11. Cerebrospinal Fluid, Blood-Brain Barrier and Blood-CSF Barrier

Content:

1. Formation and function of the cerebrospinal fluid
2. Composition of the cerebrospinal fluid
3. Blood-brain barrier and blood-CSF barrier

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Formation and function of the cerebrospinal fluid

Liquor (cerebrospinal fluid – CSF, liquor cerebrospinalis) is a clear, colourless fluid found in CNS either intracerebrally in the ventricular system of the brain (making up 20 % of the total CSF volume) or extracerebrally in the subarachnoid space (the remaining 80 % of the total volume).

The total volume of cerebrospinal fluid is approximately 150 ml and it is produced at a rate of 450 ml per day (thus replacing itself three times a day). Liquor is synthesized through two processes. Secretion (producing around 50 to 70% of the volume) occurs in the cells of the choroid plexus and ventricular ependyma. The rest of the fluid is synthesized by the ultrafiltration of blood plasma through choroidal capillaries.

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Plexus chorioideus

Choroid plexus

CSF circulates from the lateral ventricles through interventricular foramina (foramina of Monro) into the third ventricle. Mesencephalic duct (aqueduct of Sylvius) connects the third and fourth ventricle and the liquor flows further into the subarachnoid space by means of three foramina: single median aperture (foramen of Magendie) and a pair of lateral apertures (foramen of Luschka). Liquor located in the subarachnoid space surrounds the brain and spinal cord. Portion of liquor leaves the fourth ventricle to enter the central canal of the spinal cord.

Likvor-fast

The resorption of liquor takes place in the arachnoid granulations (arachnoid villi, Pacchioni’s granulations). These are the protrusions of the arachnoid through the dura mater, projecting further into the intracranial venous sinuses enabling the flow of liquor back to the blood circulation.

It is important to maintain a continuous equilibrium between the secretion, circulation and resorption of the CSF. In the case of imbalance, the fluid accumulates in the system causing a condition called hydrocephalus. If the CSF accumulates in the ventricular system, the hydrocephalus is termed internal. In the case of its accumulation in the subarachnoid space, we call the hydrocephalus external.

Liquor performs the following functions:

1) Mechanical and supportive

The brain is essentially fully immersed in the cerebrospinal liquid causing a reduction of is real weight (around 1500g) to an equivalent of about 25 g. This mechanism protects the brain against the damage caused by its own weight.

2) Protective

CSF acts as a shock absorber, protects the brain from a sudden pressure or temperature changes and the components of the immune system present in the fluid (leukocytes, immunoglobulins etc.) provide a protection against various pathogens as well.

3) Metabolic

Liquor helps to maintain the correct composition of the environment surrounding nervous tissue cells (homeostasis). It also partially provides the supply of nutrients and disposal of the metabolic waste products and forms a medium through which a diffusion of a various signal molecules (like neurotransmitters) takes place.

It is important to realize that the volume of all tissues and fluids within the skull is limited by the volume of their bone container. Monroe-Kelly’s doctrine says that the intracranial space volume remains constant and its individual components (blood, cerebrospinal fluid and the nervous tissue) exist in a state of volume equilibrium. Any increase in the volume of one of the component (caused for example by an intracranial bleeding, hydrocephalus or tumor growth) is compensated by a reduction in the volume of other components. CSF acts within this system partially as a buffer (though not having a large capacity) – it is the first system to compensate the increase in volume of the other two compartments. Brain circulation can act in a similar way but to a much lesser extent, because a restriction in blood supply increases a risk of a hypoxic damage to the brain tissue.

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Composition of the cerebrospinal fluid

Physiological values

The composition of the cerebrospinal fluid does not qualitatively differ much from the composition of blood plasma, but they differ quantitatively. The suffix -rrhachia refers to the concentration of a particular substance in the cerebrospinal fluid, for example glycorrhachia (the concentration of glucose in CSF) or proteinorrhachia (the concentration of protein in CSF).

The basic test performed to measure the concentrations of components of the CSF is its puncture. It is usually performed in the lumbar region (between L4 and L5) or, in rare instances through suboccipital puncture. Four samples (each of approximately 2 ml) are collected:

1) Biochemistry: ions, glucose, lactate, proteins including ELFO

2) Cytology

3) Microbiology: cultivation, possibly PCR

4) One backup sample (stored at 4 °C)

During the sample collection we can measure the pressure of the cerebrospinal fluid as well. The value in the case of lumbar puncture in patient lying on side is approximately 8-15 mmHg (10-18 cm H2O) or in the case of sitting patient around 16-24 mmHg (20-30 cm H2O).

Physiological findings are summarized in the following tables:

1) Ions

Substance

Value

% of plasmatic value

pH

7,28-7,32

Osmolarity

285 mosm/l

Specific weight

1003-1008

Na+

135-150 mmol/l

K+

2,0-3,0 mmol/l

Ca2+

1,1-1,25 mmol/l

~50 %

Cl

115-130 mmol/l

>100 %

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2) Nutrients and proteins

Substance

Value

% of plasmatic value

Glucose (glycorrhachia)

2,2-4,2 mmol/l

~60 %

Proteins (proteinorrhachia)

0,1-0,40 g/l

~1 % (small proteins mostly, immunoglobulins – IgG, IgM)

Lactate

1,1-2,0 mmol/l

Urea

3-6,5 mmol/l

Lipids

10-30 mg/l

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3) Cells

Type

Value

Erythrocytes

0 / mm3

Lymphocytes

0-5 / mm3

Bacteria

0 / mm3

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Pathological conditions

Many diseases of CNS can cause changes in the composition and concentrations of individual components of cerebrospinal fluid. Testing the CSF thus plays an important role in the differential diagnostics and confirmation of a particular diagnosis.

The most common causes of changes in the composition of cerebrospinal fluid are various kinds of meningitis:

1) Purulent bacterial meningitis

Purulent meningitis is characterized by a purulent (opaque) appearance of fluid, the presence of thousands of neutrophils per mm3; drop in the concentration of glucose (utilized by bacteria as an energy source) and an increase in the concentration of lactate (a product of bacterial metabolism). Very common is a significant increase in the concentration of proteins (bacterial fragment, antibodies etc.).

2) Viral aseptic meningitis

Viral aseptic meningitis usually causes less extensive changes than bacterial infection. Concentrations of glucose and lactate usually stay within physiological range and proteins increase only slightly. Fluid contains mostly lymphocytes, in the order of hundreds of cells per mm3.

Some of the degenerative disorders (for example multiple sclerosis – MS or sclerosis multiplex) are characterized by a presence of so-called oligoclonal bands. They are distinct bands of proteins (or their fragments) visible on electrophoresis, which represent various kinds of antibodies produced by plasma cells.

Hematologic malignancies can cause an infiltration of fluid by tumor cells (e.g. leukemic) revealed during cytological examination.

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Blood-brain barrier and blood-CSF barrier

Blood-brain barrier (BBB, hematoencephalic barrier – HEB)

The term blood-brain barrier denotes the barrier separating the brain tissue from the blood circulation. The structural basis consists of three parts:

1) Layer of endothelial cells interconnected through tight junctions and not containing fenestrations (normally present in endothelium of other tissues)

2) Basal membrane consisting of basal lamina of astrocytes and basal lamina of endothelial cells

3) Protrusions of astrocytes – so-called pedicles, which anneal on the basal membrane

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The main function of BBB is the protection of CNS tissue (especially neurons) against different noxious substances, which would be otherwise able to penetrate to the CNS. The selectivity of BBB prevents many harmful substances from passing into the CNS, but on the other hand allows other (necessary for the brain function) to enter. Generally, hydrophilic substances do not pass BBB until the endothelial cells and astrocytes express appropriate transport channels. The hydrophobic nature of BBB on the other hand allows the penetration of lipophilic substances.

1) Freely, by a passive diffusion, penetrate the BBB:

a) Small molecules: H2O, O2, CO2, NH3, ethanol

b) Lipophilic substances: steroid hormones

2) Selective transporters (facilitated diffusion or active transport) are typical for:

a) Glucose: GLUT-1

b) Amino acids

3) Some of the macromolecules use pinocytosis to pass through BBB

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The presence of BBB has some significant clinical implications. Apart form being important protection mechanisms against microorganisms, reducing the risk of CNS infection, BBB also prevents the passage of antibodies and antibiotics, which can seriously impede body’s ability to fight an infection. Beside the above- mentioned antibiotics, there exist a number of other drugs and substances, which are unable to pass the BBB. One of the examples is dopamine, whose insufficiency is characteristic of a Parkinson’s disease. We cannot use dopamine to treat the disease, as it will not get to the basal ganglia (where the shortage occurs). Instead we have to use its precursor L-DOPA, which penetrates BBB and turns into dopamine in the brain tissue.

Encephalopathy caused by an unconjugated hyperbilirubinemia (called kernicterus) may develop in newborns due to underdeveloped blood-brain barrier that does not prevent the bilirubin from entering the brain tissue. It is however very rare in adults with fully developed BBB.

Some regions of the brain do not have the protection of BBB. These are the chemoreceptor zones with an important function of controlling the composition of blood. Examples include:

1) Subfornical organ: contains osmoreceptors regulating the secretion of ADH

2) Organum vasculosum laminae terminalis (OVLT): contains osmoreceptors regulating the secretion of ADH and triggers the feeling of thirst

3) Area postrema: contains chemoreceptors, which are in control of the vomiting

Blood-CSF barrier (hemato-liquor barrier)

Blood-CSF barrier separates the cerebrospinal fluid and blood. Similar to hematoencephalic barrier, it consists of three structurally distinct parts:

1) Choroidal epithelial cells interconnected by tight junctions (which are more permeable than the junctions between the endothelial cells of brain capillaries) and secreting the cerebrospinal fluid. The side facing the liquor has its surfaced enlarged by the presence of projections called microvilli.

2) Basal membrane

3) Endothelium of the pia mater capillaries containing fenestrations

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Hemato-liquor barrier restricts the passage of substances from the blood into the liquor. It is more permeable than BBB and many plasma proteins thus enter the cerebrospinal liquid (through pinocytosis or active transport). Their concentrations are lower than those of blood plasma. An impairment of hemato-liquor barrier thus leads to an increase in the concentration of proteins in CSF. The transport occurs in the opposite direction as well and the substances from liquor can enter the circulation.

Subchapter Authors: Petra Lavríková and Josef Fontana

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