Lecture #1: Introduction to Hematology

  

Hematology is the branch of medical science that deals with the study of the clinical, morphologic and laboratory disorders of the blood and the blood forming organs.

This study includes the analyses of the concentration, structure and function of cells in the blood; their precursors in the bone marrow; chemical constituents of plasma or serum intimately linked with blood cell structure and function; and function of platelets and proteins involved in hemostasis and blood coagulation.

**** THE BLOOD ****

Blood is vital, life–sustaining fluid circulating constantly in a closed system of blood vessels; it is pumped from the heart into arteries; from the arteries into the capillaries, and from the capillaries into the veins to return back to the heart.

Blood is highly complex liquid connective tissue in which the cellular elements are suspended in a liquid supporting or ground substance.

FUNCTIONS OF THE BLOOD

1. It transports oxygen from the lungs to the tissues and carbon dioxide from the tissues to the lungs to be eliminated.

2. It serves as a vehicle for transport of food materials to the different tissues of the body.

3. It picks up metabolic end products and delivers to other organ for use or elimination.

4. It distributes the heat produced in active muscles and thus aids in the regulation of body temperature.

5. It transports hormones from the glands in which they are produced to the target organs.

6. Through the presence of buffer system, it helps maintain optimal pH of the acid – base equilibrium.

7. It regulates the water balance through the effects of blood in the exchange of water between circulating fluid and tissue fluid.

8. It serves in the mobilization of defense mechanism by protecting the body against bacterial invasion and disease through the activities of certain leukocytes and immune bodies in the blood stream.

9. It maintains a degree of irritability of the tissue cells so that functional activity can be carried on satisfactorily.

**** COMPOSITION OF THE BLOOD ****

A. Fluid portion – approximately 55%

Blood plasma is the fluid portion of the blood. It is a straw colored fluid containing a variety of substances and with complex chemical composition. It is the fluid portion that remains when coagulation is prevented. If blood is allowed to clot, the liquid part that separates from the clot is called serum.

Constituents of the liquid part:

a. Water

b. Inorganic constituents – sodium, calcium, potassium, magnesium, chloride, bicarbonate, phosphate, sulfate

c. Organic constituents

1. Plasma proteins

(a)   Albumin – its primary function is to cause osmotic pressure at the capillary membrane. This pressure called colloid osmotic prevents the fluid of the plasma from leaking out of the capillaries into the interstitial spaces.

(b)   Globulin – alpha, beta and gamma globulins

Alpha and beta globulins – transport substances by combining with them, acting as substrates that react with other substances, transporting protein itself from one part of the body to another.

Beta and gamma globulins – protects the body against infection.

Gamma globulins – antibodies that resist infection and toxicity thus providing the body with immunity.

(c)    Fibrinogen – plays a role in blood clotting

d. Internal secretions (hormones), antibodies and various enzymes as amylases, proteases, lipases, etc.

e. Gases – oxygen, carbon dioxide, nitrogen

B. Solid portion – approximately 45%

The solid portion consists of the cellular elements:

a. Red blood cells or erythrocytes

b. White blood cells or leukocytes

c. Hemoconia  or Mueller’s blood dust; very small powdery or dust like particles which are increased after eating fats

**** GENERAL CHARACTERISTICS OF THE BLOOD ****

A.     COLOR

Arterial blood is bright red due to high oxygen content; venous blood is very dark or purplish red due to low oxygen content. The colors of the blood from the pulmonary veins and arteries are reversed since they carry blood from and to the lungs capillaries for the elimination of carbon dioxide and pick up oxygen.

B.     VOLUME

It varies with the size of the person, the total volume approximately 6 – 8% of the total body weight. At birth, the total blood volume is around 250 – 350 ml. After infancy, the volume increases gradually until adult life. The total blood volume for adult men and women ranges from 60 – 80 ml/kg body weight.

As a rule, the blood volume remains remarkably constant in an individual and rapid adjustments take place within few hours after blood transfusion or intravenous infusion. There is therefore no danger involved in taking one half liter of blood for transfusion, and no risk in taking two ml tubes or more for analysis.

C.     VISCOSITY

The relative viscosity in vitro at 18^oC:

Whole blood – 3.8 – 5.7

Plasma – 1.67 – 2.35x

Serum – 1.58 – 2.18x

D.    SPECIFIC GRAVITY

Whole blood, men – 1.055 – 1.064

Whole blood, women – 1.052 – 1.060

Plasma – 1.025 – 1.029

Serum – 1.024 – 1.028

E.     REACTION or pH

Alkaline with pH range from 7.35 to 7.45

F.      OSMOLALITY

Serum – 281 to 297 mOsm/kg H₂O

**** COLLECTION OF BLOOD *****

The proper collection of blood is essential for satisfactory examination. It is important therefore to consider in detail various collection techniques.

Blood should be collected in chemically clean or sterile containers, for blood is an excellent culture medium for certain types of microorganisms. Containers should be thoroughly cleaned, rinsed and dried after washing.

All specimens should be labeled carefully at the time the blood is taken, giving the name of the patient, date and other pertinent information.

The two sources of blood for hematological tests are capillary or peripheral blood and venous blood. Venous blood is preferred for most hematological examinations but peripheral samples can be almost as satisfactory for some purposes if a free flow of blood is obtained.

Capillary or Peripheral Blood

Capillary blood is liable to give discrepant results, and should only be used:

1. When venipuncture is impractical, e.g., infants and in cases of extensive burns.

2. When small quantities of blood are required in the examination.

3. When the patient is bedridden and the operator feels that the skin or capillary puncture is easier to manipulate.

4. When the blood examination requires free flowing capillary blood as in clotting time and bleeding time determinations.

Sites of skin puncture

1. Palmar surface of the tip of a finger, 3^rd or 4^th finger of the left hand or the one which is less used.

2. Plantar surface of the great toe or heel of an infant especially in the newborn.

3. Free margin of the ear lobe, not the side – is recommended for small children, patients with poor veins, for some special tests and for patients who are extremely edematous, especially in the extremities.

Equipment:

1.     Puncturing instruments

a. Disposable needle or lancets which are commercially available in sealed containers

b. Hagedorn needle

c. Bard–Parker blade #11

d. Small scalper or blade

2.     Sterilizing agents

a.     70% alcohol

b.     Ether

c.      Alcohol–ether mixture

d.     1% alcohol solution of iodine

Advantages of finger puncture:

1. The finger is accessible and could easily be managed.

2. Skin at the site is elastic and tends to close the wound easily.

3. It is preferably employed for preparing blood films or smears but the blood must flow freely to avoid altered distribution of leukocytes

Advantages of earlobe puncture:

1.     Skin is thin and puncture is less painful.

2.     Post–puncture tenderness is avoided.

3.     Less tissue juice.

Disadvantages of skin or capillary puncture in general:

1. Small amount of blood is obtained and the examination can’t be repeated.

2. Capillary or peripheral blood frequently hemolyzes.

3. Skin puncture yields more nearly arteriolar than capillary blood and hematocrit, red cell count and hemoglobin content of true capillary blood are significantly less than venous blood.

4. Platelet count is lower in capillary blood due to adhesion of platelets to the site of skin puncture.

5. Fragility of red cells obtained from capillary blood is more than that of venous blood.

6.     White blood cell count is higher in capillary blood than venous blood.

7.     Precision is poorer in capillary than in venous blood because of variation in flow and dilution with interstitial fluid.

Technique

The site is first rubbed vigorously with a gauze pad or cotton ball moistened with 70% alcohol or other sterilizing agent to remove dirt and epithelial debris and to increase blood circulation. After the skin has dried, a puncture 2–3 mm deep is made with the blade or lancet. A rapid, firm puncture should be made, but with the control of the depth and site. With a sharp blade, the blade puncture gives little pain. A deep puncture is no more painful than a superficial one which makes repeated punctures necessary.

The skin at the site of puncture should be dry. The first drop of blood, which contains tissue juices, is wiped away. The second drop is used for examination. The blood must not be pressed out, since this dilutes it with fluid from the tissue juices. Moderate pressure some distance above puncture is allowable. After the needed blood has been obtained, a pad of sterile gauze is applied to the puncture and the patient is instructed to apply slight pressure until bleeding has ceased.

Pointers in doing a skin puncture

1. An edematous or congested part should not be used.

2. Cold and cyanotic skin is not advisable to use – it gives false high cell count.

3. Disposable lancets or needles are highly recommended.

4. Whichever site is used, make sure it is warm to guarantee dilated skin vessels and thus ensure a free flow of blood.

5. For earlobe puncture, the ear must be rubbed with lint until warm and pink. When the heel is used, it must be made warm by immersion in warm water or by use of hot water compress. Otherwise, values significantly higher than in venous blood may be obtained, especially in newborn.

6. After sterilizing the site, puncture through a dry area to be able to obtain a whole rounded drop of blood.

7. First drop of blood is discarded because it contains tissue juices and other particulate matters lying over the skin.

8. The ideal depth of skin is 2 to 3 mm.

9. Vigorous squeezing after the puncture should be avoided because it causes the admixture of tissue juices. Moderate pressure some distance above the puncture is allowable.

10.  Free flow of blood is essential to obtain reproducible results comparable to those with venous blood.

Venous blood

The venipuncture is in most instances a relatively simple procedure. The patient’s life may depend on vein potency and care must be taken to preserve these vessels. Hematomas or ecchymosis are usually evidence of the operator’s poor technique or judgement.

Venous blood is preferred for most hematological examinations because venipuncture is:

1. Easier and more convenient to obtain and adequate volume of blood suitable for a variety of tests.

2. It offers the fastest method of collecting samples from a large number of patients.

3. It reduces the amount and variety of apparatus to be carried to the hospital wards.

4. It allows various tests to be repeated.

5. It allows the performance of additional tests that may be requested.

6. It reduces the possibility of error resulting from dilution with tissue juices or constriction of skin vessels by cold or emotion that may occur in taking blood by finger puncture.

Sites of venipuncture

1. Antecubital fossa (vein in the arm at the bend of the elbow) – median cephalic / median basilic vein

2. Veins of the dorsal surface of the hand

3. Veins of the ankle

4. External and internal jugular veins

5. Femoral vein

6. Superior longitudinal sinus

7. Long saphenous vein

Venous blood is best drawn from an antecubital vein

Equipment

Equipment consists of gauze pads or cotton balls, sterilizing agent, tourniquet and syringe with a needle or a vacutainer.

Tourniquet may be:

1. Soft rubber tubing at least 2 – 5 cm in diameter and 18 inches in length.

2. Blood pressure  cuff inflated to 40 to 60 mmHg

3. Band–quet tourniquet – 1 inch wide rubber band

Needles

The gauge and length of the needle are chosen for the specific task. The gauge number expresses the diameter of the needle: the smaller the number, the larger the needle. The length of the needle used depends upon the depth of the vein. The tip should be inspected carefully. A blunt or bent tip will damage the patient’s vein and often leads to failure.

Length:                                    30 – 40 mm

Diameter or gauge:    0.9 mm (20 gauge)

1.0  mm (19 gauge)

1.1  mm (19 gauge)

1.2  mm (18 gauge)

0.6 mm (23 gauge)

0.5 mm (25 gauge)

1.625 mm (14 gauge)

Usually, for adults 20 or 19 gauge is suitable. For children under the age of five, 23 or 25 gauge needles can be used.

Syringes

The syringe should be of the proper size for the amount of blood to be drawn. Disposable plastic syringes are widely used. With reusable glass syringes, the fit of the plunger and barrel and the integrity of the syringe should be checked. Instead of syringes, evacuated blood collection tubes may be employed. Evacuated tubes, e.g., Vacutainer sealed with a stopper, are supplied with a measured amount of anticoagulant (or none) and sufficient vacuum to draw a pre–determined volume of blood.

Venipuncture with vacuum containing system is ideal in terms of direct sampling, economy and efficiency. These systems provide flexibility in terms of specimen volume (2, 3, 5, 7 or 10 ml per tube) and anticoagulant as well as chemically clean or sterile glassware.

Method to increase the amount of blood in the arm and to distend the veins:

1. Using a tourniquet

2. Having the patient close and open his fist

3. Massaging the arm

4. Slapping or thumbing the arm at the site of puncture

5. Immersing the arm in warm water or covering with a hot, wet towel for 5 or more minutes prior to venipuncture.

Factors involved in a good venipuncture:

1. The venipuncturist

The operator must be aware not inflict damage and preserve the veins for innumerable future uses. The hematomas displaying all the colors in the site of puncture testify to the operator’s lack of skill or judgement. As a rule, the damage is only temporary but it may be long lasting or even permanent. Therefore, venipuncture must be approached with extreme care and deliberation.

2. The patient and his veins

The patient should be reassured with kind words. Self–assurance and poise will do much to establish the proper rapport. The patient should be made comfortable and the approach to his arm should be convenient for the operator.

The veins should be checked and evaluated. When veins are deep and not felt distinctly, use a tourniquet. Use any technique to make the veins more prominent before you do the actual puncture.

3. Equipment

Syringe size is determined by the volume of blood required. Disposable plastic syringes are most widely used. The gauge and length of the needle used depend on the size and depth of the vein. The gauge number varies inversely with the diameter of the needle.

Pointers in doing venipuncture:

1. To prevent hemoconcetration, the tourniquet pressure should not be maintained longer than necessary. The outer end of the tourniquet should be tucked under so that a slight pull will release it.

2. To distend the veins, the patient is asked to open and close the fist several times.

3. Even if not seen, veins can usually be felt beneath the skin. In fat persons, veins that show as blue streaks are usually too superficial and too small.

4. Loosen the tourniquet if blood flows freely, otherwise, leave it in place until the desired amount of blood is obtained. At this time, have the patient open his fist, release the tourniquet, withdraw the syringe and needle, and apply gentle pressure to the puncture site with dry gauze or cotton.

5. The operator must see that the patient’s condition is satisfactory before he is dismissed. If there is any sign of continued discomfort, anxiety, bleeding or shock, the patient should be kept lying down and seen by a physician.

6.     Hemolysis interferes with many examinations and therefore should be minimized.

HEMOLYSIS

Hemolysis is the destruction of the red blood cells. It is a process which should be prevented to take place during the collection of blood. It affects the results of various hematological examinations. It can be prevented by observing the following:

1. Use of dry syringe and needle.

2. Use of clean dry glassware and not too thin needle.

3. Draw blood slowly, not faster than the vein is filling.

4. Avoid rough handling of blood.

5. Don’t eject blood from the syringe through the needle. Remove the needle first.

6. Avoid frothing by ejecting blood gently down the side of the tube.

7. Avoid admixture of air.

8. Mix the blood with anticoagulant by gentle inversion, not by shaking.

9. Don’t freeze blood because the red cells will hemolyze on thawing.

10.  Make sure that all solutions with which blood is to be mixed or diluted are correctly prepared.

11.  Stopper and store blood sealed, if examination is to be delayed beyond 1 to 3 hours, store in a refrigerator.

12.  Use of isotonic solutions.

Complications of venipuncture and suggestions for their prevention:

A. Immediate local complications

1. Hemoconcentration – increased amount of cellular elements in the blood due to prolonged application of tourniquet (i.e., over 60 seconds)

Suggestion: Release the tourniquet immediately after sufficient blood has entered the syringe

                             

2. Failure of the blood to enter the syringe – this maybe due to:

a. Excessive pull of plunger collapses the vein

Suggestion: Slight back and forth movement reduces the force of aspiration

b. Piercing the outercoat of the vein without entering the lumen

Suggestion: Withdraw the needle slightly and reenter the vein

c. Transfixation of veins – piercing through the walls of the veins

Suggestion: Withdraw the needle slightly and gently aspirate to see if blood enters. If

                        This fails, the puncture may have to be reported.

3. Hematoma / ecchymosis – subcutaneous effusion of blood resulting to discoloration, pain, swelling and tumor–like mass.

Suggestion:           Repeat puncture on another site

4. Circulatory failure – failure of the blood to flow due to nervousness and other emotional factors

Suggestion:           This is not beyond the control of a medical technologist.

                              Call a physician

5. Syncope – fainting due to sudden insufficiency of blood supply to the brain.

Suggestion:                       Let the patient lie flat on the bed and call a physician

6. Continued bleeding – this may occur in patients with hemorrhagic tendency.

Suggestion:                       Local pressure controls bleeding

B. Late local complications

1. Thrombosis – clotting of blood inside the vessel due to trauma and repeated infections.

2. Thrombophlebitis – inflammation of the vein in which a thrombus (blood clot) is present.

Suggestion:           These complications are under the care of a physician

C. Late general complications

Serum hepatitis may be caused by transmission of the virus by contaminated needle or syringe. The use of disposable needles has virtually eliminated the source of transmitted disease.

**** ANTICOAGULANTS ****

Anticoagulants are chemical agents that prevent blood from clotting.

If venous blood is to be used for examination, an anticoagulant is required. The choice of anticoagulant and the ratio of blood to anticoagulant are of great importance. Dry anticoagulants are used to avoid dilution which lowers the concentration of the formed elements in the blood. The anticoagulant selected must not alter the size of the red cells, nor bring about their hemolysis, it must minimize disruption of the leucocytes and it must be readily soluble in blood.

Since a measured amount of dry anticoagulant is generally already present in the vessel used to receive blood to be obtained by venipuncture, the operator must be certain that the volume of blood required for the amount of anticoagulant is actually delivered into the vessel and promptly mixed with the anticoagulant. If too much blood is added, small clots may form; sometimes these are not easily noted but are nevertheless, capable of altering the values. If too little blood is added, the red cells may be crenated, thereby falsely reducing the volume of packed red cells and the corpuscular indices derived therefrom.

Since the formed elements of the blood tend to settle upon standing, it is essential that, prior to sampling for blood counting and other examinations, the venous blood be gently but thoroughly mixed.

The specimen must also be checked for visible autoagglutination of red cells and aggregation of platelets, and for the presence of clots. Insufficient attention paid to these simple matters may vitiate the significance of blood counts and other examinations performed by the most costly apparatus or by trained medical technologist.

A.   Heparin

Heparin is present in most tissues of the body, but in concentration less than that required to prevent the blood from clotting. It was first found in the liver and named from hepar, the Greek word for that organ. In the body, it exists, in the highest concentration in the liver and the lungs. It is a mucoitin polysulfuric acid and is available as the sodium, potassium and ammonium salts.

Action of heparin as anticoagulant

1. The heparin – protein complex inactivates thromboplastin, the first phase substance needed to start the series of clotting steps.

2. It has a direct antithrombin action, that is, it inactivates any molecule of thrombin in the presence of a cofactor located in the albumin fraction of the plasma.

Formula

1 mg of dry heparin or 0.1 ml of liquid heparin per 10 ml blood

0.1  – 0.2 mg of dry heparin per ml of blood

Preparation of saturated heparin solution

Powdered heparin – 1.0 gram

Distilled water – 100 cc

Evaporate to dryness at 37^oC – 56^oC

Advantages

a. Excellent and natural anticoagulant usually prepared from lungs of animals.

b. Does not alter the corpuscular size and therefore heparinized blood has been used as a standard for comparison of the effects of various inorganic anticoagulants.

c. Best anticoagulant for prevention of hemolysis and is therefore recommended for osmotic fragility tests.

d. Less toxic than sodium citrate and therefore is preferred as an anticoagulant for open heart surgery and exchange transfusions in which large quantities of blood are given rapidly.

e. Used for electrolyte determination, erythrocyte sedimentation rate and test for blood pigments.

f.  Especially used for erythroblastosis fetalis

Disadvantages

a. Expensive

b. Not recommended for study of morphology of the cells; it gives a blue background on a blood smear stained with a Romanowsky dye, e.g. Wright’s stain.

c. Temporary action – the anticoagulant effect in vivo is of short duration but if used in adequate concentration in vitro will prevent coagulation of refrigerated blood for 3 or more days.

d. Not satisfactory for serological tests.

e. Not to be used for white cell and platelet counts as it tends to cause the white cells and platelets to clump.

B.   Sequestrene

This is also known as ethylenediaminetetraacetic acid (EDTA) or versene

Action of EDTA as anticoagulant

It acts as a chelating agent which combines with calcium and binds it in a non–ionized form. The disodium or dipotassium salt of EDTA is an effective anticoagulant in the proportion of 1 to 2 mg / ml of blood or 0.1 ml of 10% solution in water per 5 ml of blood.

Preparation of 10% sequestrene solution

Sequestrene (dry powder) – 10 grams

Distilled water – 100 ml

Advantages

a. Preserves cellular elements of the blood and doesn’t cause significant changes in the size and shape of RBC and WBC.

b. Satisfactory for erythrocyte sedimentation rate, hematocrit, cell counting, electrophoresis, fetal hemoglobin and blood grouping procedures.

c. Prevents agglutination of platelets and is preferred for thrombocyte studies. Platelet counting is still possible after several hours since it tends to prevent surface adhesion and clumping of platelets.

d. Recommended for blood smears because it prevents formation of artifacts even on prolonged standing.

e. May also be used in blood transfusion as it has a few toxic effects.

Disadvantages

            It is not suitable for use in the investigation of coagulation disorders especially in the

            estimation Prothrombin time.

C.   Oxalates

Action of oxalates as anticoagulant

Oxalates such as sodium, potassium, ammonium or lithium inhibit blood coagulation by forming rather insoluble complexes with calcium ions which are necessary for coagulation.

1. Dried ammonium–potassium oxalate

Other names:       Double oxalate           Wintrobe’s fluid

                              Balanced oxalate       Heller – Paul fluid

Preparation of the anticoagulant

3 parts of ammonium oxalate – 1.2 grams

2 parts of potassium oxalate – 0.3 grams

Distilled water – 100 cc

Advantages

a. The balanced action of this anticoagulant – ammonium swells the cells and the potassium shrinks the cells – preserves the cells from hemolysis thus it does not produce significant shrinkage or enlargement of red cells.

b. May be used for erythrocyte sedimentation rate, cell counts, hemoglobin, hematocrit determination and mean corpuscular values.

c. Cheap, easy to prepare and requires no dilution.

Disadvantages

a. Cannot be used for chemistry examination especially in the determination of urea, nitrogen or potassium

b. Cannot be used for blood transfusion

c. Causes distortion of cells and clumping of platelets

d. Not recommended for morphological studies because it causes clover leafing of leucocyte nuclei, crenation of red cells, vacuolation in the cytoplasmic of granulocytes, phagocytosis of oxalate crystals, artifact formation in the nuclei of lymphocytes and monocytes and other malformations develop rapidly.

2. Potassium oxalate

This is used as anticoagulant in the proportion of 1 to 2 mg per ml of blood. Dried sodium or lithium oxalate can be substituted for potassium oxalate.

Note:

Temperature in excess of 80^oC should be avoided during the drying of oxalates since at elevated temperature the oxalates will be converted to carbonate which has no anticoagulant property.

D.  Citrates

Action as anticoagulant

Citrate forms a double salt with calcium and binds it in a non–ionized form.

Formula

1 part of 3.8% disodium citrate and 4 parts of blood is the usual proportion for routine use especially for erythrocyte sedimentation rate determination (Westergren method).

1 part of 3.8% or 3.2% aqueous solution of di– or tri–sodium citrate and 9 parts of blood is the proportion for investigation of the clotting mechanism.

Buffered citrate (sodium citrate and citric acid) – stabilizes plasma pH

Advantages

1. Citrate is widely used in collecting blood for transfusion since it is relatively non–toxic salt which is rapidly utilized by the body or excreted by the kidneys.

2. Trisodium citrate is used for blood coagulation and platelet function studies.

3. Buffered citrate is now commonly used because it helps stabilize plasma pH.

For better long term preservation of red cell for enzyme studies and for the study of hemolytic disorders and for transfusion purposes, citrate is used in combination with dextrose in the form of Acid Citrate Dextrose (ACD), Citrate Phosphate Dextrose (CPD) or Alsever’s solution. Dextrose prolongs the survival of red cells.

Standard preparation of Acid Citrate Dextrose (ACD)

            Trisodium citrate                                           –          1.32 grams

            Citric acid                                                        –          0.48 grams

            Dextrose                                                         –          1.4 grams

            Distilled water                                                –          100 ml

            1 ml ACD is sufficient to prevent coagulation of 4 ml blood

Preparation of Citrate Phosphate Dextrose (CPD)

            Trisodium citrate                                                       –          30 grams

            Sodium dihydrogen phosphate, monohydrate        –          0.15 grams

            Dextrose                                                                     –          2 grams

            Distilled water q.s.ad                                                             –          1 liter

Preparation of Alsever’s solution

Glucose                                               –          20.5 grams

Trisodium citrate, dihydrate                         –          8 grams

NaCl                                                    –          4.2 grams

Water, distilled q.s.ad.                      –          1 liter

4 parts blood are mixed with 1 part of Alsever’s solution

E. Fluoride

Action as anticoagulant

Fluoride forms a weakly dissociated calcium component and thus prevents coagulation. Although considered as a preservative for blood glucose determination, it also acts as a weak anticoagulant. When used as a preservative along with an anticoagulant as potassium oxalate, it is effective in a concentration of about 2 mg/ml of blood. It exerts its action by inhibiting the enzyme system involved in glycolysis.

When sodium fluoride is used as anticoagulant, the concentration must be much greater, 6 – 10 mg/ml blood. As a general rule, fluoride should not be used when collecting blood specimens for enzyme determination or when using an enzyme as a reagent in a test, e.g. urease method for the determination of urea.

Fluoride acts as a powerful enzyme poison – hence it is also used as a preservative, especially for blood and CSF sugar estimation where there is likely to be more than ½ to 1 hour delay between the taking of the specimen and actual analysis.

10 mg sodium fluoride per ml blood plus 1 thymol

**** BLOOD PREPARATION COMMONLY EMPLOYED IN HEMATOLOGY ****

Before blood is examined, it usually undergoes some form of preparation. The kind of blood preparation depends on the examination to be done. However, there are some examinations which require no such preparation but instead; blood is examined as it flows freely from the puncture as in bleeding time determination.

A. Diluted Blood

For cell counts, e.g. white cell count, red blood count, platelet count (direct method) and eosinophil count, the dilution is made by sucking a measured portion of blood and diluting fluid into a pipette. For hemoglobin determination and other special examinations, the dilution is done in a standard test tube.

Keeping time: Diluted blood is not very stable. For the platelet count, it will only keep for about 30 minutes. For other tests, the diluted blood will keep for about 2 hours.

B. Blood smear

Blood smear may be prepared with the use of two glass slides or two cover glasses or with a slide and a cover glass.

Blood smear is used in the following tests:

1. Differential leukocyte count

2. Morphologic study of normal and abnormal white cells, red cells and platelets

3. Reticulocyte count

4. Platelet count (indirect method)

5. Lupus erythematosus cell (L.E.) examination

6. Bone marrow examination – bone marrow film

Keeping time: The blood smear should be stained within 2 hours after it is made. Once stained, it may be kept for about 2 years.

C. Whole blood or Non–clotted blood

If whole blood is needed in the examination, blood should be prevented from clotting by adding an anticoagulant. Depending on the anticoagulant used, blood may be oxalated, sequestrenized, heparinized or citrated.

Non–clotted blood is used in those tests which require blood plasma and therefore may also be used in preparing dilute blood.

Keeping time:

The keeping time of non–clotted blood depends upon the examination and the anticoagulant used; it may be kept for 1 hour to even 24 to 48 hours provided precautionary measures like refrigeration and prevention of hemolysis are observed.

D. Blood plasma

When clotted blood is centrifuged, the liquid portion which separates is called plasma. It is prepared with a special type of anticoagulant and is used in the following tests:

1.     Prothrombin Time

2.     Partial Thromboplastin Time

3.     Fibrinogen Deficiency Test

4.     Thromboplastin Generation Time

5.     Other tests for coagulation disorders

Keeping time: None, because it should be prepared directly after the blood is withdrawn and should be used immediately.

E. Blood serum

When blood is placed in a test tube and allowed to clot, after sometime, the clot retract an expresses a fluid called serum. This serum is pipetted off and used in the following tests:

1.     Prothrombin Time

2.     Partial Thromboplastin Time

3.     Thromboplastin Generation Time

4.     Other tests for coagulation disorders

Keeping time: It should be kept within 2 hours after prepping; otherwise, cells may lose their clumping or agglutinating power.

F. Cell suspension

When an isotonic solution like normal saline solution (NSS) is placed in a test tube a few drops of blood are added, the preparation is called cell suspension. This may also be prepared by allowing the cells to suspend in their own serum. This kind of blood preparation however is seldom used in Hematology.

Keeping time: It should be kept within 2 hours after preparing, otherwise, cells may lose their clumping or agglutinating power.

G. Defibrinated blood

Defibrination (removal of fibrin from the blood) is done by the:

1. Use of applicator sticks in which 3 to 4 paper clips are attached to one end and is twirled in the blood sample until all fibrin thread are attached to the clips.

2. Use of glass beads – about 25 ml blood in an Erlenmayer flask containing 20 (3 – 4) glass beads. Flasks are rotated until the beads are covered with fibrin and cease to make a rattling sound.

3. Use of 0.5 cm length of glass rod which is held in place by thrusting into the bore of a stopper or cotton. Blood is placed into the flask and the rod is fused inside; this is then rotated in a figure of 8 motions for 5 – 10 minutes until all fibrin threads adhere to the rod.

After removing the fibrin strands by means of any of the methods previously described, the resulting blood preparation is called defibrinated blood which is used for morphologic study of white cells, red cells and for lupus erythematosus cell (L.E. examination)

H. Blood collected in siliconized glassware

The glassware is first coated with a suitable water dilution of a water soluble silicon concentrate by immersion in the solution for 5 seconds or longer. Then the glassware are rinsed well with water and then dried at room temperature for 24 hours or in hot air over at 100^oC for 10 minutes.

This blood collected in silicon coated glassware is used in various platelet examinations. It should be immediately used.

I. Buffy coat preparation

A number of methods are available for the concentration of leukocytes, platelets and nucleated cells which collect above the column of packed red cells. This buffy layer is sometimes called the “white cell concentrate.”

Venous blood, anticoagulated or defibrinated is centrifuged for 15 minutes in a Wintrobe hematocrit tube at 3000 rpm. The supernatant liquid is thrown off and the buffy layer is pipetted and ejected on one or two clean slides. After emulsifying the buffy coat in a drop of the patient’s serum or plasma, films are spread, allowed to dry in air, fixed and stained in the usual way.

When leucocytes are scanty or if many slides are to be made, it is worthwhile centrifuging the blood twice; first, centrifuge 5 ml blood and then fill a hematocrit tube with upper cell layers of the previously centrifuged sample and recentrifuge.

As an alternative to centrifugation, the blood may be allowed to settle, with the help of sedimentation–enhancing agents such as fibrinogen, dextran, gum acacia, Ficoll or methyl cellulose.

Uses of buffy coat

1. In the diagnosis of various cases of leukopenia.

2. In the diagnosis of various cases of leukemia.

3. In searching for blasts and other immature cells, megakaryocytes, nucleated red cells, phagocyte and atypical cells.

4. In the examination of lupus erythematosus cells.

5. In searching for megaloblasts in pernicious anemia.

6. In searching for nucleated red cells and immature granulocytes in metastatic malignancy.

7. In determining the presence of erythrophagocytosis in hemolytic anemia and chronic granulomatous infection.