Erythrocyte Information and Courses from MediaLab, Inc.

Spinal fluid samples are either clear or turbid. Some sources use the following rating system for turbid CSF specimens: 0 = crystal clear fluid 1+ = faintly cloudy, smoky, or hazy 2+ = turbidity clearly visible but newsprint read easily through tube 3+ = newsprint not easily read through tube 4+ = newsprint cannot be seen through the tubeTurbidity may be caused by leukocytes, erythrocytes, fungi, bacteria, amoebae, contrast media, or aspiration of epidural fat during puncture.200 leukocytes/mm3 will cause slight turbidity (1+); increased numbers of WBCs will cause increased turbidity. At least 400 erythrocytes/mm3 are needed to produce 1+ turbidity.Occasionally CSF will have an oily appearance due to the presence of substances remaining in the CSF after radiologic (x-ray) procedures have been performed.

Bilirubin is formed as a result of the breakdown of hemoglobin from erythrocytes in the reticuloendothelial system. It becomes bound to albumin and transported through the blood to the liver. This free or unconjugated bilirubin is insoluble in water and cannot be filtered through the glomerulus of the kidney. In the liver, bilirubin becomes conjugated with glucuronic acid to form bilirubin diglucuronide. This conjugated bilirubin, which is also called direct bilirubin, is water soluble and is excreted by the liver through the bile duct and into the duodenum.

Pappenheimer bodies, while visible on a Wright's stained smear, should be Perls' Prussian blue stain, which is specific for iron. Pappenheimer bodies are seen in certain types of anemia characterized by an increase in the storage of iron, such as sideroblastic anemia and thallassemia. These inclusions are also seen in the peripheral blood following a splenectomy. In a healthy person with a normal spleen, Pappenheimer bodies are destroyed before the erythrocytes enter the peripheral circulation.

To verify that red cell inclusions contain iron, it is necessary to use an iron stain, such as Perl's Prussian blue. The iron-containing granules are called siderotic granules. A mature erythrocyte containing siderotic granules is referred to as a siderocyte, while an immature (nucleated) erythrocyte containing siderotic granules is known as a sideroblast. A Pappenheimer body is a siderotic granule which is visible on Wright stain. All Pappenheimer bodies are Prussian blue positive, but not all siderotic granules are visible on Wright's stain as Pappenheimer bodies.

The number and size of the reticulocytes seen on a Wright's stained smear give valuable information regarding the effectiveness or ineffectiveness of erythrocyte production.

This slide is a picture of erythrocytes which contain Cabot rings.

To help you learn to differentiate myeloid cells and erythrocytes under high power, some slides showing thinner areas than would normally be used for determination of the M:E ratio have been included. Erythroid cells are shown at the arrows.

Erythrocytes are non-nucleated, round, biconcave, disc-shaped cells They are 6.7 to 7.7μ in diameter, 2μ thick, and have an average volume (Mean Corpuscular Volume, MCV) of 80-100μ3.

Erythrocytes are produced in the bone marrow and released into the peripheral blood where they may remain for approximately 120 days before senescence.Their main function is the transport of the respiratory gases (oxygen and carbon dioxide) between the lungs and body tissues.Each erythrocyte can be thought of as an "envelope" containing hemoglobin.Each hemoglobin molecule contains iron which has a high affinity for oxygen.As a result, when an erythrocyte passes through one of the capillaries of the lungs, it picks up oxygen.The oxygen is transported through the blood to the tissues where it is released.Carbon dioxide from the tissues then diffuses into the RBC where it undergoes chemical changes.About 70% of the altered carbon dioxide diffuses into the plasma, 25% binds to the hemoglobin molecule, and 5% goes into simple solution within the red cell.In each of these three ways carbon dioxide is transported from the body tissues back to the lungs, where it is released.

Antibody - A modified type of serum globulin synthesized by lymphoid tissue in response to antigenic stimulus. By virtue of specific combining sites each antibody reacts with only one antigen. Anucleate - Having no nucleus. Azurophilic granules - The well-defined large reddish granules (lysosomes) which may be present in large lymphocytes. They are called "azurophilic granules" because they stain blue with the azure stains which were originally used. Basophilic granules - Specific granules present in the cytoplasm of basophils. These granules are large and stain purple-black due to their strong affinity for basic stain. B-cell - Bone marrow derived lymphocytes which produce humoral antibodies. Biconcave - Having two concave surfaces. Cellular Immunity - The capacity of a small proportion of lymphoid population to exhibit response to a specific antigen. Chromomere - The centrally located granular portion of the platelet. Clone - A population of cells descended from a single cell. Delayed Hypersensitivity - (part of cellular immunity) that develops slowly over a period of 24-72 hours after an antigenic stimulus. It consists of an accumulation of cells around small vessels and/or nerves. Example: Tuberculin skin test reaction. Digestive Enzyme - A substance that catalyzes or accelerates the process of digestion. Eosinophilic Granules - Specific granules present in the cytoplasm of eosinophils. These granules are large, refractile spheres which stain reddish-orange due to their strong affinity for acid stain. Erythrocyte (red blood cell, RBC) - One of the elements found in peripheral blood. Normally the mature form is a non-nucleated, circular, biconcave disk adapted to transport respiratory gases. Fixed Macrophage - A phagocyte that is non-motile. Free Macrophage - An ameboid phagocyte present at the site of inflammation. Graft Rejection - A transplanted tissue that is rejected by the body's antibodies. Graft vs. Host Reaction - A complication that occurs when an implanted piece of tissue, which contains antibodies, rejects the host's tissue. Granulocyte - A leukocyte which contains granules in its cytoplasm, i.e., neutrophilic, eosinophilic, or basophilic granules. Half-life - is the length of time it takes for half of the cells circulating at a given time to leave the blood for the tissues. Hemocyte - Any blood cell or formed element of the blood. Hemostasis - A mechanism of the vascular system to arrest an escape of blood. It involves an interaction between blood vessels, platelets, and coagulation. Heparin - A mucopolysaccharide acid which, when present in sufficient amounts, functions as an anticoagulant by inhibiting thrombin. Histamine - A powerful dilator of capillaries and a stimulator of gastric secretions. Humoral Immunity - Acquired immunity produced after response to an antigenic stimulus in which B cells produce circulating antibodies. Hyalomere - the clear, blue non-granular zone surrounding the chromomere of a platelet. Immune Response - The interaction of a cell and an antigen that results in a proliferation of the cell and a capacity to produce antibodies. Isotonic Fluid - A fluid whose elements have an equal osmotic pressure. Leukocyte (white blood cell, WBC) - One of the formed elements of the blood; involved primarily with the body's defense. Lysosome - A microscopic body within cell cytoplasm; contains various enzymes, mainly hydrolytic, which are released upon injury to the cell. Megakaryocyte - A giant cell of the bone marrow from which platelets are derived. Mononuclear - A cell having a single nucleus.

Heinz bodies are 1-3 um particles of denatured hemoglobin settling eccentrically, usually close to the red cell membrane. They are found in erythrocytes in unstable hemoglobin disorders, acute drug induced hemolysis, and following splenectomy. Their formation may be exaggerated by in-vitro incubation of a fresh blood sample with phenylhydrazine. Heinz bodies, as pictured here, are identified using a supra-vital stain, such as new methylene blue or cresyl violet. Bite cells, visible with Wright-Giemsa staining, are visual reminders that the spleen is functional and has pitted the aberrant chunk of hemoglobin from the circulating erythrocyte.

Two photographs of a peripheral blood smear are submitted for review . The smears are from a 9-month-old baby with a heart valve replacement. In the upper photograph is a nucleated RBC and platelets are decreased. Nucleated red cells and occasional giant platelets indicate an active marrow response. In the process of forcing blood cells through the heart valve, erythrocytes are damaged, schistocytes are formed, and platelets are destroyed leading to thrombocytopenia. In the lower field are schistocytes, acanthocytes, echinocytes (burr cells), spherocytes, and the absence of platelets. The presence of burr cells could represent an artifact of smear preparation, but with the history of valve replacement, the red cell changes are likely the result of red cell damage as the cells circulate through the new valve. This situation is described as Waring Blender Effect because of damage to blood cells passing through the new valve, looking as if they had suffered the onslaught of a blender. Target cells and mild hypochromia may reflect iron deficiency through the loss of iron from destruction of RBC's. Iron loss through red cell destruction may be reflected in some hypochromia.

The photograph represents peripheral blood smear findings in another patient with hereditary spherocytosis. The red cells vary in size (anisocytosis)with a mixture of microcytes (red cells with central pallor) and microspherocytes (red cells with central staining). Macrocytes are conspicuous, some staining light blue. They are immature erythrocytes (reticulocytes)released from the bone marrow early. The bone marrow, geared up for rapid cell release in response to severe hemolysis, expels young red blood cells into the circulation before completing their 24 hour maturation cycle. Hemolysis, jaundice, and gall stone formation disappear following splenectomy. Gallbladder and stone removal eliminate the right upper quadrant pain. A serious consideration, especially in children with hereditary spherocytosis, is hemolytic crisis. A viral infection may allow red blood cell destruction to continue unabated. Anemia of such sudden onset and severity may become catastrophic, with death as the outcome. Splenectomy removes this possibility.

Hemoblobin H disease follows deletions of 3 of the 4 alpha globulin chains. Beta chains, unable to bind with insufficient numbers of alpha chains, form beta chain tetramers, or HbH.These beta chain tetramers appear as numerous dot size inclusions in erythrocyte cytoplasm, best seen in supravital brilliant cresyl blue stains (lower photograph).The most common molecular defect in alpha thalassemia is DELETION, not MUTATION; whereas, in beta thalassemia, the molecular defect is MUTATION.Leptocytes, as illustrated in the upper photograph,(lepto, derived from a Greek word meaning thin, fine, or slight), are characteristic of HbH disease. They have thinner cell membranes than the cells we recognize as target cells. They stain more lightly than normal erythrocytes and their centers are almost colorless.Subtle changes perhaps, but worth keeping in mind

The patient whose blood smear is shown in the photograph was a 32-year-old female from Virginia who came to the high country of Colorado to ski. The day after arrival, she experienced shortness of breath, fatigue, and upper abdominal pain. She was seen in a medical center in the mountains where a working diagnosis of altitude sickness was made. A CBC revealed RBCs 5.1 x 1012/L, hemoglobin 12.8g/dL, MCV 60fL, hematocrit 40.9%, and normal total WBC, differential, and platelet count. The RDW was normal. Further questioning revealed a previous diagnosis of heterozygous beta-chain thalassemia. No other abnormal hemoglobins were found on hemoglobin electrophoresis, but HbA-2 was elevated to 5%, supporting the diagnosis of beta thalassemia. The patient's poikylocytosis and anisocytosis may be a clue to an underlying erythrocyte abnormality. Persons with iron deficiency anemia may experience various degrees of hypoxia upon arriving at high altitudes. Those with sickle cell disease and thalassemia minor (as in this case) may experience bone pain or other symptoms of "crisis" and/or alteration in the appearance of their erythrocytes upon sudden high altitude exposure. The classic teaching is that in differentiating iron deficiency anemia from thalassemia, increased RDW would favor iron deficiency; normal RDW favors thalassemia.

Illustrated in the photomicrograph of a peripheral smear are two populations of erythrocytes. Approximately 50% of the erythrocytes are normal size and contain a full complement of hemoglobin. The patient had received blood transfusions. The transfused red blood cells are the normocytic, normochromic red cells. Admixed are microcytic erythrocytes and larger erythrocytes, some faintly mottled or smudged, suggestive of reticulocytes. This picture represents a hemolytic process with a reticulocyte response. A similar dimorphic red cell population appears following erythropoietin therapy. It is important to recognize when a population of cells in the peripheral smear is not in context with anticipated laboratory findings and the clinical situation.

Ovalocytes are rod shaped erythrocytes with nearly parallel lateral walls. If the long axis of an erythrocyte is no more than twice as long as the short axis, the cell is an ovalocyte. If the long axis is more than twice as long as the short axis, the cell is an elliptocyte. Hemoglobin tends to collect at each end of these cells. The ends of the cells are rounded and never pointed, to be differentated from sickle cells. Ovalocytes present in greater than 25% of red cells on the blood smear are characteristic of hereditary ovalocytosis. The oval shape is attributed to a defect in horizontal red cell membrane protein interactions. Lesser numbers of circulating ovalocytes may be present in various anemias including megaloblastic, sideroblastic, iron deficiency, and in thalassemias. A rare ovalocyte (less than 1%) may be found on almost any peripheral blood smear. Resistance to malarial infection may be a beneficial attribute of hereditary ovalocytosis.

Many of the distorted erythrocytes displayed on the previous page are also present on this one. We see anisocytosis, poikilocytosis, fragmented forms, target cells, and a few Howell-Jolly bodies. Note also circulating nucleated red blood cells (normoblasts). The presence of these normoblasts may represent a premature release from a hyperplastic marrow or, more likely, are due to a lessening of the normal inhibition of erythroid release from the marrow as a result of splenectomy, permitting their earlier entry into the circulation.

The focus of these photographed fields is on the occasional large oval macrocyte,and the large, hypersegmented neutrophils representing either vitamin B-12 or folic acid deficiency, or both. The distinct hypochromia of many of the erythrocytes reflects low iron stores.

A 54 year-old man was brought to the clinic by his sister who was emphatic that her brother was "not taking care of himself."The patient had a previous gastrectomy and splenectomy. He also had a diagnosis of alcoholism, malnutrition, and hepatic cirrhosis. The following five pages discuss a variety of erythrocyte changes that have occurred as a result of his various conditions.

Red cell morphology can be defined as the appearance of the erythrocytes on a Wright's stained smear.Careful examination of the red cells for the purpose of identifying abnormalities is part of the differential procedure. This examination is important because it may provide valuable diagnostic information to the physician, as well as provide a quality control mechanism to verify red cell indices values as determined by automated or manual methods.Evaluating red cell morphology involves differentiating normal morphology from abnormal and artificial morphology. The abnormal morphology covered in this unit may be seen in a variety of disorders.

Normal red cells are seen in this field. Mature erythrocytes can be described as round, elastic, non-nucleated, bi-concave discs which appear buff colored on Wright's stained smears. Notice that many of the cells have an area of central pallor which covers about one-third of the cell. The pallor occurs as a result of the disc-shaped cells being spread on the slide. Normal mature red blood cells have an average diameter of 7.2 microns with a range of 6-9 microns. This is approximately the same size as the nucleus of a small lymphocyte, which is often used as a guideline when determining the size of the red cells on a slide. The average thickness of a normal mature red blood cell is 2.1 microns with a mean corpuscular volume (MCV) of 87 cubic mircons/femtoliters.

It is important to differentiate in vitro changes which are secondary to preparing the slide, from in vivo morphology, which is the result of the pathophysiological condition of the patient. Examining erythrocytes in the critical viewing area is extremely important in making this distinction. The determination of the clinical significance of the morphology reported is the responsibility of the physician, who must correlate the blood smear findings with the clinical diagnosis, and other laboratory parameters.

The term, stomatocyte, is derived from the Greek term, stoma, meaning mouth. Stomatocytes are cup-shaped erythrocytes which have an elongated or slit-like central pallor. The occasional stomatocyte seen in normal smears is the result of a slight pH change in the environment similar to the in vitro changes which cause cells to assume the echinocyte shape. A stomatocyte can be seen in the center of this slide.

Erythrocytes, when spread on a glass slide, show varying degrees of central pallor as noted in the previous exercise. This central pallor is related to the hemoglobin concentration present in the red cells.When viewing normal mature red cells, the central area (one-third of the cell) is white, while buff-colored hemoglobin is visible in the outer two-thirds of the cell. The mean corpuscular hemoglobin concentration (MCHC, 32-36 gm/dl of red blood cells), is the indice value which is used to verify the presence of adequate hemoglobin concentration in the cells visible on the peripheral smear.

Plasma cells are uncommonly observed in the peripheral blood smear.They are normal constituents of lymph nodes, spleen, connective tissue and bone marrow. The presence of plasma cells in the peripheral blood is indicative of a large number of conditions mostly related to infections , immune disorders, malignancies, toxic exposures, hypersensitivity reactions and their responses.Although mature plasma cells have a distinct appearance, they still may be confused morphologically with immature plasma cells and other cells with inclusions, reactive changes or nucleated red bloods cell with altered identities.In the upper and lower photographs are plasma cells with features mindful of myeloma cellsThe large myeloma cell in the upper photograph has an eccentric immature nucleus with a muddy chromatin pattern.Note also clumping and stacking of the erythrocytes, bordering on rouleaux formation ,implicating an increase in plasma gamma globulin.The plasma cell with the double nucleus in the lower photograph is particularly suggestive of myeloma.Further studies are in order including a bone marrow examination where at least 30% of bone marrow cells should be variations of mature and immature plasma cells.Serum electrophoresis will reveal a monoclonal globulin spike, and light chains in excess of 1.0 gm/24 hours may be seen in the urine.The presence of lytic bone lesions is a convincing clinical clue.With these findings in combination, a diagnosis of myeloma can be made with assurance.