Lesson 4 - fractures and bone healing.pdf

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Orthopedics (Berlusconi)

B&J – Lesson 8

Ratti - Rizzardi

Fractures and bone healing
A long bone is made generally by three
components: the diaphysis or shaft, the
epiphysis at the proximal and distal
extremities and a narrow portion in between
called metaphysis1. The rationale of
subdividing the bone in regions is that each
part differs in vascularization and thus, in time
required for bone healing. Epiphyses are
faster than diaphysis in healing since the
formers are very well vascularized while the
latter is supplied by only one vessel.
When a bone is cross-cut, it is possible to
recognize 2 portions: the cortex (or compact
bone) and the cancellous bone (or
trabeculated part).
The periosteum is wrapped around the bone in close contact with the compact bone; this structure
is crucial in many homeostatic processes of the bone including bone healing.
The Wolff’s law states that a bone is able to remodel, changing its density, in response to the applied
forces; the main consequence of this law is that where there are flexion (compression) forces the
bone is thicker due to adaptive changes in the internal architecture of the trabeculae followed by
secondary changes in the external cortex.
For example, the medial part of the femur figured on the left, being
weightbearing, will be thicker than the lateral one that is subjected to
tension. In case of fracture, a metal device should be applied in the
lateral side in order to sustain the lateral wall in tension and
antagonize the compression in the medial site.
Thus, when treating a fracture, it is important to know where are both
the compression and the tension side of the bone in order to apply
forces against the normal biomechanics that wouldn’t allow the
fracture to heal.
Another important implication of the Wolff’s law is that in children
when there is a fracture there may be remodelling of the bone, also
if the bone is displaced in respect to the axis.
Fractures
A fracture is an interruption of bone continuity and it can be traumatic (caused by a force superior
to the bone resistance), pathologic (caused by a reduced bone strength) or surgical (performed in
order to achieve any therapeutic aim).
The bone can undergo a fracture either where the force has been applied (direct trauma fractures)
or at a distant site (indirect trauma fractures that are divided into Flexion fractures, Torsion fractures,
Compression fractures, and Avulsion fractures).
Fractures due to their heterogeneity are classified according to various features:
• basing on lesion level (diaphysis, epiphysis and metaphysis).
• basing on joint involvement, fractures can be articular or extra-articular.

1

The Metaphysis contains the growth plate, the part of the bone that grows during childhood, and as it grows it ossifies
near the diaphysis and the epiphyses.

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B&J – Lesson 8

Ratti - Rizzardi

•

basing on fragment contact, fractures can be displaced or non-displaced. In a displaced
fracture, the bone snaps into two or more parts and moves so that the two ends are not lined
up straight. The contact between the fragments is fundamental for healing, thus in displaced
fractures the surgeon has to align the segments.

•

basing on skin involvement fractures can be closed or open (compound fracture). In open
fractures, the bone is exposed to external environment and they can be due either to the bone
that punctures the skin or to laceration of the skin from outside. Open fractures can be
complicated by bacterial infections and their healing can be delayed/absent (non-union) due to
impaired blood flow caused by soft tissue damage.
According
to
Gustilo-Anderson
classification - that bases on the
extent of soft tissue damage, the
extent of contamination and energy of
the trauma - open fractures can be of
5 grades:
- Grade 1: open fracture, clean
wound smaller than 1 cm in length.
- Grade 2: open fracture, wound in
between 1 and 10 cm in length
without extensive soft-tissue damage, flaps, avulsions.
- Grade 3: open fracture with adequate soft tissue coverage of a fractured bone despite
extensive soft tissue laceration or flaps, or high-energy trauma (gunshot and farm injuries)
regardless of the size of the wound. The surgeon is able to close it.
- Grade 3b: open fracture with extensive soft-tissue loss, periosteal stripping and bone
damage. Usually associated with massive contamination. Will often need further soft-tissue
coverage procedure. Surgery is not enough to close the skin.
- Grade 3c: open fracture associated with a vessels and nerves injury requiring repair,
irrespective of degree of soft-tissue injury.
The preferred approach for open fractures is surgery that consists in anatomical reduction of
the fracture (realignment of bone portions) if it is displaced followed by wound cleaning and
positioning of external fixator (internal fixators are not used as they may increase soft tissue
damage). Antibiotic prophylaxis with broad-spectrum antibiotics is always performed.

•

basing on damage entity, fractures can be:
- complete, further divided in:
o transverse fracture when the trauma is
in a specific point and the break occurs
at a right angle to the axis of the bone.
A transverse pattern indicates a high
energy fracture.
o oblique fracture which occurs at an
angle other than right angle to the axis
of the bone.
o spiral fracture2 which is caused by
twisting a bone excessively. This type of fracture heals faster than others since the
contact may be maintained. A spiral pattern indicates a low energy fracture.
o comminuted high-energy fractures, characterized by the presence of multiple lines of
fractures.
o complex
- incomplete further divided in green stick and infraction.

2

The torsion of the bone can occur due to leg sprain while walking, running or jumping or due to the turn of the upper
while playing iron arm.

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Bone healing
The bone is able to heal itself with 2 different mechanisms according to the type of fracture:
• sanatio per primam intentionem (primary
healing) can occur only in case the fragments are
in perfect strict contact with each other and the
fracture line is simple3.The process consists in the
formation by osteoclasts of tunnels between the 2
fragments, in which eventually osteoblasts migrate
and start to fill the tunnels with new bone. For this
process, absolute stability is required: the two
fragments must never move one against the other.
At x-ray, no deformities or growth can be seen.
•

secondary intention/healing occurs in case the fracture line is not simple or there are multiple
fragments not in contact between them. This process relies on the formation of a callus that
requires few steps:
1) Inflammatory Phase: characterized by the presence of hematoma and the granulation tissue
around the bone, which is not really visible on plain films.
2) Fibrocartilaginous Callous (aka soft callus) Formation: fibroblasts, recruited during
inflammatory phase, from the periosteum invade the fracture site and start proliferating, forming
a fibrocartilaginous bridge with collagen fibers
around the fracture. This process is not visible on
plain films either.
3) Endochondral ossification which is the
process by which cartilage is turned into bone
4) Bony Callous Formation: osteoblasts start
producing spongy bone trabeculae, and the fibrous
tissue is slowly converted into spongy bone. The
area starts becoming more radiopaque.
5) Bone Remodeling is a long process of restitutio
ad integrum and may require few years. Compact bone replaces spongy bone around the
periphery of the fracture.

According to the type of bone healing (per primam or
per secondary intention) we want to achieve, a
different kind of therapeutic approach is chosen. The
rules that regulate the choice are based on Strain
Theory by Stephan Perren. This theory states that:
• If there is a narrow simple fracture line,
absolute stability is required, which can be
achieved by inter-fragmentary compression
together with neutralization. This results in a Per
primam intentionem healing.
• If there is a wide complex fracture line, relative stability is required, which can be achieved
just with a bridge fixation, this technique essentially consists in the application of some devices
(nail, external fixation, cast, plating) in order to bridge the 2 (or more) fragments of the bone in
order to keep them together. This results in secondary healing with callus formation.
If the two principles are mixed, the fracture will never heal.

3

Comminuted fractures cannot have per primam healing.

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The process of bone healing is strongly variable regarding the timing and the efficiency;
many factors related to the patient influence either positively or negatively the
process: for example, age. Indeed, in children the biological process of bone
remodelling is more active than in adults; this grants to children to have, even in case
of dislocated fractures, a correct and faster healing even without anatomical reduction.
This is possible until the growth plate is still open, so up until 10 years of age.
If a child experiences a femur fracture (image on the right), after 3 weeks the callus
starts to form, then calcifying process begins and in 12 weeks it becomes a bony callus.
In 6 months, bone remodelling occurs following the Wolff law.
Active life (sportsmen) favors healing increasing blood circulation while healing is
delayed by immobility and absence of gravity. Also, diet4 can influence bone
healing. Hormones have different actions for example, corticosteroids5 slow healing while
Estrogens6, PTH7 and GH improve healing.
Patient comorbidities, such as diabetes, neuropathies, anemia, vitamin deficiencies (A, C, D and
K especially), infections and drugs (anti-inflammatory, anti-hypertensive and anti-coagulative) slow
healing as well as habits as smoking and alcohol.
Local factors include infections, tumors, necrosis, denervation, local damage (soft tissues and
vascularity), bone loss, type of bone and blood supply. Bone portions that have a terminal blood
supply (arterioles don’t have any collaterals but splits directly into capillaries) are more prone to face
Avascular necrosis (AVN), examples are the distal tibia, the talus, the neck of the femur and the
scaphoid bone.
Surgical factors include surgical damage of the periosteum (as it harbours the precious blood flow),
hardware (since the choice of the right implant is crucial), gap (as a too large gap impedes the
healing), weightbearing (a little weightbearing is crucial for the healing process) and stability of
fixation.
Absence of pain together with remodelling phase at x-ray are indicative of complete healing. The
process of healing is defined as union or consolidation. Nonunion is permanent failure of healing
unless surgery is performed; nonunion may occur when the fracture moves too much, has a poor
blood supply or gets infected. A fracture with nonunion generally resembles, in structure, to a fibrous
joint, and is therefore often called a "false joint" or pseudoarthrosis. The diagnosis of nonunion is
generally done when there is no progress between two x-rays. Still it is possible to predict nonunion
by seeing the fracture able to move during the remodelling phase e.g. femoral fractures usually heal
in 3 months, thus if after the 3rd month there is still movement at the fracture site, healing cannot
occur without external intervention.
Radiological evaluation of traumas
Dislocations and Sprain
The dislocation (in Italian lussazione) is the complete loss of contact between articular ends of 2
bones within a joint, while a subluxation is only a partial loss of contact between the 2 articular
ends. Instead, a sprain (in Italian distorsione) is defined as wrenching or twisting of a joint, with
partial or complete rupture of its ligaments.
4

Consuming 1200-1500 mg of calcium and 800-1000 IU vitamin D can help in keeping bones strong.
Long-term use of corticosteroids is associated with 35% of all cases of nontraumatic AVN (avascular necrosis). Doctors think
these drugs may affect your body's ability to break down fatty substances. These substances collect in the blood vessels -- making
them narrower -- and reduce the amount of blood to the bone. That can lead to AVN.
6
Estrogen deficiency is known to increase osteoclast bone resorption, whereas estrogen replacement can reverse this
effect. Estrogen seems to be an important factor in all stages of fracture healing. The application of estrogens
enhances fracture healing of long bones at least in mice.
5

7

could increase bone mineral density to accelerate fracture healing.

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Since the precise location of the injury may be difficult to understand, especially in the pelvis, when
the patient refers trauma and pain, a visit followed by an x-ray is necessary. If an injury to a joint is
suspected, the doctor when reading x-ray has to consider in order:
1. the joint line evaluating its size and continuity.
2. the relationship between the bones.
3. the shape of bones. Deformities can have several etiologies for
example dysplasia.
4. the position of tuberosities. For example, in a femur it is important
to check if the greater and the lesser trochanter are in place.
In case of trauma to the pelvis it is important to
assess if the head of the femur is inside the socket (hip joint) and if there is
a good line in the symphysis pubis and in sacro-iliac joint.
In the X-ray on the right, the head of the femur is not in place. If the x-ray is
not informative enough to assess the direction in which the head has been
displaced, CT, MRI or x-ray in other projections are indicated. Displacement
direction is fundamental to choose the maneuver to put the head back in the
socket.
The x-ray on the left shows that the patient has undergone a prosthetic
surgery (total joint replacement) of the right hip joint, since
screws (viti) and metal are present. Whenever screws are
present, surgeons and radiologists have to pay attention since
screws may go over the ileo-pectineal line where iliac vessels
pass. On the left there’s a clear deformation of the femoral head
together with its upward displacement resulting in a length
difference of the 2 lower limbs (this can be assessed by
comparing the position of the left and right trochanters). This
total asymmetry quite surely is physically visible with the limping
of the patient.
In case of trauma to the knee, the doctor has to evaluate the
relationships between the tibia & the fibula, the patella which
is visible in AP view and medial & lateral condyles which are
visible in lateral view.
The medial condyle is located where the tibia has a concave
shape in strict contact with the convex part of the femur while
The lateral condyle is located where the convex tibia profile
is near the concave part of the femur.
The x-ray on the left shows a dislocation of the knee:
the tibia has moved anteriorly. An antero-medial
dislocation of the tibia may cause severe damage to
the arteries and also nerves. Thus, a dislocation must
be reduced immediately in order to prevent damage to
the very important structures.

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On the top there’s a normal ankle joint while in the
bottom there’s the x-rays of a patient that reported a
fracture of the distal fibula (lateral malleolus) and an
anterior dislocation of both the fibula and the tibia.
Probably, this patient puts the foot in a bad way on the
floor resulting in the torsion of the ankle joint in the
articulation of the knee joint: sprain and torsion create
a spiral fracture.
In these settings, the first concern is soft tissues
around.
Fractures
• Shaft.
A whole bone x-ray in both AP and lateral view is necessary to
evaluate a fracture of the shaft. For example, in case of fracture
of the shaft of the femur the x-ray has to comprise both the hip
joint and the knee joint to assess direction of displacement,
presence of metal in the knee or the hip, asymmetry in shaft
and/or in epiphysis either of the femur or of the tibia. Afterwards,
cortex shape, continuity and thickness and bone shape have
to be evaluated.
The picture on the left is a good example of a stress fracture8,
that may be the result of long usage of an
external fixator. The external fixator
indeed can cause microfracture of the lateral tension side, leaving the
medial weightbearing side more stable. The fracture is incomplete as the
line does not span the entirety of the bone and it can be classified as close
and undisplaced. The axis, rotation and length of the bone are normal.
Moreover, it should be classified as transverse, but usually this type of
fractures are the result of high energy trauma. This condition requires an
external intervention (surgery aimed at increase the tension side
thickness) since it is not of traumatic origin, but it is the result of the failure
of the internal biomechanics of the bone. Moreover,
surgery is required since in this situation the stabilization
of the bone needs the activation of the intrinsic healing potential of the organ.
On the right, an oblique displaced fracture is present. The femur is shortened
and externally rotated and the patella is lateral translocated. The latter is the
result of the incapability of the shortened femur to bear gravity force. This
condition can be assessed in the initial part of the physical examination, since
during inspection of the patient in lying position, he will have the foot externally
rotated (result of femoral fracture) with the hip in normal position (otherwise a
problem in the hip or in the muscles could be suspected). What is peculiar of
this image is the density of the cortex; in fact, the proximal part is normal but
getting distal, the cortex is not anymore smooth and with a normal thickness.
This anomaly was revealed to be a metastasis from a squamous-cellular
carcinoma of the lung.
•

Epiphysis evaluation starts with the assessment in 2 view x-rays of the intraarticular line, density of the bone and relationship between bones.

8

A stress fracture is a fatigue-induced fracture of the bone usually caused by repeated stress over time. Instead of
resulting from a single impact, stress fractures are the result of accumulated trauma from repeated submaximal loading,
such as running or jumping. Because of this mechanism, stress fractures are common overuse injuries in athletes.

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On the right, there’s a
patellar fracture that
impairs the extension of the
knee joint since the patella
is the site of insertion of the
quadriceps tendon and of
the patellar tendon. This
displacement needs
surgical intervention to
reconstruct the extensor
mechanism.
Clinical case 1: a 71 years old lady has been hitten by a car while walking. She comes to the ER in
a wheelchair, she can’t walk and has a lot of pain on the knee. Soft tissues are not affected, the knee
is not swollen, but it’s stiff.
To make a first analysis of the X-rays (AP and lateral view):
1. Follow the joint line evaluating its size and continuity.
2. Look at the relationship between the bones: there’s no difference,
they are in contact.
3. Look at the density and shape of bone. The cortex is thin because
she’s 71 years old and probably she is affected by osteoporosis.
Moreover, in both the projections there’s a white line that revels
abnormalities in the density of the tibia (red circles).
4. Look at position of tuberosities. Lateral view allows to evaluate the
alignment of two condyles: in a healthy subject the latters should
overlap. Condyles may not align either because the condyle is
divided in two parts or because the limb is externally rotated (the x-rays has been done wrongly).
In this case, there’s the displacement of the lateral condyle of the tibia.
The CT shows a big gap due to a loss of bone in the tibial lateral
side and cartilage pulled downward (white line9): the fragment
has gone at least 2 cm inside the tibia, it’s comminuted and
rotated. Probably, the depression of cartilage occurs, during
falling of the old woman, as a result of torsion associated to
compression10 (the lateral condyle of the femur exerts a big force
on the lateral meniscus that pushes the lateral cortex of the
proximal tibia downwards).
Without intervention the
meniscus enters the bone. This condition is surgical: the
fragments have to be reduced to assure the healing of the
fracture and prevent the deviation of the knee.

9

The cartilage is harder in consistency than the epiphysis medulla so at X-ray it appears as a white line.
This is what often happen in young patients in a skiing injury: a proximal tibial plateau fracture.

10

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Clinical case 2: a 35ys old man cannot move the shoulder after a
motorvehicle accident.
In this x-ray it is not possible to assess properly the relationship
between bones, the head cannot be precisely defined since the
humerus is displaced and turned.
With a tridimensional CT reconstruction,
it is possible to determine that the head
of the humerus is massively displaced
posteriorly and that the shaft has been
shortened.
Moreover, the head of the humerus has
a difficult blood flow, just like the main
part of the epiphysis. Indeed, a fracture
or especially a dislocation of the head
may disrupt the vascular supply of the humeral head and, even if the
surgeon reduces it perfectly, that head will lose its vitality because the blood
flow has been disrupted in the accident.
In this surgical image the clamp moves the head
and it possible to appreciate the shaft of the
humerus. It is also possible to observe the
glenoid fossa which is empty: the femoral head
needs to be moved from posteriorly into place
where it is kept in place by an internal fixator.

Clinical case 3
This is an open Gustilo 2
fracture at x-ray and CT. In this
setting, the classification is
important to understand if the
fracture has interrupted the
ligaments.
The tibia is laterally dislocated
and there’s a spiral fracture of
the fibula with comminution on
one side.
For the fact that it’s a joint
fracture it must be reduced anatomically to allow immediate
movement and weight baring.
In the first hospital setting, reduction of bone
portion at the attachment of the deltoid
ligament is carried out and the latter gets
fixed by sutures too. Still, reduction was not
successful and the internal fixation (x-ray on
the left) of the lateral malleolus, that is
shortened,
externally
rotated
and
comminuted, is necessary to allow absolute
stability for the healing to be carried out.

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