Surgery for Head Injury
51
Surgical Management of Traumatic Brain Injury Dhaval Shukla Department of Neurosurgery NIMHANS
-
Upload
dhaval-shukla -
Category
Health & Medicine
-
view
319 -
download
0
description
Surgery for Head Injury Traumatic Intracranial Hematoma Traumatic Brain Injury
Transcript of Surgery for Head Injury
Surgical Management of Traumatic Brain Injury
Dhaval ShuklaDepartment of Neurosurgery
NIMHANS
Intracranial Hematomas (ICH)
• ICH is the commonest cause of secondary deterioration after TBI
• ICH constitutes >70% of the causes of death in patients who ‘talk and die’
Intracranial Hematomas (ICH)
• Though technically simple emergency surgery may be among the most frustrating procedures performed by neurosurgeons– Complications: heavy bleeding and brain swelling – Operations frequently occur at night– Less experienced surgeons are delegated to do
surgeries– Decisions regarding removal of contusions may be
difficult
Pathoanatomical Classification
Imaging Parameters
(A/2) - B
Volume Basal Cisterns
Midline Shift
Preoperative surgical checklist
1. Blood to laboratory for:(A) cross matching (2 units of whole blood)(B) coagulation studies
(I) PT(Ii) APTT(Iii) Platelet count
(C) blood gas analysis(D) routine full blood count and electrolytes
Preoperative surgical checklist
2. X-rays of chest and cervical spine3. Consent4. Foley catheter5. Two large bore peripheral i.v. lines6. Arterial catheter7. Protection of both eyes8. Adequately secured endotracheal tube
Properative Medications
• Antibiotics• Mannitol• Anticonvulsants– ICH, Depressed fractures
– Phosphenytoin: Loading 18 mg/ kg iv in 100 ml NS
over 30 min
• No steroids
Extradural Hematoma (EDH)
• Contact injuries resulting from blunt trauma to
the skull and meninges
• 1-2% of all head injuries
• Fractures: 30 to 91 %
EDH - Clinical
• Lower incidence in elderly and young infants
• Unconsciousness– 30 to 60 % mild or no loss of consciousness
– 20 % unconscious from the time of injury
– Lucid interval in only 20 to 50 %
EDH - Clinical
• Rapidly symptomatic– 1/4th enlarge
– Mean time to enlargement • 8 h after injury
– No enlargement later than • 36 h from injury
EDH – Imaging
• Associated intracranial injuries in 24 to 75 %
NIMHANS
EDH - Surgery
Craniotomy with hitch stitchesNIMHANS
EDH - Outcome
• Mortality: 0 to 12 %• Favorable outcome 55 to 89 %• Level of consciousness – Conscious: Favorable outcome in 90 to 100 % Mortality 0 to 5 %– Coma: Favorable outcome in 38 to 73 % Mortality 11 to 41 %
EDH - Outcome
• Pupillary status– Normal reactivity: Favorable outcome in 84 to 100%– Abnormal pupil unilateral: Favorable outcome in 55
to 100 %– Abnormal pupil bilateral: Unfavorable outcome and
mortality
• Presence of associated intracranial injuries– Mortality: Three times
Subdural Hematoma (SDH)
• Incidence: 12 to 29 % of severe TBI• Most lesions over cerebral convexities in the
frontal and temporal regions • Extent of secondary brain injury may be more
important than the subdural clot itself• SDH more likely to develop complications of
cerebral ischemia, cerebral edema, and increased intracranial pressure
SDH - Clinical
• Mean age: 31 to 47 years• Coma (GCS < 8): 37 to 80 %• Lucid interval: 12 to 38 %• Pupillary abnormalities: 30 to 50 %• Unconsciousness out of proportion to external
injury and size of blood clot• Acute SDH can enlarge but also ‘disappear’
SDH - Imaging
NIMHANS
Surgery for acute SDH
Craniotomy with or without bone flap replacement and duraplasty
In comatose patients with small SDH an ICP monitoring can guide a careful conservative management
SDH - Outcome
• Most lethal of all head injuries• Mortality: 30 to 90 %• Favorable outcome: 19 to 30 %• Timing of surgery?• Strongest determinant of outcome: sustained
intracranial pressure • None of the patients above 60 years of age
have good recovery
Chronic SDH (CSDH)
• Acute: < 3 days
• Subacute: 4 -20 days
• Chronic: > 21 days
• CSDH may completely organize and resolve or
calcify
CSDH - Clinical
• Incidence: 7.35 per 100,000 per year seen in the age group 70 to 79 years
• Rare in age < 40• History of head injury: 50 to75 %• Risk factors: Chronic alcoholism, brain atrophy,
CSF shunts, seizure disorders, and impaired coagulation
• Dementia, stroke, transient ischemic attacks, other mass lesions
CSDH - Clinical
• Headache: 80 %• Altered sensorium: 28 to 100 %• Motor deficits: 24 to 62 %• Gait abnormality: 40 %• Memory loss or confusion: 33 %• Papilledema: 25 %
An erroneous admission diagnosis up to 40 %
CSDH - Imaging
• Bilateral: 15 to 20 %• Intravenous administration of contrast to look
for enhancement of the inner membrane particularly for isodense CSDH
CSDH - Treatment
• Twist drill craniostomy– Failure: 5 to 24 %
• Burr holes – Success: 86 to 95 %
• Craniotomy• Subdural shunt• Outcome– All deaths occur in patients in poor clinical grade or
secondary to medical conditions
Cerebral Contusions
• Contusion: Perivascular hemorrhage about small blood vessels and necrotic brain
• Hematoma: Contusions with blood content of at least 2/3rd of the volume of the lesion and appearing more homogeneous
• Cerebral laceration: Pia-arachnoid is torn• Burst lobe: cerebral contusion and hematoma,
with concomitant acute SDH
Delayed Traumatic Intracerebral Hematomas (DTICH)
• 6 hours to 30 days• 0.6 to 7.4 %• Pathogenesis:– Increased vessel fragility– Increased intramural pressure– Increased capillary wall permeability– Fibrinolysis– Rupture of a post-traumatic aneurysm
Contusion – Clinical Features
• 8.2 % of all injuries• 13 – 35 % of severe TBI• Neurological deficits• Restlessness• Seizures• Progressive neurological deterioration– 33 %– 24 to 72 hours (up to 7 to 10 days)
Contusion - Imaging
• Salt and pepper: • Coup and contre coup (remote): Frontal/
Temporal• Multiple
NIMHANS
Surgery for cerebral contusions
Craniotomy with evacuation of lesionDecompressive craniectomy and
bone flap placement in abdominal wall
Contusion - Outcome
• Presence of traumatic subarachnoid hemorrhage on an admission is powerful predictor outcome
• Older age, alcoholism, and coagulation disorders• Posttraumatic epilepsy• Psychiatric disorders• Mortality– Coup: 16.4 %– Contrecoup:44.1%– DTICH: 35 to 40 %
Depressed Fracture
• Incidence: 6 % • Significantly depressed if the outer table of
one or more of the fractured segments lies below the inner table of the surrounding skull
• Compound depressed fracture: 75 to 91 %• Dural tear: 51 to 60 %• Associated parenchymal injuries: 50 – 71%
Depressed Fracture - Clinical
• Focal neurological deficits
• No LOC: 25 %
• Post-traumatic amnesia <1 hour: 25 %
• Seizures
• CSF leak and meningitis
Depressed Fracture - Imaging
• Always assess for fractures on bone windows
NIMHANS
Surgery for depressed fracture
Elevation with debridementDuraplasty Antibiotics
NIMHANS
Surgery for depressed fracture involving venous sinus
• Observation alone
• Debridement and closure of an overlying scalp
laceration without fracture elevation
• Fracture elevation and exposure of the
damaged sinus, followed by sinus repair or by
sinus ligation in presence of hematoma
Depressed Fracture - Outcome
• Infection: 1.9 – 10.6%
• Morbidity: 11 %
• Late epilepsy: 15 %
• Mortality: 1.4 – 19 % (depending on
associated lesions)
Posterior Fossa Lesions
• < 3 % of injuries
• 1.2 – 12.9 % of all EDH
• 0.5 – 2.5 % of all SDH
• 1.7% of all contusions
• Posterior fossa ICH almost always occur in older
children and young adults
Posterior Fossa Lesions - Clinical
• Rapid and life threatening neurological
deterioration
• Patients can have respiratory and cardiac
arrest without clinical signs of progressive
neurological deterioration
• Headache, neck pain, and vomiting
Posterior Fossa Lesions - Imaging
• Fourth ventricular compression• Hydrocephalus• Supratentorial extension of EDH• Associated supratentorial lesion• Cervical spine injuries
NIMHANS
Surgery for posterior fossa lesions
• Neurological dysfunction or deterioration
• Distortion or obliteration of IV ventricle
• Cisternal compression
• Hydrocephalus
Suboccipital craniectomy and evacuation with or without EVD
NIMHANS
Posterior Fossa Lesions - Outcome
• GCS• Associated supratentorial lesions• Location– Parenchymal vs extraparenchymal– Midline vs lateral
• Hydrocephalus• Acuity of presentation
Decompressive Craniectomy
Decompressive craniectomy (DECRA)
DECRA significantly decreases ICP but associated with more unfavorable outcomes
Cooper DJ, et al. NEJM, 2011.
Lobectomy for Brain Swelling
• Swollen and contused temporal pole may cause tentorial herniation and brain-stem compression
• More controversial• > 80 % still have raised ICP postoperatively• Patients under 40 years with higher initial GCS
benefit more
Complications
Diffuse intraoperative bleeding
Diffuse brain swelling
Diffuse Intraoperative Bleeding
1. Check the coagulation studies.2. Transfuse blood and fresh frozen plasma as
appropriate, usually 6–10 units.3. Consider development of an ICH, either on
the same or opposite side4. Optimize cerebral perfusion pressure
Use vasopressor agents if necessary
Diffuse Intraoperative Bleeding
5. Thiopental 250mg–1 g in incremental doses6. More mannitol and lower PaCO2 to ~ 28 mmHg
by increasing ventilation7. Rule out intraoperative pneumothorax
Management• Factor VII and Tranexamic acid do not help
significantly• Complete normalization of the hematological
parameters by replacing the appropriate factors
Diffuse Brain Swelling
• Most commonly seen with acute SDH
• Anticipated when preoperative CT scan shows
brain swelling (midline shift out of proportion
to thickness of SDH)
• Anesthesia causes
– Impaired ventilation
Diffuse Brain Swelling
• Surgical causes:
– Ipsilateral ICH beyond the craniotomy margin
– Contralateral fracture or small hematoma on the
preoperative CT
• Management
– Decompressive craniectomy
– Mortality 50 %
Postoperative Management
