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The purpose of this
course is to teach the healthcare professional how to identify and
respond to compartment syndrome.
Upon completion of this
module the learner will be able to:
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1. |
Describe risk factors and
etiologies of compartment
syndrome |
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2. |
List the three types of
compartment syndrome |
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3. |
List and describe the
clinical manifestations (6
P’s) of compartment syndrome |
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4. |
Identify prevention and
treatment of compartment
syndrome |
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5. |
Teach patient education
concerning compartment
syndrome |
Compartment syndrome, if not
identified and acted upon early,
will result in irreversible damage
to neuromuscular soft tissue.
Therefore, the healthcare
professional must be aware of the
risks, signs and symptoms, unusual
circumstances, and appropriate
interventions with this syndrome.
Compartment syndrome is a
life-threatening condition in which
increased tissue pressure in a
confined anatomical space causes
decreased blood flow leading to
ischemia and dysfunction of
contained myoneural elements. It is
marked by pain, muscle weakness,
sensory loss, and palpable tenseness
in the involved compartment.
Ischemia can lead to necrosis
resulting in permanent impairment of
function. Increased pressure within
the compartment results from
bleeding and swelling into the
closed space which in turn causes
pressure on the vital structures.
There is elevation of interstitial
pressure in a closed fascial
compartment that results in
microvascular compromise. As the
duration and magnitude of
interstitial pressure increases,
myoneural function is impaired and
necrosis of soft tissues eventually
develops. Compartment syndrome can
occur where there is significant
edema in a compartment within the
hand, forearm, upper arm, buttock,
legs, feet, and occasionally the
abdomen. Usually compartment
syndrome occurs due to fractures of
the tibia or forearm, in vascular
injuries, or burns. Almost any
injury or surgery can cause the
condition.
Arteries and their subdivisions
bring freshly oxygenated blood to
the tissues, and the associated
venous system returns deoxygenated
blood to the venous circulation. The
human body has a number of areas
that function as closed compartments
to this delivery system. There are
three main compartments in the
forearm and four main compartments
in the lower leg. The long bones of
the limbs, for example, are joined
and surrounded by sheets of tough
and relatively inelastic tissue
called fascia which create
comparatively inflexible boundaries.
The placement of the fascia is such
as to divide the leg, for instances,
into a number of sections or
compartment. These compartments
contain muscles, arteries, veins,
and nerves. These compartments
generally have a fairly constant
volume that permits only slight
variation. If swelling occurs in
these compartments the subsequent
rise in compartment pressure can
cause serious damage.
The arterial blood system continues
to bring blood into the compartment,
but low pressure veins and their
subdivision have a low intra-luminal
pressure that is restricted. When
this occurs it is further compounded
by the release of fluid from the
blood vessels resulting in a further
rise in compartment pressure that
perpetuates the cycle. Edema within
the closed compartment will increase
the pressure within that compartment
eventually compromising the vascular
supply. Such compromise will lead to
further ischemia and edema
formation. A vicious cycle will be
established as cells become deprived
of oxygen.
Subsequent necrosis of muscle and
loss of capillary wall integrity
will lead to transudation,
exudation, and the development of
massive edema within the
compartment. Rhabdomyolysis then
occurs. Rhabdomyolysis is the
dissolution or breakdown, of
striated muscle that results in the
production of myoglobin. Myoglobin
is known to cause acute renal
failure. If untreated,
rhabdomyolysis may lead to
myoglobinuria, permanent
neurovascular damage, renal failure,
sepsis, and even death. This occurs
as the myoglobin is released into
the circulation where it can occlude
the distal convoluted tubule and
precipitate renal failure.
Significant fluid loss into damaged
tissues leads to hypovolemia and
metabolic acidosis. This not only
acts as a potent pre-renal cause for
renal impairment but also enhances
the nephritic effect of myoglobin.
Severe metabolic complications may
present after reperfusion when the
damaged membranes continue to leak,
aggravating edema formation and
increasing the pressure in the
closed osteofascial compartment.
Rhabdomyolysis is well documented as
a secondary cause in a range of
conditions related to skeletal
muscle injury.
The syndrome may develop as quickly
as within the first 30 minutes to
1-2 hours post trauma. Or it may
develop postoperatively, post
fracture reduction, or in as late as
5-6 days. If it is allowed to last
for more than 6 hours, neuromuscular
damage becomes irreversible.
Splinting, traction, early closed
reduction with casting, or early
surgery for fractures reduce the
risk of Compartment Syndrome.
There are three categories of
etiology:
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1. |
Decreased compartment size
can be caused by restrictive
dressings, splints or casts,
excessive traction, or
premature closure of fascia. |
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2. |
Increased compartment
content can be caused by a
fracture that causes
bleeding or from a vascular
injury, burns, infiltrated
IV infusion, swollen or
inflamed bowel, or
snakebites. The first
response is to elevate the
extremity. However, when the
extremity is elevated too
high above heart level, this
compromises arterial
perfusion, which further
compounds the ischemic
problem. |
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3. |
Externally applied C can be
caused from restrictive
dressings, prolonged
compression from lying on a
limb or crushing injuries of
soft tissue. |
Damage to limbs, particularly the
legs, related to nerve damage and
unchecked intra-compartmental
pressures were documented as long
ago as 1872 by Richard von Volkmann.
The combination of nerve-related
damage and compartment syndrome
causing contracture related to a
supracondylar fracture is still
referred to as Volkmann contracture.
Damage caused by hypertension or
ischemia related to the limbs, and
the association with rhabdomyolysis,
was described by surgeons during
World War II in patients who had
sustained severe muscle injury.
Today compartment syndrome following
prolonged pelvic surgery is an
uncommon, but a well documented
complication.
Abdominal compartment syndrome has
been recognized for years, but the
term abdominal compartment syndrome
(ACS) was only introduced in the
1980s. The risk of life-threatening
elevation in intra-abdominal
pressure is not limited to
postoperative patients. Other causes
that may cause an increased pressure
include hemorrhage, edema, distended
bowel, mesenteric venous
obstruction, tense ascites,
peritonitis, and tumors.
A delay in diagnosis is the most
important determinant of a poor
patient outcome. Patients with a
history of trauma, surgery,
extravasation, diabetes, poor
neurovascular status, or infection
are at risk. Although more commonly
associated with trauma or surgery on
the limbs, compartment syndrome has
been reported as a complication of
some positions adopted for surgery,
particularly the lithotomy and
knee-chest positions. Various
studies identify serious
complications following surgery,
particularly when the lithotomy
position was used during urological
surgery. The consequences for the
patient are devastating, often
resulting in multiple fasciotomies,
chronic pain, and weakness.
The possibility of developing
compartment syndrome and
rhabdomyolosis is especially high in
the presence of other risk factors
including obesity, peripheral
vascular disease, and prolonged
duration of surgery. Compartment
syndrome has been described in
instances of drug overdose where
persons have remained in one
position for several hours, with the
force supplied by the weight of
their body on the extremity being
the causative mechanism for the
syndrome developing.
Within the operating suites, the
success of many surgical procedures
depends upon satisfactory exposure
of the operative site, which often
is achieved by placing patients in
physiologically abnormal positions.
With perceptive powers of the
patient no longer intact, postural
insults may occur that normally
would not be tolerated in the awake
state.
Variations on the lithotomy position
are used for many procedures. A
modified lithotomy trendelenburg
(with additional head-down tilt)
provides optimal combination
approaches (abdominal and perineal)
for complex urological, colorectal,
and gynecological surgical
procedures. This position allows the
legs to be supported on
multi-jointed operating table leg
supports rather than lithotomy pole
stirrups that reduce the degree of
hip flexion and support the calves
in semi-cylindrical padded cushions.
The lower leg may be secured by soft
straps or bandaging. While the
practitioner ensures that the
patient is positioned safely and
correctly to minimize joint strain
and pressure points, there is very
little done to prevent the
possibility of compartment pressure
increases.
It is difficult to prevent any
increase in compartmental pressure
by the very nature of the position.
The patient may be wearing
compression stockings (if these are
too small the problem will be
compounded) and will likely have
intermittent compression devices
attached to each lower leg. The leg
will still receive a degree of
direct compression against calf
support and it is essential to
ensure that surgical assistants do
not lean on the leg and provide
additional compression.
Reduced perfusion is inevitable. The
elevation of the legs above the
heart reduces limb perfusion that
may be compounded by the head-down
tilt. Other factors related to limb
perfusion may be hypotension
(induced by anesthesia or
sympathetic block) and
surgically-induced pressure on major
vessels during episodes of the
procedure which may also affect
venous return for short periods.
Pre-existing arterial disease may
also be a contributory factor. When
surgery is prolonged, the risk of
compartment syndrome is increased.
Most literature refers to long
surgical procedures (six hours or
longer) but it is now thought that
much shorter episodes can also be
responsible.
Compartment syndrome usually
presents after reperfusion of a
limb. Pain and swelling may not
occur immediately. The first signs
usually occur after the patient has
regained consciousness, undergone
their post-anesthetic care, and
returned to the unit. Often several
hours are reported as uneventful
before the first signs and symptoms
are reported. The first suspicions
are usually aroused when a patient
complains of severe pain in the
lower legs when they have recovered
consciousness or a few hours after
surgery. Some patients may even
describe pain despite postoperative
epidural anesthesia. The patient’s
leg may appear tense and swollen.
The level of pathological pain is
found to be far greater than the
ordinary postoperative pain to be
expected from the surgical
intervention.
The diagnosis of compartment
syndrome requires a high index of
clinical suspicion. Timing of
identification and intervention with
compartment syndrome is crucial to a
positive patient outcome. It is
possible that an initial diagnosis
of deep vein thrombosis (DVT) may
interfere with the correct
diagnosis. The measurement of
compartment pressures will confirm
the suspicions of compartment
syndrome while venous Doppler
studies will confirm a DVT. Remember
the “6 P’s” of compartment syndrome:
Other warning signs of Compartment
Syndrome:
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1. |
Fractured blisters:
represent areas of necrosis
of the epidermis and
separation of the skin
layers. Occur as the body
attempts to relieve the
pressure in the compartment. |
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2. |
Laboratory findings:
elevated WBC (white blood
cell count) and ESR
(erythrocyte sedimentation
rate) levels due to the
severe inflammatory response |
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3. |
Elevated temperature due to
ischemia/necrosis of tissue
and possible infectious
response. |
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4. |
Elevated Serum Potassium due
to cell damage. |
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5. |
Lowered Serum pH levels due
to acidosis |
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6. |
Stretch pain or pain on
passive extension or
hyperextension of digits
(toes or fingers, depending
on the site) |
Don’t lose valuable time waiting for
laboratory findings. Be vigilant to
assessment of the “6 P’s”
When compartment syndrome is
diagnosed and treated early, full
recovery usually follows. When
initial signs and symptoms appear,
loosen any external constrictive
dressings or cut the cast. Other
measures are to position the
extremity at the level of the heart
not above the heart and provide
adequate hydration of the patient to
maintain arterial blood pressure.
Accurately monitor compartment
pressures.
Medical decompression may be
instigated if compartment syndrome
is suspected and intra-compartment
pressures are only marginally
increased. A mannitol infusion has
been reported as effecting a
complete resolution.
Fasciotomy, or surgical
decompression, is a surgical
incision of the affected
compartments. It may be required if
conservative interventions are not
effective in interrupting the
edema-ischemia cycle. As soon as the
fascia is sectioned, or surgically
split open by an incision through
all layers down to and including the
fascia, the compartmental contents
can bulge, thus allowing pressures
to decline along with reinstitution
of the normal circulatory pattern.
If performed Fasciotomy should be
done in less than 6 hours and no
later than 12 hours after onset of
symptoms. If the procedure is
performed during this time frame it
is likely to prevent myoneural
deficits. Fasciotomy must be
undertaken by a skilled surgeon,
ensuring that all compartments (for
instance all four in the lower leg)
are accessed through a single
lateral incision or double vertical
whenever possible.
During fasciotomy it is vital to
identify and protect nerves. Wounds
are usually left open protected by
suitable sterile dressings.
Inspection of the wound after 48
hours may necessitate further
necrotic tissue excision. Delayed
skin closure or skin grafting may
become treatment options. Adequate
analgesia and antibiotic coverage
are essential for improving
outcomes.
In cases where treatment and
prophylaxis of renal failure
associated with rhabdomyolysis is
suspected or diagnosed, prompt fluid
and metabolic correction is
essential to re-establish a good
urine output. Mannitol has also been
beneficial as a renal vasodilator
and intravascular expander and aids
to induce osmotic diruesis. If these
methods fail dialysis may be
necessary.
Patient and staff education should
include general education about
compartment syndrome itself,
treatment, healing, and prognosis.
Staff should clearly understand what
procedures should and should not be
done to prevent compartment
syndrome. Discharge education should
include wound care, infection
prevention, extremity mobility/range
of motion as allowed, and continued
neurovascular assessments.
Current knowledge related to the
risk of compartment syndrome when
caring for patients of trauma or
when operating in positions that put
the legs higher than the heart when
not absolutely necessary can be
deemed negligent. If it means
repositioning and re-draping, thus
adding extra minutes to the surgical
time and costing a small amount in
additional drapes, surely this is a
small price to pay for excellent
perioperative care. The main goal in
care of the patient with compartment
syndrome is to maintain tissue
function and viability.
Anglen, J., Banoventz, J., 1994
Clinical Orthodedics & Related
Research. (301): 239-42, Apr.
Bocca, G., van Moorselaar, J., Wout,
F., van der Staak, F., Monnens, L.,
2002 Compartment Syndrome,
Rhabdomyolysis and Risk of Acute
Renal Failure as Complication of the
Lithotomy Position, Journal of
Nephrology 15 (2) 183-185.
Pearse, M., Harry, L., Nanchahal,
J., 2002 Acute Compartment Syndrome
of the Leg, British Medical Journal
325: 558-559.
Raza, A., Byrne, D., Townell, N.,
2004 Acute Compartment Syndrome
After Urological Pelvic Surgery,
Journal of Urology 171: (1) 5-11.
Tal A., Lask, J., Keslin, J., Livine,
P.M., 2004 Abdominal Compartment
Syndrome: urological aspects;
British Journal of Urology
International 93: 474-477.
Warrell, D., Cox, T., Firth, J.,
Benz, E., 2003 Oxford Textbook of
Medicine 4th ed, Vol. 3, Sections
18-33, p 257, Oxford, Oxford
University Press. |
