Lab 5

1. Lab5 Cerebrospinal Fluid(CSF) Part I

2. Introduction • CSF is a clear, colorless liquid fills the cavities of the brain and the spinal cord, surrounding them and acts as a lubricant and a mechanical barrier against shock. • The nervous system of the vertebrate embryo consists of a hollow tube with a canal running through its whole length

3. CSF • Formed primarily in the ventricles. • Flows down through the brain-stem canal, and leaves the central nervous system by being absorbed into surrounding tissue spaces. • Has a slightly alkaline chemical composition, similar to blood. • It contains no RBCs, and low amounts of protein and lipids in comparison to blood, it is about 99 % water. • There are about 100 to 150 ml of CSF in the normal adult body.

5. Formation • CSF is a secretion product of the choroids plexus on the ventricles (ultra filtration of blood in the choroids plexus) also of the ependymal lining of the ventricles of the brain and of the cerebral subarachnoid space . • It assumes its final composition as a result of material exchange between with the blood adjacent brain tissue. • Secretion predominates in the ventricles and absorption in the subarachnoid space (arachnoidvilli); a flow of CSF is produced from the ventricles into the subarachnoid space.

6. Major Transport interfaces in CNS

8. CSF Circulation • CSF circulates from the two lateral ventricles through the Foramen of Monroto the third ventricle • down the Aqueduct of Sylvius • to the fourth ventricle • and into the subarachnoid space via the Themedian aperture and the the lateral apertures .

11. Rate of formation • 0.3 ml/min . • 20 ml/hr. • 500 ml/day.

12. Functions of the CSF • Mechanical Cushion to brain • Source of Nutrition to brain • Excretion of metabolic waste products. • Intra-cerabral transport medium. • Control of chemical evnironment. • Auto regulation of intracranial pressure

13. Sample Collection • Lumbar puncture (spinal tap) is the most common means of collecting a specimen of CSF. • The patient is positioned on his side with his knees curled up to his abdomen and his chin tucked in to his chest (occasionally this procedure is performed with the person sitting bent forward). • The skin is cleaned, and a local anesthetic is injected over the lower spine.

17. Remark • The specimen must be collected under sterile conditions • Sealed immediately to prevent leakage or contamination, and sent to the laboratory without delay. • Specimen should be labeled with the patient’s name, age, date, room number, and suspected disease. • The laboratory staff should be alerted so that they can prepare to examine the specimen immediately. • Blood sample should be collected 30 min. before lumber puncture for glucose, protein and immunoglobulin determination. • The attending physician should be notified as soon as results are obtained so that appropriate treatment can be started.

18. Tube of Collection • Specimens are usually collected in three sterile tubes, labeled 1,2, and 3. in order in which they are drawn (2-4 ml in each tube)., • Tube 1for chemistry and serology, • Tube 2 for microbiology, • Tube 3 is used for cell count and differential

19. Sample Storage • CSF specimens for additional chemical and serological tests should be frozen, hematology tubes are refrigerated, and microbiology tubes remain at room temperature.

20. Lumber puncture – Lying Position

21. Purpose of CSF Analysis • The purpose of a CSF analysis is to diagnose medical disorders that affect the CNS which include: 1. Viral and bacterial infections, such as meningitis and encephalitis . 2. Tumors or cancers of the nervous system. 3. Bleeding (hemorrhage) around the brain and spinal cord. 4. Multiple sclerosis: a disease that affects the myelin coating of the nerve fibers of the brain and spinal cord. 5. Syphilis, a sexually transmitted disease .

22. CSF examination • Physical examination • Chemical examination • Cytological examination • Bacteriological examination

23. I- Macroscopic examination

24. I- Physical Examination (Macroscopic) • Total volume • Adult = 90-150 ml / Neonates = 10 -60 ml. • Distribution • 20 ml in the ventricles. • 60 ml in the subarachnoid space. • 70 ml in the spinal canal.  • Appearance Normal CSF is crystal clear and the consistency of water. The major terminology used to describe CSF appearance includes crystal clear, cloudy or turbid, milky, xanthochromic, and bloody. Normal CSF Xanthochromic CSF

25. Clearity • Normal CSF is crystal clear and the consistency of water. • Cloudy, turbid or milk • WBCs (over 200 cells/µl) • RBCs (over 400 cells/µl) • Mcroorganisms (bacteria, fungi, amebas) • Contrast media • aspiration of epidural fat during lumber puncture

26. CSF Color • Color: • Clear and colorless as Distilled water • Normal • Encephalitis and Meningitis associated with viral infections. • Bright Red • Puncture of blood bessels • Old hemorrhage (yellow supernatant) • Yellow • Xanthochromic : bilirubin from disintergration of RBC in subarchnoid space from old hemorrhage • Excess bilirubin in plasma.

27. Xanthochromicis a term used to describe CSF supernatant that is pink, orange or yellow • Oxyhemoglobin : From lysed RBCs present in CSF before lumber puncture, or traumatic tap • Bilirubin from lysed RBCs in CSF, or increased direct bilirubin with normal blood-brain barrier, or in premature infants • CSF protein levels over 150 mg/dl or traumatic tap with protein concentration over 150 mg/dl. • Contamination of CSF by Merthiolate used to disinfect the skin. • Carotenoids in CSF due to systemic hypercharotenemia • Melanin in CSF due to meningealmelanosarcoma.

28. 3. • Bloody Grossly bloody CSF can be an indication of subarachnoid hemorrhage, but it also may be due to the puncture of a blood vessel during the spinal tap procedure.

29. We can differentiate between both by the following : • Uneven distribution of blood: Traumatic tap often shows significant clearing of blood between the first and third tubes. • Centrifugation: Traumatic tap often shows significant clear supernatant after centrifugation. • Clot formation: Fluid collected from traumatic tap may form clots due to the introduction of plasma fibrinogen into the specimen. • The presence of erythrophagia in blood film of subarachnoid hemorrhage. • Xanthochromic supernatant: intracranial hemorrhage is associated with small Xanthochromia caused by release of Hb from hemolysed RBCs.

30. Continue Macroscopic examination • Specific gravity:1.006 – 1.008 • pH : Alkaline • Spontaneous clotting • Clotting occurs when there is an excess of fibrinogen in the specimen, usually associated with a very high protein concentration. • This finding occurs classically in association with tuberculous meningitis or with tumors in CNS.

32. II- Microscopic examination

33. 1. CSF cell count • The cell count that routinely performed on CSF specimen is WBC's count. • Normal adult CSF contains 0 to 5 WBC's /µl. the number is higher in children and as many as 30 WBC's /µl can be consider normal in newborns. NOTE: Cell counts should be done within 30 minutes after withdrawal of the specimen to avoid cell disintegration. Specimen that can't be analyzed immediately should be refrigerated. Hematocytometer

36. Materials Diluting Fluids • Crystal Violet, 0.2 gm • Glacial Acetic Acid, 10 ml • Distilled Water, 100 ml Note that : (Clear specimen is counted undiluted while the dilution is for the turbid one)

37. Procedures

38.  Notes: • RBCs will be lysed with this method. To perform RBCs count use either undiluted CSF or if many RBC’s present, saline diluent. • Correction for contamination: A calculation is used to correct CSF WBC counts which are falsely increased due to a traumatic tap:

39. 2. Differential cell count : The differential count should be performed on stained smear and not from the cells in the counting chamber, 100 cells should be counted, classified, and reported in term of % (sample should be centrifuged, then sediment is used to make smear)

40. Causes for increased Neutrophils in CSF • Meningitis: • Bacterial meningitis. • Early viral meningoencephalitis. • Early tuberculous meningitis. • Early mycotic meningitis. • Amebic encephalomyelitis. • Other infections: • Cerebral abscess. • Subdural empyema. • Following seizures. • Following CNS hemorrhage: • Subarachnoid hemorrhage. • Intracerebral hemorrhage. • Following CNS infarct. • Reaction to repeated lumber puncture. • Injection of foreign materials in subarachnoid space (e.g., contrast media). • Metastatic tumor in contact with CSF

41. Causes for increased Lymphocytes in CSF • Meningitis: • Viral meningitis. • Syphilitic meningoencephalitis. • Tuberculous meningitis. • Fungal meningitis. • Bacterial meningitis due to listeriamonocytogenes. • Parasitic infestations of the CNS e.g., toxoplasmosis. • Degenerative disorders. • Multiple sclerosis. • Other inflammatory conditions.

42. Causes for increased Eosinophil in CSF • Parasitic infestations. • Fungal infection. • Rickettsial meningitis.

43. Increased number of Monocytes usually occurs as part of a "mixed reaction" • With Neutrophil, lymphocytes, and plasma cells : In Tuberculous meningitis, Fungal meningitis, chronic bacterial meningitis • Without Neutrophil: In viral meningoencephalitis and Syphilitic meningoencephalitis