 weeks depending on site and patient (usually 6 weeks)
• signs of healing visible on XR from 7-10 days
• general: upper limbs/hands quicker than lower limbs/feet
• phalanges: 3 weeks
• metacarpals: 4-6 weeks
• distal radius: 4-6 weeks
• forearm: 8-10 weeks
• tibia: 10 weeks
• femur: 12 weeks

Question 17

What are the main principles of fracture management? (3)

Answer 17

• reduce - bring fracture ends together
• hold - hold ends in right position with/without metal
• rehabilitate - once bone has healed, limb is still weak = needs rehabilitation

Question 18

What are the two types of reduction?

Answer 18

• closed - pull bones together without opening skin
  
  • manipulation
  • traction - skin / skeletal (pins in bone)
• open
  
  • mini-incision
  • full exposure

Question 19

What are the different ways of holding a fracture?

Answer 19

• plaster/splint (closed)
• fixation
  
  • internal/external
  • intramedullary/extramedullary
  • monoplanar/multiplanar (external)

Question 20

What are the general complications of fractures (early/late)? (4)

Answer 20

• fat embolus
• DVT
• infection
• prolonged immobility (UTI, chest infections, sores)

Question 21

What are some specific complications of fractures? (6)

Answer 21

• neurovascular injury
• muscle/tendon injury
• non union/mal union
• local infection
• degenerative change (intra-articular)
• reflex sympathetic dystrophy

Question 22

What factors affect fracture healing? (2)

Answer 22

• mechanical environment - movement, forces
• biological environment - blood supply, immune function, infection, nutrition

Question 23

What are the causes of neck of femur (NOF) fractures in older vs younger patients?

Answer 23

• osteoporosis in older patients
• trauma in younger patients
• combination of both

Question 24

What do we want to know about patient’s history in NOF fracture? (4)

Answer 24

• age
• comorbidities - respiratory/cardiovascular/diabetes/cancer
• preinjury mobility - independent/shopping/walking/sports
• social history - relatives? stairs at home? alcohol?

Question 25

What is the significance of the intertrochanteric line?

Answer 25

• intertrochanteric line runs between greater trochanter and lesser trochanter
• capsule sits on intertrochanteric line
• above intertrochanteric line = intracapsular fracture (worry about blood supply)
• below intertrochanteric line = extracapsular fracture (blood supply likely preserved so head of femur likely to survive)

Question 26

What are some examples of intracapsular and extracapsular fractures by location? (5)

Answer 26

• subcapital (intracapsular)
• transcervical (intracapsular)
• basicervical (intracapsular)
• subtrochanteric (extracapsular)
• 3-part intertrochanteric (extracapsular)

Question 27

What kind of NoF fracture is more likely to have an interrupted blood supply?

Answer 27

Intracapsular = risk of avascular necrosis (death of bone due to lack of blood) is higher

Question 28

What feature is seen on XR that can help us identify a NoF fracture?

Answer 28

Shenton’s line (from medial edge of femoral neck to inferior edge of superior pubic ramus) - loss of contour can indicate NoF fracture

NB: not always abnormal in NoF fracture

Question 29

How do we determine whether to fix or replace a fracture? (3)

Answer 29

• location of the fracture
• degree of displacement
• age

Question 30

Flowchart for treating NoF fractures.

Answer 30

• extracapsular –> internal fixation (plate and screws - dynamic hip screw or nail)
• intracapsular?
  
  • displaced - <55y/o = reduce and fixation with screws, >65y/o = replace (total hip replacement if fit and mobile, hemiarthroplasty if less fit)
  • undisplaced –> fixation with screws

Question 31

How do shoulder dislocations present? (4)

Answer 31

• variable history but often direct trauma
• pain
• restricted movement
• loss of normal shoulder contour

Question 32

What is the clinical examination for shoulder dislocation?

Answer 32

Assess neurovascular status - axillary nerve

Question 33

How do we investigate shoulder dislocations?

Answer 33

• X-ray prior to any manipulation - identify fracture e.g. humeral neck, greater tuberosity avulsion or glenoid
• scapular-Y view/modified axillary in addition to AP

Question 34

How do we manage shoulder dislocations?

Answer 34

• numerous techniques to reduce a dislocated shoulder
• vigorous/twisting manipulation should be avoided to avoid fractures
• safest method is traction-counter traction +/- gentle internal rotation to disimpact humeral head
• ensure adequate patient relaxation e.g. Entonox or BZs
• if alone could use Stimson method (using hanging weights)
• undertake in safe environment, especially in elderly e.g. resus, ask for senior/anaesthetic support early on if necessary

Question 35

What is a complication of shoulder dislocation?

Answer 35

Hill Sachs defect - as humerus comes out, bangs on glenoid and a fleck of bone comes off (Bankart lesion) –> recurrent shoulder dislocation

Question 36

What are the three ways of managing a distal radius fracture?

Answer 36

• cast/splint
• MUA and K-wire
• ORIF

Question 37

When is cast/splint done for distal radius fracture?

Answer 37

• temporary treatment for any distal radius fracture - reduction of fracture and placement into cast until definitive fixation
• definitive if minimally displaced, extra-articular fracture

Question 38

When is MUA and K-wire done for distal radius fracture?

Answer 38

• for fractures that are extra-articular but have instability, particularly in children
• MUA (manipulation under anaesthesia) in theatre with K-wire (Kershner wire - pin in wrist) fixation can be used
• wires can be removed in clinic post-op

Question 39

When is ORIF done for distal radius fracture?

Answer 39

• Open Reduction and Internal Fixation
• any displaced, unstable fractures not suitable for K-wires, or with intra-articular involvement
• uses plates and screws

Question 40

What is another example of a fracture in the hand?

Answer 40

Scaphoid fracture

Question 41

What are some examples of wrist fractures? (3)

Answer 41

• Colle’s fracture - from fall on an outstretched hand
• Smith fracture - from fall on a flexed wrist/direct blow to the back of the wrist
• Barton’s fracture - intra-articular fracture

Question 42

What causes a tibial plateau fracture?

Answer 42

• proximal tibia comprises a key weightbearing surface as part of the knee joint, articulating with distal femur
• tibial joint surface is relatively flat and comprises both medial and lateral plateaus with a central tibial spine acting as insertion point for ligaments
• any extreme valgus/varus force or axial loading across knee can cause tibial plateau fracture, with impaction of the femoral condyles causing the comparatively soft bone of tibial plateau to depress or split

Question 43

What other injuries are associated with tibial plateau fractures?

Answer 43

Concomitant ligamentous or meniscal injury

Question 44

For which tibial plateau fracture patients do we do non-operative management?

Answer 44

• only truly undisplaced fractures with good joint line congruency assessed on CT/high fidelity imaging
• reduce, hold, rehabilitate

Question 45

What operative management is there for tibial plateau fractures?

Answer 45

• predominance of treatment will be operative
• restoration of articular surface using combination of plate and screws
• bone graft or cement may be necessary to prevent further depression after fixation

Question 46

What is the Gustillo-Anderson classification for open (tibial plateau) fractures? (Extra info?)

Answer 46

• type I - puncture wound <1cm, minimal contamination and soft tissue damage
• type II - laceration 1-10cm, moderate soft tissue damage, adequate bone coverage, minimal comminution
• type IIIA - laceration >10cm, extensive soft tissue damage, adequate bone coverage, segmental/severely comminuted fractures, heavily contaminated wounds
• type IIIB - as IIIA but with periosteal stripping and bone exposure
• type IIIC - any open fracture with vascular injury requiring repair

Question 47

What is the most commonly fractured bone in ankle fractures?

Answer 47

Fibula

Question 48

What is a Weber A fracture?

Answer 48

Below ankle joint without damage to ligaments

Question 49

What is a Weber B fracture?

Answer 49

At the level of ankle joint and may extent to fibula

Question 50

What is a Weber C fracture?

Answer 50

Above ankle joint, unstable

Question 51

How do we manage ankle fractures non-operatively?
And for which patients is this suitable for?

Answer 51

• non-weightbearing below knee cast for 6-8 weeks, can transfer into walking boot and then physiotherapy to improve range of motion/stiffness from joint isolation
• Weber A i.e. below syndesmosis and therefore thought to be stable
• Weber B if no evidence of instability (no medial/posterior malleolus fractures and no talar shift)

Question 52

How do we manage ankle fractures operatively?

Answer 52

• soft tissue dependent - patients need strict elevation as injuries often swell considerably
• ORIF +/- syndesmosis repair using either screw or tightrope technique
• syndesmosis screws can be left in situ but may break after some time so therefore can be removed at a later date if needed
• Weber B (if unstable fracture - talar shift/medial or posterior malleoli fractures)
• Weber C (i.e. fibular fracture above the level of the syndesmosis therefore unstable)