cerebrospinal fluid and intracranial pressure

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CEREBROSPINAL FLUID AND INTRACRANIAL PRESSURE

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Page 1: Cerebrospinal fluid and intracranial pressure

CEREBROSPINAL FLUID AND INTRACRANIAL

PRESSURE

Page 2: Cerebrospinal fluid and intracranial pressure

CEREBROSPINAL FLUIDThe cerebrospinal Fluid [CSF] is a

clear, colorless transparent, tissue

fluid present in the cerebral

ventricles, spinal canal, and

subarachnoid spaces.

Page 3: Cerebrospinal fluid and intracranial pressure
Page 4: Cerebrospinal fluid and intracranial pressure

FORMATION CSF is largely formed by the choroid

plexus of the lateral ventricle and remainder in the third and fourth

ventricles.

About 30% of the CSF is also formed from the ependymal cells lining the

ventricles and other brain capillaries (perivascular space).

Page 5: Cerebrospinal fluid and intracranial pressure

MECHANISM OF FORMATION OF CSF

CSF is formed primarily by secretion (active transportation) and also by

filtration from the net works of capillaries and ependymal cells in the

ventricles called choroid plexus.

Page 6: Cerebrospinal fluid and intracranial pressure

The resulting characteristics of the CSF are:

Osmotic pressure approximately equal to that of plasma

sodium ion concentration Approximately equal to that of plasma

chloride ion About 15 per cent greater than in plasma

potassium ion approximately 40 per cent less

glucose 30 percent less

Page 7: Cerebrospinal fluid and intracranial pressure

Rate of formation:

About 20-25 ml/hour

550 ml/day in adults. Turns over 3.7 times a day

Total quantity: 150 ml:

30-40 ml within the ventricles

About 110-120 ml in the subarachnoid space [of which 75-80 ml in spinal part and 25-30 ml in the

cranial part].

Page 8: Cerebrospinal fluid and intracranial pressure

The brain tissue is separated from the plasma by three main interfaces

(a) blood–brain barrier (BBB),

(b) blood–cerebral spinal fluid barrier (BCSFB)

(c) arachnoid cells underlying the dura mater.

Page 9: Cerebrospinal fluid and intracranial pressure
Page 10: Cerebrospinal fluid and intracranial pressure

WHAT IS THE BLOOD BRAIN BARRIER

Structural and functional barrier which impedes and regulates the influx of most compounds from blood to brain

Formed by • endothelial cells (BMEC) of capillary• Basement membrane• Foot process of astrocytes

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WHAT IS BLOOD CSF BARRIER

Lumen of blood capillaries separated by ventricle

Endothelial cell of capillaries Basement membrane Choroid epithelial cell with tight

junction

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Page 13: Cerebrospinal fluid and intracranial pressure

REGIONS OF BRAIN NOT ENCLOSED BY BBB

• Circumventricular organs –area postrema, –median eminence, –neurohypophysis, –pineal gland, –subfornical organ and – lamina terminalis

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ABSORPTION OF CSF THROUGH ARACHNOID VILLI

The arachnoidal villi are fingerlike inward projections of the arachnoidal membrane

through the walls into venous sinuses.

The endothelial cells covering the villi have vesicular passages directly through the bodies

of the cells large enough to allow relatively free flow of (1) cerebrospinal fluid, (2)

dissolved protein molecules, and (3) even particles as large as red and white blood cells

into the venous blood.

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REGULATION OF ABSORPTION

• Absorption of CSF occurs by bulk flow is proportionate to CSF pressure.:

• At pressure of 112 mm (normal average): filtration and absorption are equal.

• Below pressure of 68 mm CSF, absorption stops

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COMPOSITION OF CSFProteins(Less than plasma)=20-40 mg/100 mlGlucose( Less than plasma )=50-65 mg/100 mlCholesterol= 0.2 mg/100 mlNa+(more)= 147 meq/Kg H2OCl+(more) =Ca+(less) = 2.3 meq/kg H2OUrea(less) = 12.0 mg/100 mlCreatinine = 1.5 mg/100 mlLactic acid = 18.0 mg/100 ml

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CHARACTERISTICS OF CSFNature:Colour = Clear, transparent fluidSpecific gravity = 1.004-1.007Reaction = Alkaline and does not coagulateCells = 0-3/ cmmPressure = 60-150 mm of H2O

Page 18: Cerebrospinal fluid and intracranial pressure

CIRCULATION OF CSFLateral ventricle

Foramen of Monro [Interventricular foramen]

Thirdventricle

Subarachnoid space of Brain and Spinal cord

Fourth ventricle:

Cerebral aqueduct

Foramen of megendie and formen of luschka

Page 19: Cerebrospinal fluid and intracranial pressure
Page 20: Cerebrospinal fluid and intracranial pressure

FUNCTIONS OF CSFA shock absorberA mechanical bufferAct as cushion between the brain and craniumAct as a reservoir and regulates the contents of the craniumServes as a medium for nutritional exchange Transport hormones and hormone releasing factors

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Count. Function Remove metabolic wastes from CNS Serves as pathway for pineal secretion

to reach the pituitary gland. it protects against acute changes in

arterial and venous blood pressure; it is involved in intra-cerebral transport,

ex. hypothalamic releasing factors

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HYDROCEPHALLUS:External hydrocephallus: Large amounts of

CSF accumulates when the reabsorptive capacity of arachnoid villi decreases.

Internal hydrocephallus: occurs when foramina of Luschka & Magendie are blocked or obstruction within ventricular system, resulting in distention of the ventricles.

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Hydrocephalouscommunicating hydrocephalous :

fluid flows from the ventricular system into the subarachnoid space.

In communicating type blockage is in the subarchnoid space by blockage of arachnoidal villi themselves .

Non communicating : Fluid cant pass to the subarachnoid space In this type is blockage of the aqueduct of sylvius

. Obstruction of villi blockage ↑ CSF

pressure hydrocephalous may lead to edema .

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Page 25: Cerebrospinal fluid and intracranial pressure

INTRACRANIAL PRESSURE • ICP typically means the supratentorial CSF

pressure measured in the lateral ventricles or over the cerebral cortex.

• Normal ICP value is 10 mm Hg or130 mm of H2O

• Intracranial hypertension is defined as a sustained increase above 37 mm Hg or 300mm of H2O

Page 26: Cerebrospinal fluid and intracranial pressure

MONORO-KELLIE HYPOTESIS

• The pressure-volume relationship between ICP, volume of CSF, blood, and brain tissue, and cerebral perfusion pressure (CPP) is known as the Monro-Kellie doctrine or the Monro-Kellie hypothesis.

• Since the cranium is a rigid structure with a fixed volume, comprising of CSF, brain, and blood. An increase in one of these components must be accompanied by an equivalent reduction in another to avoid a rise in ICP

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• Initially, an increase in volume is met with little or no change in ICP. Ultimately, there is a point where minute increases in volume can result in a dramatic rise in ICP.

• Compensatory mechanisms that prevent the initial rise in ICP include:a) displacement of CSF from the cranial to spinal compartment,

b) decrease in production of CSF c) increase in absorption of CSF d) decrease in total cerebral blood volume

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Clinical signs and symptoms that suggest increased ICP include:

1) Headache2) Nausea/vomiting3) Blurre vision4) Papilledema 5) Somnolence alter level of consciousness6) Pupillary dilatation7) Cushing triad• Bradycardia• Hypertension• Irregular respiration

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CAUSES• mass effect such as brain tumor, infarction with

edema, contusions, subdural or epidural hematoma, or abscesses

• generalized brain swelling can occur in ischemic-anoxia states, acute liver failure, hypertensive encephalopathy, pseudotumor cerebri, . These conditions tend to decrease the cerebral perfusion pressure but with minimal tissue shifts.

• increase in venous pressure can be due to venous sinus thrombosis, heart failure, or obstruction of superior mediastinal or jugular veins.

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• obstruction to CSF flow and/or absorption can occur in hydrocephalus , extensive meningeal disease (e.g., infection, carcinoma, granuloma, or hemorrhage), or obstruction in cerebral convexities and superior sagittal sinus (decreased absorption

• increased CSF production can occur in meningitis, subarachnoid hemorrhage, or choroid plexus tumor.

• Idiopathic or unknown cause (idiopathic intracranial hypertension)

• Cerebral venous sinus thrombosis

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DISRUPT STRUCTURAL INTEGRATIY

LOCAL EDEMA

INCREASED COMPONENT IN CRANIUM

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CHANGE IN VOLUME OF OTHER

BRAIN HAS LIMITED SPACE TO EXPAND

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COMPANSATION WILL OCCURE

DISPLACEMENT INCREASED ABSORPTION

DECREASED CEREBRAL BLOOD VOLUME

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ICP BEGAIN TO RISE

CHANGE IN LEVEL OF CONSCIOUSNESS

REDUCE CEREBRAL FURTHER BLOOD FLOW SWELLING

Page 35: Cerebrospinal fluid and intracranial pressure

ISCHEMIA CUSHING REFLEX VASOMOTOR CENTER INCREASED ARTERIAL PRESSURE TO

COMPANSATE ICF

SYMPATHETIC RESPONSE

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BRADYCARDIA IRREGULAR RESPIRATION HYPERTENSION

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FURTHER SWELLING

AUTOREGULATIO PRODUCTION OF CSF DILATATION OF BV

MAINTAIN CBF

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INEFFECTIVE DECOMPANSATIONAUTOREGULATION

SHIFTING OF BRAIN TISSUE FROM HEIGHER PRESSURE TO LOW PRESSURE

HERNIATION

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ISCHEMIA DISTURBE VITAL CENTER

CESSATION OF CBF COMA

PERMENANT NEUROLOGICAL DEATH