Surgery: Principles of Fracture Management PDF

Summary

This document provides an overview of the principles of management for fractures. It covers topics such as classification, reduction, and immobilization techniques. The document also touches on soft tissue management and rehabilitation.

Full Transcript

PRINCIPLES OF
MANAGEMENT OF
FRACTURES
OUTLINE
INTRODUCTION
CLASSIFICATION OF FRACTURES
PRINCIPLES OF MANAGEMENT OF FRACTURES
RESUSCITATION
REDUCTION
RETENTION
SOFT TISSUE IMMOBILIZATION
REHABILITATION
CONCLUSION
REFERENCES
INTRODUCTION
A Fracture is a break in the continuity of a bone.
It is:
1. Closed (Simple) when there is no laceration of the skin overlying it.
2. Open (compound) when there is a laceration of the skin which
communicates with it thereby allowing the fracture to communicate
with the outside environment. A compound fracrure is said to be
'compound from within' when the laceration of lhe skin is caused by a
fragmemt of the broken bone and 'compound from without ' when
the laceration is caused by the force which gave rise to the fracture.
3. A pathological fracture is one which occurs in an abnormal or
diseased bone. The force required to produce the fracture is minimal
or trivial, The disease may be localized (e.g. cyst or metastasis) or
generalized (e.g. osieoporosis or rickets)
CLASSIFICATION
Based on several ways:
Extent
Location
Morphology
Mechanism
Associated soft tissue injuries
Based on Extent.

Complete: fracture extends 360
° of bone circumference (all
around).
Incomplete: seen almost only in
children:
Greensick
Buckle fracture
Based on the Location.

Name of bone
Side
Diaphysis, metaphysis or epiphysis
Long bones (diaphysis): divide them in thirds (proximal, middle or
distal third)
Morphology:

Transverse: is one in which the
bone is broken almost
transversely across and is
caused by either an indirect
bending force or a direct
tapping force.
Morphology:

Oblique: is oblique in outline
and also results from bending
indirect violence. The bone
fragments tend to be displaced
as a result of the muscles even
after reduction.
Morphology:

Spiral: is one in which the
fracture is spiral in pattern. It is
caused by twisting force from
indirect violence.
Morphology:

Comminuted fracture: is one in
which there are more than two
fragments at the site of a
fracture. lt is often caused by
direct violence or crushing
injury.
Segmental fracture: is one in
which the affected long bone is
broken at two or more distlnct
levels.
Mechanism:

High energy vs. low energy.
Multiple injuries vs. isolated injury.
Pathological fracture: normal load in the presence of a weakened bone
(tumor, osteoporosis, infection)
Stress fracture: normal bone subjected to repeated load (military
recruits).
Associated soft tissue injuries:
Close fracture: skin integrity is maintained.
Open fracture: fracture hematoma is exposed to external
environment.
PRINCIPLES OF MANAGEMENT OF
FRACTURES
The goals of treatment of fractures are:
1. Reduction of the fracture to correct any deformity and restore
normal anatomy.
2. Adequate immobilization of the fracture to maintain reduction
and the alignment of the bone during healing and also to
promote healing. Adequate immobilization must be
maintained until union of the bone is sound.
3. Maintenance of joint mobility by active movement of the joints
not immobilized.
4. Maintenance of muscle tone by exercising the muscle of the
affected limb during immobilization.
 These are the principles of management
1. RESUSCITATE
2. REDUCTION
3. RETENTION
4. SOFT TISSUE MANAGEMENT
5. REHABILITATION
RESUSCITATION
RESUSCITATION using the ATLS principle (PRIMARY AND
SECONDARY SURVEY)
Airway maintenance and cervical spine control
Breathing
Circulation
Disabilities: brief neurological assessment
Exposure
Splintage to prevent further damage by movement of fragments
Antibiotics
Analgesics
Antitetanus (Subcut 1500IU ATS)
REDUCTION
It is achieved by:
1. Closed manipulation whenever possible
2. Open reduction if closed manipulation fails or is not likely to
succeed.
Closed Reduction
A. Closed manipulation
Under general, local or regional anaesthesia, the fractured
fragments are manipulated with a force opposite in direction to
the one that produced the fracture in order to restore the normal
anatomy.
OPEN REDUCTION
Open reduction implies the opening of skin or mucusa to
visualise the fracture and inspect the adequacy of reduction with
our eyes.
INDICATIONS
1. Failure of closed reduction.
This may be due to:
(i) interposition of some tissues between the fractured fragments.
(ii) displacement of the fracture fragments by contraction of the
muscles.
(iii) displacement of inaccessible intra-articular fragments e.g.
fractured head of radius.
(iv) late unreduced fracture.
2. Failure in maintaining reduction after closed manipulation in
certain types of fractures e.g. oblique or spiral fracture of the tibia,
transverse fracture of the patella.
3. Fractures that cannot be reduced by the closed method e.g.
fractures around joints.
4. Difficulty in getting hold of a short fractured fragment e.g.
fracture dislocation of the shoulder.
5. Associated arterial injury.
RETENTION BY IMMOBILIZATION
lmmobilization after reduction is by
(a) splints
(b) traction.
(c) Fixation
a) The splints are usually made of plaster of Paris (POP) but may
be of wood, metal, external fixators or light weight casting
material such as Scorch cast or Fibreglass.
b) Traction: Continuous traction on a limb also immobilises the
fracture and maintains the alignment of the bony fragments. It is
used in lower limb fractures. The leg is put in a suitable frame.
The traction may be (i) skin traction or (ii) skeletal traction.
i) Skin traction: A non-elastic adhesive plaster is attached to the
skin and a weight applied to a cord leading from this adhesive
plaster. Skin traction cannot be used when weights more than 5kg
are needed for traction as this tends to rip off the adhesive plaster.
ii) Skeletal traction: A metal wire or pin e.g. Steinman's pin is
inserted into the bone below the fracture and attached to a weight
through a cord which pulls the bone to correct the deformity.
lnternal fixation

Different types of materials
are available for the intenal
fixation of a fracture ie. wire,
screws, pins, plates and
intramedullary nail. Stable
bone fixation is the aim and
makes external
immobilization often
unnecessary. These materials
are made of stainless steel,
titanium or vitallium which is
cobalt-chromium-
molybdenum alloy.
 External skeletal fixation
The fracture is fixed externally with a special external metal frame.
Pins are inserted into the bone above and below the fracture and
then fixed into the external metal frame. Fixation is rigid.
This method is indicated in severe open fractures especially of the
tibia, femur, humerus, radius and ulna if there is marked soft tissue
damage with skin loss which may require frequent dressing or skin
grafttng. It allows ready access to the wound. It is also indicated in
closed fractures in patients with multiple trauma, head injury or burns,
in fractures requiring distraction (e.g. bone loss) and in non-union.
The external metal frame may be single e.g. the Orthofix or Oxford
External Fixation, or double e.g. Hoffman's Fixator. Some external
fixators have modifications that allow them to be used for limb
lengthening procedures in patients with bone loss and shortening e.g.
Ilizarof fixator
 There are two types of the external fixators. We have the circular
and the linear.
Components of the linear ex-fix include; Pins(schantz screw,
denham’s pin and steinman’s pin), clamps and connecting rod
Components of circular ex-fix; Pins, wires, clamps and frame
The prime disadvantage of an external fixator is the ‘pin sites’.
These pin sites require care as they may become infected or
tether soft tissues, thereby interfering with function.
REHABILITATION
The main aim of treatment is to return the patient to a similar
level of premorbid function as quickly as possible.
It is important to move the affected joints and the joints in close
proximity to the fracture (e.g. elbow and shoulder exercise while
in a cast for a distal radial fracture), limiting global stifness and
wasting of the muscles on that limb.
COMPLICATION
EARLY LATE
Infection Non-union
Compartment syndrome Mal-union
Haemorrhage Shortening
Osteomyelitis
Hypovolaemic shock
Osteoarthritis
Septicaemia
Volkman’s ischaemic
Fat embolism contracture
Crush syndrome DVT&PE
Disuse atrophy of affected limb
CONCLUSION
Fracture is the one of the common orthopaedic conditions and
as such, appropriate and effective measures should be taken to
save life of patient, save the limb, save joint and restore
function(as much can be restored).
REFERENCES
Baja’s priciple and Practice of Surgery 5th Edition
Bailey and Love