1. SUBJECT SEMINAR ON
“COMPARTMENT SYNDROME
AND VIC”
Moderator :
Dr GAURAV M
Asst proffesor ( Dept of orthopedics )
Presenter :
Dr NAGESH SHERIKAR
postgraduate ( Dept of orthopedics )
BANGALORE MEDICAL COLLEGE
3. A closed area of muscle groups, nerves and blood
vessels sorrounded by fascia
Muscles are arranged in different compartments and
sorrounded by one fascia , this arrangement is called
osteofascial compartment
Normal pressure : 5-15 mmhg
Intracompartmental pressure raises to 35-40 mmhg
WHAT IS COMPARTMENT ??
4. Acute compartment syndrome is defined as an elevation
in osteofascial compartment pressure to a level and for a
duration that without decompression will cause tissue
ischemia and necrosis.
Volkmann ischemic contracture is a sequeal of
untreated or inadequately treated compartment syndrome
in which necrotic muscle and nerve tissue have been
replaced with fibrous tissue.
DEFINITION
5. Is the elevation of intracompartmental pressure during exercise, causing
ischemia, pain, and rarely neurologic symptoms and signs
It is characterized by resolution of symptoms with rest but may proceed to
acute compartment syndrome if exercise continues.
CHRONIC EXERTIONAL COMPARTMENT SYNDROME (CECS)
6. 1881: Richard von Volkmann - contracted state believed
due to ischemic muscle
1884- Lesser developed clinical model
1888- Peterson felt due to nerve compromise
1906- Hildebrand coined ' volkmans ischemic contracture '
1914- Murphy recommended FASCIOTOMY to prevent
contracture
1940- Griffiths 4p's
1967- Whiteside stressed 4 compartment FASCIOTOMY
HISTORY
7. Incidence- 3.1/ 100,000
Mean age was 32 years ; males - 30 years
Females - 44 years
M>F( 10 times )
Younger > older patients
Open = closed #
LEG IS THE COMMONEST SITE.
TIBIAL FRACTURE IS COMMONEST CAUSE AND ANTERIOR COMPARTMENT IS
MOST FREQUENTLY INVOLVED
FOREARM IS 2ND COMMONEST SITE, SUPRACONDYLAR FRACTURE IS THE
COMMONEST CAUSE WITH FLEXOR COMPARTMENT MOST FREQUENTLY
INVOLVED
EPIDEMIOLOGY
8. I. Acute compartment syndrome (ACS)
medical emergency
caused by a severe injury
can lead to permanent muscle damage.
II. Chronic compartment syndrome (CCS)
known as exertional compartment syndrome
not a medical emergency
most often caused by athletic exertion.
Types of Compartment syndrome:
13. A. BLEEDING
FRACTURES
The most common reason for abnormally
increased tissue pressure.
In adults - closed and open tibial shaft
fracture , distal radial fracture
In children -radial head or neck fracture ,
supracondylar fracture
1. INCREASED IN VOLUME OF COMPARTMENT CONTENTS
14. SOFT TISSUE TRAUMA ( muscle rupture) rugby players , forestry
workers
SURGERY
Following surgical treatment by the knee arthroscopy , Hauser
operation, proximal tibia osteotomy without drainage and
intramedullary nailing of the tibia
Postoperative hematoma
15. B. EDEMA
Venous stasis
Capillary leak syndrome
Exercise -Exercise-induced edema by marching and mountain
climbing may be another reason
Inflammation
16. A. EXTERNAL COMPRESSION
All induce a postischemic
reperfusion injury to the
capillary bed. Tissue hypoxia
induces dysfunction of the
endothelial cells of the capillary
bed, which may leak plasma and
water into the interstitial space.
2.PROLONGED ISCHEMIA
17. External compression by tight
bandages such as orthoses, plaster
cast, or elastic stockings increases
intramuscular pressure.
A tight plaster cast decreases the
compliance of compartment tissues. A
normal swelling of a limb may
therefore create pathologically
increased intramuscular pressure
18. B. ARTERIAL OCCLUSION
if exceeds 6 hours of complete
ischemia, the endothelial
cells most likely will be damaged
and leak plasma into the interstitial
space
C. LIMB ELEVATION
Patients with arteriosclerosis and
diabetes --- increased risks for
insufficient blood perfusion and
development of ischemia.
19. A.FASCIAL DEFECT
B. BURN INJURY
◼ The constrictive effects of circumferential burns may cause acute compartment
syndromes which may be relieved by long, linear incisions through the skin along
the axis of the extremity.
3. DECREASED SIZE OF THE COMPARTMENT
21. 1. Arteriovenous Gradient Theory : Rowland
The increase in local tissue pressure reduce the local arteriovenous
pressure gradient and thus reduce blood flow . When flow diminishes to less
than the metabolic demands of the tissue ( not necessarily to zero ) , then
functional abnormalities result
The relationship between AV gradient and local blood flow ( LBF) is
summarised as
LBF = PA-PV ×R
THEORIES
22. The ultimate result of reduced blood flow to skeletal muscle is
Ischemia followed by necrosis , with increasing periods of complete
Ischemia produce increasing irreversible change .
The duration of muscle Ischemia dictates the amount of necrosis
Examples
EFFECT OF RAISED TISSUE PRESSURE ON MUSCLE
23. There is little dispute about the effects of raised tissue pressure on
neurologic function.
EFFECTS ON NERVE
EFFECTS ON BONE
Non union
25. CLINICAL PRESENTATION
Pain out of proportion
Pallor
Paresthesia/hypoesthesia
Paralysis
Pulselessness
These are signs of an ESTABLISHED
compartment syndrome where ischemic
injury has already taken place
5P's
26. Earliest symptom
Classically out of portion to injury
Severe pain with passive stretch
Pain that is not responsive to the normal dosage of pain
medication
sensitivity -19% ,
specificity of 97% (i.e., a high proportion of false-
negative or missed cases but a low proportion of false-
positive cases)
PAIN
27.
28. PARESTHESIA
First sign of nerve Ischemia
Followed by hypoesthesia, anesthesia , paresis , paralysis
Peripheral nerve tissue is more sensitive than muscle to ischemia
Permanent damage may occur in 75 minutes
sensitivity -13%
specificity - 98%
30. Rarely present
Indicates direct damage to vessels rather than compartment syndrome
PALLOR AND PULSELESSNESS
(presence of a pulse does not exclude the diagnosis)
31. • Compartment pressure - objective
parameters
• Lab tests : Pulse CPK, Urine myoglobin
• Pulse oximetry :
• Is helpful in identifying limb hypoperfusion
• Is not sensitive enough to exclude
compartment syndrome.
33. Raised tissue pressure is primary event in compartment syndrome
and changes in ICP precede the clinical signs and symptoms.
When to monitor ?
Where to monitor ?
Threshold for diagnosis of Compartment syndrome and
fasciotomy ?
PRESSURE MONITORING
34. Suspected compartment syndrome
Equivocal or unreliable examination findings
Unconscious patient with tight compartments
Vascular injury
Regional anesthesia
WHEN ??????
35. INDICATIONS :
◼High risk
TECHNIQUE : performed each compartments at close to the
fracture site as possible ( highest pressure ) or maximal swelling
area
36.
37.
38. 1.Needle manometer method/ WHITESIDES saline infusion technique
Performed by using a needle introduced into the compartment and connected to a column filled
partly with saline and partly with air .To this column a syringe filled with air is attached , as is a
pressure manometer or transducer .
Advantage -simple and inexpensive
Disadvantage –
1.Not suitable for continuous monitoring
2. Required injection of saline into the compartment and in this way could aggravate impending
syndrome
3. Least accurate
4. Needle with only one perforation at its tip also can become easily blocked.
METHODS
39.
40. 2. The wick catheter-Mubarak et al
modification of the needle technique, in which fibrils protrude from the bore of
the catheter assembly. This allows a large surface area for measurement and
prevents obstruction of the needle
Advantage - Ideal for continuous measurement
Disadvantage –
1. Blood clot blocking the tip or air in the column of fluid between the catheter and
the transducer, which will dampen the response and give falsely low readings.
2. retention of wick material in the tissues.
41. 3. slit catheter- Rorabeck et al.
same principle as the wick catheter in that it is
designed to increase the surface area at the tip of
the catheter by means of being cut axially at the
end of the catheter.The interstitial pressure is
measured through a column of saline attached to
a transducer .
The slit catheter is more accurate than the
continuous infusion method
as accurate as the wick catheter
42.
43. 4. solid state transducer intracompartmental catheter (STIC)
44.
45.
46.
47. THRESHOLD FOR DECOMPRESSIVE FASCIOTOMY
Mubarak -- Fasciotomy when >30-40mmHg
Matsen -- >45 mmHg developed ACS
Whitesides -- Fasciotomy when within 20mmHg of DBP
McQueen -- Fasciotomy when within 30mmHg of DBP
Heppenstall – within 40mmHg MAP
48. Also known as exertional CS, recurrent CS and subacute CS
Exercise –induced pain
Bilateral in 80-95% of patients
Occur mainly in the lower limb
Incidence is equal among male nd female young athletes
Typical patient is young (20-30s) athlete
Pathophysiology of CCS
Probably occurs from increased muscle relaxation pressure during exercise ,
which causes decreased muscle blood flow, leading to ischemic pain and
impaired muscle function
CHRONIC COMPARTMENT SYNDROME
49. ◼Exercise can increase muscle volume by 20% , causing an increase in
pressure in a noncompliant Compartment
50.
51.
52. One or more among the following:
1.Pre-exercise pressure >=15mmHg
2.Post-exercise pressure at 1 minute >=30 mmHg
3. Post exercise pressure at 5 min >= 20mmHg
DIAGNOSIS
53. Conservative-
◼ Cessation of causative activity
◼ Rest.
◼ Ice
◼ Physical therapy
◼ FASCIOTOMY IS THE ONLY PROVEN SUCCESSFUL TREATMENT
MANAGEMENT
56. COMPLETELY remove the cast , bandages and dressings
The limb should be NURSED FLAT
(DO NOT ELEVATE as elevation reduces the arterial inflow and the arterio-venous
pressure gradient on which perfusion depends )
Ensure patient is normotensive as hypotension reduces perfusion pressure and
fascilitates further tissue injury
Oxygen administration
Correct hypoperfusion with iv fluids and blood products
EMERGENCY TREATMENT
57. Fasciotomy - prophylactic release of
pressure before permanent damage occurs.
Will not reverse injury from trauma.
Fracture care – stabilization with
– Ex-fix
– IM Nail
SURGICAL TREATMENT
58. Unequivocal clinical findings
Pressure within 15-20 mm hg of DBP
Rising tissue pressure
Significant tissue injury or high risk pt
> 6 hours of total limb ischemia
Injury at high risk of compartment syndrome
FASCIOTOMY INDICATIONS
59. Make early diagnosis
Full and adequate decompression
Long extensile incisions
Release all fascial compartments
Any muscle necrosis must be thoroughly
debrided to avoid infection
Preserve neurovascular structures
Coverage within 7-10 days
No scope for limited or subcutaneous
fasciotomy
FASCIOTOMY PRINCIPLES
60. Within 6 hours - Almost complete recovery
Within 12 hours ~ 60-70% normal limb function
More than 12 hours ~ 8% normal limb function
TIMING OF FASCIOTOMY
70. Both volar and dorsal fasciotomies may be performed. In most cases the volar compartment is
approached first through an incision extending from the biceps tendon at the elbow to the palm
of the hand to allow carpal tunnel decompression that is usually necessary .
Fascial incision then allows direct access to the compartment . The deep flexors must be carefully
inspected after fascial incision. Separate exposure and decompression of pronator quadratus may
be necessary.
Usually volar fasciotomy is suff icient to decompress the forearm but if ICP remains elevated in
the dorsal compartment perioperatively, then dorsal compression is easily performed through a
straight dorsal incision .
76. Is performed through
anterior and posterior
incisions when the
compartments are easily
visualized.
On rare occasions the
deltoid muscle should also
be decompressed
FASCIOTOMY
79. HAND FASCIOTOMY
Two Dorsal incisions along 2nd and
4th MC
Can reach the adductor
compartment via 2nd MC incision
80.
81. Both thigh compartments
can be approached
through a single lateral
skin incision
Medial incision can be
used over the adductors if
considered necessary
THIGH
86. Traditionally five compartments (lateral, medial, central, interosseous,
and calcaneal)
Dorsal incisions overlying the second and fourth metacarpals allow
sufficient access to the interosseous compartments and the central
compartment that lies deep to the interosseous compartments .
The medial and lateral compartments can be accessed around the deep
surfaces of the first and fifth metatarsal, respectively
FOOT FASCIOTOMY
87.
88.
89.
90.
91.
92.
93. Fasciotomy incisions must never be closed primarily because this
may result in persistent elevation of ICP.
The wounds should be left open and dressed, and approximately 48
hours after fasciotomy a “second look” procedure should be
undertaken to ensure viability of all muscle groups.
Skin closure or cover should not be attempted unless all muscle
groups are viable.
WOUND MANAGEMENT
94. FIRST STEP :
1. VAC - reduces swelling , promotes tissue granulation and increased perfusion
2.. Wet to dry dressings - will remove wound drainage and dead tissues
SECOND STEP : ( wound closure techniques) 2 days after surgery
1. Delayed primary closure
2. Split thickness skin grafting- High long term morbidity
3. Continous traction
4. Acell- creates new layer of skin in fasciotomy wound
95.
96. • Altered sensation within the margins of the wound (77%)
• Dry, scaly skin (40%)
• Pruritus (33%)
• Discolored wounds (30%)
• Swollen limbs (25%)
• Tethered scars (26%)
• Recurrent ulceration (13%)
• Muscle herniation (13%)
• Pain related to the wound (10%)
• Tethered tendons (7%)
FASCIOTOMY- COMPLICATIONS
97. Delay to fasciotomy of more than 6 hours is likely to cause significant
sequelae
Volkmann’s contracture
Weak dorsiflexors
Claw toes
Sensory loss
Chronic pain
Amputation
LATE SEQUELE
98. TIME LAPSE BETWEEN INJURY & INTERVENTION –
FASCIOTOMY WITHIN 6HRS : ≈100% FULL RECOVERY
WITHIN 12HRS : 68%
BEYOND 12HRS : 8%
PROGNOSIS
99. Minimize the external application of pressure
Not closing Fascial defects
Minimizing tissue Ischemia
Performing prophylactic fasciotomy protecting soft tissue
Avoiding excessive limb elevation above the level of the heart
PREVENTION
103. VIC is the end result of prolonged ischemia of muscles and nerves in an extremity.
Primary target – Muscle
Secondary target- Nerve
Muscle undergoes necrosis, fibrosis and contracture
Nerve injury causes further muscle dysfunction, sensory deficit or chronic pain.
PATHOGENESIS
104.
105.
106. Elbow flexion
Forearm pronation
Wrist flexion
MCPJ extension
IPJ flexion
Thumb flexion & adduction
Median & ulnar nerve neuropathy
DEFORMITY IN UPPER EXTREMITY
107. INTRINSIC MUSCLE CONTRACTURES
Intrinsic plus deformity
Flexion (MCPJ) + Extension (PIPJ)
VOLKMANN'S CONTRACTURE
Intrinsic minus deformity
Hyperextension (MCPJ) + Flexion (PIPJ)
◼ Although the two entities resultant clawmay occur simultaneously, the hand
deformity is determined by the more powerful extrinsic finger contracture flexors
108. 1. SEDDONS CLASSIFICATION
Grade I: Ischaemia
Grade II: Ischaemic contracture
Grade III: Ischaemic contracture with nerve involvement
2. ZANCOLLI ( upon the structures involved) :
Type I: Contracture involving forearm muscles with normal intrinsic muscles
Type II: Contracture involving forearm muscles with paralysis of intrinsic muscles
Type III: Contracture involving forearm muscles with contracture of the intrinsic
muscles
Type IV: Combined type
CLASSIFICATION
109. 3. HOLDENS CLASSIFICATION ( Based on etiology) ;
Type 1- proximal arterial injury as in supracondylar fracture more extensive
Ischemia
Type 2 - Direct injury as in crush injury of the forearm
4. TSUGES (presentation );
mild( involving FDP)
moderate( FDP, FDS, FPL,FACT,FCU)
severe ( both flexors and extensors)
110. 1. MILD (LOCALIZED)
Limited to extrinsic finger flexors
Usually 2 or 3 fingers
Hand sensibility & strength are normal
Intrinsic muscles not involved
Fixed joint contracture not present
Usually occur in young adults
Most are caused by fractures or crush injury
No paralysis of the extrinsic or intrinsic muscles and no fixed joint contractures.
111. MODERATE
Classic type
Primarily affects FDP & FPL
Occasionally FDS, FCR & FCU
Wrist & thumb are flexed
Wrist is held in a flexed position and the fingers show an intrinsic minus deformity
Claw hand deformity
Secondary nerve compression
median > ulnar nerve
The muscle degeneration is moderate , leaving enough intact contractile elements for active
flexion even in the deep flexer compartment , a muscle slide technique is performed with release
112. SEVERE
Affect forearm extensors & flexors
Commonly due to brachial artery damage
Median nerve is always involved with the ulnar nerve also severely involved
Forearm muscle mass has a firm"Woody consistency"
Often encountered:
Loss of nerve function
Malunion or nonunion
Cutaneous scarring
Contractures
114. ROBERT JONES METHOD :
Wooden tongue depressors were
used to correct established
deformities gradually from distal to
proximal
BANJO SPLINT:
Permits the fingers to be exercised
at all times and is most efficient
CONSERVATIVE MANAGEMENT
115. MILD (EARLY)
Normal hand sensibility & strength: conservative
Dynamic splintage
At night - extension splints
Satisfactory outcome with early treatment
MILD (LATE)
Excision of infarcted muscle
Lengthening the tendon
Principles of management
116. MODERATE
Max pages muscle sliding operation : This consists of releasing the common
flexor origin from the medial epiconyle and passively stretching the fingers . This
slides the origin of the muscle down and releases the contractures
Other muscle sliding operation –
1. Inglis and Cooper
2. Williams and haddad
Neurolysis : It consists of freeing the peripheral nerves from the surrounding
fibrous tissue
Tendon transfers
117. RELEASE OF SECONDARY NERVE COMPRESSION
Signs of gradual recovery: 12month period
MEDIAN NERVE CAN BE CONSTRICTED IN
Lacertus fibrosus
2 heads of Pronator teres
Proximal arch of FDS
Carpal tunnel
118. ULNAR NERVE COMPRESSION
Incidence much lower
Btw ulnar & humeral heads of FCU
RADIAL NERVE COMPRESSION
Rarely involved
Under tendinous origin of supinator
(arcade of Frohse)
119. Treatment of Contractures be performed at the time of, or subsequent to, nerve
decompression
1. INFARCT EXCISION
6 months of splinting before surgery (Seddon)
Resection of all muscles reduced to solid scar
Postop immobilization (supination & extension)
2. FLEXOR TENDON LENGTHENING OR EXCISION
Z lengthening of FDP, FDS, FPL, PT ( Goldner)
Disadvantage: weakness
120. 3) TENDON TRANSFERS
Usually delayed till after nerve recovery
After maximal contracture correction
A. PHALEN & MILLER (1947)
Digital flexion & thumb opposition
ECRL → FDP, ECU → thumb opposition, EPB → ECUs
121. SEVERE TYPE
•Excision of the scar
•Proximal or distal row carpectomy
•Arthrodesis of the wrist in functional position
•Amputation for very severe cases of VIC with gangrene
122. • COMPARTMENT SYNDROME HAS DISASTROUS CONSEQUENCES IF PERMITTED TO
RUN ITS COURSE.
• TRUE ORTHOPEDIC EMERGENCY
• Early FASCIOTOMY has better outcome
• Reliable, safe, and effective
• The only treatment for compartment syndrome, when performed in time
SUMMARY
123. Cambells orthopedics
Rockwood and Green's Fractures in Adults
Compartment syndrome by Jorma Styf
Wheeless textbook of orthopedics
McRaes orthopedics and trauma
Fasciotomy in the treatment of the acute compartment syndrome. J Bone Joint Surg
Am. 1976 Jan;58(1):112-5
REFERENCES
124. 1. Compartment pressure and it's relevance in the management of Compartment syndrome (MAY
'07)
2. Describe the anatomy of Compartments of the leg. Describe the methods of measuring the
Compartment pressure .Add a note on treatment of compartment syndrome (NOV '12)
3. Describe the anatomy of compartments of the leg .How will you diagnose and manage a case of
compartment syndrome of the leg (MAY '09)
4. Compartment syndrome (NOV '12) , (APRIL' 08)
5. Discuss the management of a patient with communited fracture of tibia plateau with
Compartment syndrome (MAY ' 14)
6. Discuss the pathophysiology of volkmans ischemic contracture. Discuss the clinical features and
principles of management of impending volkmans ischemia involving forearm ( SEP '07)
7. Volkamns ischemic contracture (MAY '07)
QUESTIONS ASKED
