Intracranial Procedures Notes PDF Fall 2022

Summary

These notes cover intracranial procedures, including anatomy & physiology review, and cerebrospinal fluid (CSF). The document details the blood brain barrier, cerebral blood flow, and key determinants of cerebral blood flow.

Full Transcript

NA 741 Principles of Anesthesia II Fall 2022

Intracranial Procedures
Anatomy & Physiology Review

CNS Cells
Cerebrospinal Fluid
Cushions brain, provides buoyancy, & provides ideal conditions for neurologic
function
Locations
o Ventricles (L/R lateral, 3rd, 4th)
o Around brain
o Subarachnoid space in the brain and spinal cord
Production
o Choroid plexi in ventricles @ 20 mL/hr
o Volume ~ 150 mL at any given time
o ICP = 5 – 15 mmHg
Reabsorption
o Arachnoid villi at superior sagittal sinus into venous circulation via
pressure gradient

CSF Plasma

Osmolarity
295 295
(mOsm/L)

Na+ (mEq/L) 138 138

K+ (mEq/L) 2.8 4.5

Cl- (mEq/L) 119 102

HCO3- (mEq/L) 22 24

PaCO2 (mmHg) 47 40

pH 7.33 7.40

Glucose (mg/dL) 60 90

Protein (mg/dL) 35 7000

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Blood Brain Barrier
Areas of the brain that are NOT
Separates CSF from plasma
inside the BBB:
Endothelial cell tight junctions restrict passage of large molecules & ions
1. CRTZ
o Substances with molecular weight > 500 daltons
2. Area Postrema
o Polar molecules (amino acids, glucose, mannitol)
3. Posterior pituitary
o Water soluble drugs
4. Pineal gland
o Proteins
5. Choroid plexus
Permeable to lipid-soluble molecules
6. Hypothalamus
o Anesthetics, CO2, ETOH, O2, nicotine
Cerebral Blood Flow
Arterial Venous
o Anterior o Cortex/cerebellum
§ Internal carotid arteries à Circle of § Superior sagittal sinus
Willis à hemispheres § Dural sinus
§ 80% of CBF o Basal brain
o Posterior § Inferior sagittal sinus
§ Vertebral arteries (via subclavian) à § Vein of Galen
Basilar artery à Posterior brain and § Straight sinuses
cervical spinal cord o All blood exits brain into jugular veins
§ 20% of CBF

Cerebral blood flow is regulated by “flow-metabolism coupling”
Normal CBF is 50 mL/100g tissue/min (15% CO)
o 750 mL/min (15% of CO)
Ischemia occurs at 20 mL/100g tissue/min
Cell death occurs at 10 mL/100g tissue/min
Five Key Determinants of Cerebral Blood Flow
1. Cerebral Metabolic Rate (CMRO2)
2. Cerebral Perfusion Pressure (CPP)
3. PaCO2
4. PaO2
5. Venous Pressure
CMRO2
CBF has direct correlation with CMRO2 (↑ demand = ↑ supply)
o ↑ CMRO2 = ↑ CBF
o ↓CMRO2 = ↓ CBF
Oxygen consumption
o 20% of total body oxygen consumption
o 60% for electrical activity
o 40% for cellular integrity
o Takeaway: can only ↓ CMRO2 up to 60%
Increase CMRO2:
o Seizures
o Ketamine
o N2O
o Hyperthermia
Decrease CMRO2:
o Halogenated anesthetics
o IV anesthetics (Propofol, Etomidate, Barbiturates)
o Hypothermia: ↓ 7% per 1o C body temperature (suppression @ 18-20o C)

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NA 741 Principles of Anesthesia II Fall 2022
Cerebral Perfusion Pressure (CPP)
CPP = MAP – ICP (or CVP); whichever is higher
CBF autoregulation is maintained when CPP is between 50-150 mmHg
CPP effect on CBF CPP = MAP – ICP (or CVP)
< 50 mmHg cerebral vessels are maximally vasodilated in effort to ↑ CBF
50 - 250 mmHg constant and consistent CBF CBF = CPP/CVR
cerebral vessels are maximally vasoconstricted in effort to ↓
> 150 mmHg
CBF
o Note: do NOT confuse CPP with MAP
When is autoregulation impaired?
o Intracranial Tumor o Volatile anesthetics
o Head Trauma o Chronic HTN (right shift in CPP curve)
PaCO2
PaCO2 has a direct correlation with CBF: ↑ PaCO2 = ↑ CBF
o CSF pH alters cerebral arteriolar diameter
PaCO2 effect on CBF
80 – 100 mmHg cerebral vessels are maximally vasodilated in effort to ↑ CBF
for each 1 mmHg change in PaCO2, there is a 1-2 mL/100g/min
26 – 80 mmHg
change in CBF
cerebral vessels are maximally vasoconstricted in effort to ↓
< 25 mmHg
CBF
Think about how respiratory acidosis/alkalosis affect CBF
Metabolic acidosis does NOT affect CBF à H+ can’t cross BBB
PaO2 & Venous Pressure
PaO2
PaO2 effect on CBF
< 50 – 60 mmHg cerebral vessels are vasodilated in effort to ↑ CBF
> 60 mmHg NO EFFECT on CBF
Venous Pressure
o ↑ CVP = ↓ cerebral drainage = ↑ cerebral volume
o Impairing venous drainage
§ Jugular compression (positioning: tucking the chin can impair venous drainage)
§ ↑ intrathoracic pressure (cough, PEEP)
§ Thrombosis
§ Vena cava syndrome
Intracranial Pressure (ICP)
Cushing’s Triad
Normal ICP: 5 – 15 mmHg
1. HTN (body’s attempt to maintain
Intracranial HTN: ICP > 20 mmHg
perfusion)
o S/S: HA, N/V, papilledema, ↓LOC, seizure, coma
2. Bradycardia (baroreceptor reflex)
Initial rise in volume is compensated by shunting CSF into spinal cord, once
3. Irregular respirations (medullary
exhausted then CPP (and therefore CBF) begins to suffer
compression)
Monro-Kellie Hypothesis
o Cranium = rigid box with 3 volumes:
1. Brain = 80%
2. Blood = 12%
3. CSF = 8%
o ↑ in one requires a ↓ in others to maintain the same pressure
o Causes of increased volume for each component
§ Brain à swelling, tumor, etc.
§ Blood à increased CBF (volatile anesthetics, vasodilators, etc) and bleeding
§ CSF à increased CSF production, decreased CSF reabsorption, impaired BBB, CSF flow obstruction

o Points 1 – 2 are compensated
o Points 2 – 3 is where compensation begins to fail and you start
having s/s of intracranial HTN and focal ischemia
o Points 3-4 is where you start having risk of global ischemia &
intracranial herniation

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Ways to Lower ICP
o Hyperventilate (effect lasts 4-6 hours)
o Mannitol 0.25-1 g/kg
o Furosemide 0.5-1 mg/kg
o Corticosteroids
o Restrict Fluids
o Elevate HOB
o Hypothermia (not recommended for CHI)
o Normotensive to slightly hypertensive
Cerebral Blood Flow Summary Graph
o Below autoregulation limit à vessels are
maximally dilated à pressure dependent
o Above autoregulation limit à vessels are
maximally constricted à pressure
dependent
o The vessel diameter is only blue because
the graph had MAP as blue.
Cerebral Protection
Ischemic & Reperfusion
Brain is susceptible to rapid ischemic injury
o High rate of oxygen & glucose consumption
o Unable to store oxygen and glucose à very dependent on adequate blood flow
o Unable to dispose of toxic metabolites quickly
Global ischemia 2/2 severe hypotension or anemia
o Treated with interventions aimed to restore total cerebral perfusion
Focal ischemia is a regional insult
o Treatment focused on the region in question
o A “penumbra” of salvageable tissue usually surrounds the necrotic core
o Augment CPP while decreasing reperfusion injury
§ Restoration of flow = ↑ free radicals & inflammatory mediators = exacerbation of injury
Ventilation Management
Vt 6-8 mL/kg
Peak pressure < 40 cmH2O
No PEEP unless needed for oxygen requirement
o PEEP ↓ cerebral venous drainage & ↓ CO
PPV to control ventilation & PaCO2
o Also ↓ risk for VAE when in sitting position
Fluids & Electrolytes
Euvolemia with isotonic or slightly hypertonic solutions
Avoid glucose containing solutions
o Glucose is quickly metabolized and is not osmotically active à cerebral edema
o Ideal BG: 90-280 mg/dL
§ Hypoglycemia: no glucose for ATP
§ Hyperglycemia: more glucose is converted to lactic acid if ischemia is present
Diabetes Insipidus is a loss of intravascular water à hypotonic solutions acceptable
Excessive NaCL: hyperchloremic metabolic acidosis
Tumor Resections
Preoperative Evaluation
Identify problems to plan appropriately
o Intracranial mass lesion & ↑ ICP
§ Most important information is presence/extent of intracranial hypertension (H&P, MRI, CT, etc.)
§ HA, dizziness, visual/gait disturbances, N/V, seizures, altered LOC, confusion, papilledema, loss of
strength/sensation, cranial nerve dysfunction, etc.
Premedication limited or avoided completely
o Be extremely careful with drugs that depress respiration (↑PaCO2)
Continue steroids & anticonvulsant therapy
Induction & Airway Management
Goal is limit changes in ICP & CPP
Consider preinduction A-line, osmotic diuresis, or CSF drainage
Hypotension & hypoventilation must be avoided
Strict BP control during intubation (↑ r/f herniation)
Propofol as induction agent

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Blunt SNS from laryngoscopy: Fentanyl (1-2 μg/kg), Lidocaine (1-1.5 mg/kg), or esmolol 10-20 mg
Adequate vascular access is mandatory
o 2 large bore IVs + arterial line (possible CVL)
Mayfield pins after induction & vascular access
o Adm propofol, opioids, or esmolol to blunt
Excessive neck flexion/extension/rotation can compress IJ and impair cerebral venous drainage
ICP control is paramount until dura is opened
HD instability must be minimized d/t impaired autoregulation
o Hypotension = ischemia
o Hypertension = ↑ r/f bleeding and edema
Decreasing ICP & Increasing Exposure: manipulating the variables of the Monro-Kellie hypothesis
Vascular Compartment CSF Compartment Cellular Compartment
(reducing cerebral blood volume) (reducing CSF volume) (reducing cellular edema)
o No PEEP o Ventriculostomy o Mannitol (0.25-1 g/kg) or
o Hyperventilation Lasix (0.5-1 mg/kg)
o Limit Volatile Anesthetic o Hypertonic saline (3% @ 50-
o HOB elevated 100 mL/hr)
o Limit IVF to euvolemia o Steroids
Maintenance of Anesthesia
Avoid increases in ICP (at least until dura is opened)
Maintaining CPP
Neuromonitoring requirements
Fluid maintenance with dextrose-free-iso-osmolar crystalloid or colloids to achieve euvolemia
Rapid Emergence is the goal (Short-acting, easily titratable drugs)
o Propofol, remifentanil, sevoflurane, desflurane, possibly N2O
Maintenance of Anesthesia: Drugs
Volatile Gas < 0.5 MAC (cerebral vasodilation)
Propofol gtt 50-300 μg/kg/min (depends on VA use)
Remifentanil 0.05-2 μg/kg/min (IBW)
o Beware of opioid-induced hyperalgesia
o Low-dose ketamine or magnesium sulfate can help attenuate this
Emergence from Anesthesia
Patients with normal GCS (13-15) are usually extubated
HD control is paramount (HTN can lead to worsening cerebral edema)
o Labetalol, esmolol, nicardipine, etc. on hand
o Coughing or vomiting can be deleterious
§ Careful titration of opioids and antiemetics
o Control pain without obtunding patient
§ Short-acting opioids, IV acetaminophen, LA infiltration by surgeon, dexmedetomidine, etc.
Types of Tumors
Intracranial Tumors
In adults, supratentorial lesions are more common from CNS support cells (gliomas, astrocytomas, oligodendrogliomas, etc.)
Most common metastatic tumor to the brain includes melanoma or those that originate in the lung, breast, or kidney
Primary concern is usually elevated ICP
Infratentorial & Posterior Fossa Tumors
Close proximity to brainstem
o More HD distress, changes in respiratory control, and arousal changes
o Altered respiratory patterns, cardiac dysrhythmias, or CN dysfunction
More frequently require postoperative intubation and mechanical ventilation
Positioning can be prone, lateral, or sitting
o Particular risk for VAE: especially if patient is spontaneously ventilating
Cerebral Aneurysms
Saccular aneurysm: most common cause of subarachnoid bleeding
o Arterial bleeding à subarachnoid space
o Venous bleeding à subdural space
Essential causes of rupture = ↑ aneurysmal distention pressure
o ↑ MAP = ↑ distention = ↑ aneurysm radius = ↑ wall tension
o ↓ ICP = ↓ distention = ↓ aneurysm radius = ↓ wall tension
Most common sign of SAH is “worst headache of my life”
o Syncope, N/V, photophobia, fever, obstructive hydrocephalus, etc.
Aneurysm and Transmural Pressure
o MAP = pressure pushing outwards (making rupture more likely)

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o ICP = pressure pushing inwards (making rupture less likely; like a tamponade effect)
Rupture more likely with: HTN, drop in ICP
Most common aneurysm locations in Circle of Willis
o ACA = 40%
o MCA = 25%
o PCA = 25%
o BA = 10%
Rupture Risk
o ↑ transmural pressure (TMP = MAP – ICP)
o Diameter > 2.5 cm (Laplace)
o Smoking
o Excessive EtOH
o Recreational drugs
o Age > 40
o Female
o Systemic HTN
Surgical options: aneurysm clipping or endovascular coiling
o Intervention should take place within 48 hours of initial bleeding
Induction of Anesthesia
Limit preoperative sedation to avoid hypercapnia
A-line for induction
2 large bore IV’s
Type and Cross 2-4 units PRBCs; have them in the room
Smooth induction with tight BP control
o Propofol, Lidocaine
o Fentanyl, Esmolol
Maintenance of Anesthesia
TIVA vs. Volatiles
BP 15-20% below baseline
o Prevent vasospasm
o ↓ EBL
Limit excess crystalloids
Clipping: may ↑ MAP
Clamping: when the parent vessel is clamped, increase MAP ~ 80-100 mmHg to ensure adequate collateral blood flow

Emergence from Anesthesia
Need rapid wake up for neuro assessment
Similar considerations as intracranial mass
Keep BP within 20% of baseline
Cerebral Aneurysm: Intraoperative Rupture
Most likely during:
o Dural Incision (↓ ICP)
o Excessive brain retraction
o Aneurysm dissection
o Clipping or clip release
Treatment
o Volume: Immediate, aggressive volume replacement (PRBC)
o Pressure: ↓ MAP to 40-50 mmHg
o Visualization: Surgeon will attempt to clip feeder vessel à may need adenosine 0.3-0.4 mg/kg à transient cardiac arrest to
halt blood flow and improve visualization
Cerebral Aneurysm Clipping and Endovascular Coil
Clipping Endovascular Coil
Involves placing a clip at the base of aneurysm involves transarterial catheterization to thread coil into
Removes aneurysm from MAP so it can’t rupture aneurysm sac.
anymore A neuro-interventional radiology procedure
Treated the same as an open craniotomy aneurysm clip with the
addition of heparin (necessary when a foreign metal material is
being implanted into the body)
o Heparin 70 units/kg bolus
o Protamine at end of case: 1mg for every 100 units of
heparin

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Cerebral Vasospasm
Linked to morbidity/mortality after SAH (1:4 patients w/I 4-9 days)
Free Hgb irritate vasculature à hyperactive vasculature à cerebral vasoconstriction à cerebral infarction
Most common presentation: new neurologic deficit or altered LOC
Gold standard for diagnosis: cerebral angiography
Prevention/detection: frequent neuro checks and/or daily transcranial doppler exam
Cerebral Vasospasm: Treatment
Maintain CPP (MAP-ICP or CVP)
Perfusion to ischemic areas is pressure dependent because the blood vessels supplying ischemic areas are already maximally
vasodilated; therefore, MAP will need to be increased 20 – 30 mmHg above baseline to maintain CPP
Triple H Therapy = Hypervolemia + Hemodilution + Hypertension
o Liberal hydration (↓ viscosity) + ↑ BP = ↑ CBF
o Goal Hct = 27-32%
Nimodipine is the only CCB associated with ↓ morbidity/mortality
o Does NOT relieve vasospasm, but instead it increases collateral flow
Traumatic Brain Injury
15-20% of mortality in ages 5-35
50% of all deaths related to trauma
o Hypotension, hypoxemia, intracranial HTN, hematoma, etc.
Ensure stable C-spine, protected airway, HD stability, & cerebral protection
Stat non-contrast head CT to assess for bleeding
Key considerations
o Unstable C-spine
o Bloody airway or skull-base fracture
o Full stomach
o Intracranial HTN
Blood thinners?
o Warfarin reversal with FFP, recombinant factor 7a, or vitamin K
o Clopidogrel or aspirin reversed with plt transfusion (possibly recombinant VII)
Skull Base Fracture
o Raccoon Eyes: Periorbital ecchymosis
o Battle’s sign: bruise behind one or both ears
Traumatic Brain Injury Anesthetic Implications
Maintain CPP while decreasing ICP
o Too much hyperventilation can ↑ ischemia
o Use methods to ↓ ICP previous discussed, EXCEPT:
DO NOT GIVE…. STEROIDS or possibly mannitol
o Hypertonic saline ideal
o Avoid N2O because you don’t know what other injuries are present
o Avoid colloids and hypotonic solutions
Ventriculoperitoneal Shunt
VP shunt allows excess CSF to drain into peritoneal cavity
3 key parts
o Burr hole access through dura
o Abdominal incision
o Subcutaneous tunneling from head to abd (connect the sites)
o Catheter passed through
Most stimulating portion is usually tunneling

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