White blood cell Information and Courses from MediaLab, Inc.

In an undiluted specimen, count and differentiate red cells and white cells at the same time. You can count red cells on a hand counter and use the differential counter for white cells. If you cannot differentiate white cells from red cells in the undiluted specimen, a plain capillary tube may be filled with crystal violet acetic acid diluent which is subsequently expelled from the tube. A very thin coating of the diluent will remain on the inside of the tube. CSF is drawn halfway up into the tube, which is then rocked back and forth to mix. The hemacytometer is then filled with the fluid containing stained white blood cells and lysed red cells. If cells are numerous and overlapping and it is necessary to focus through several planes in order to see all of the cells, a dilution must be made. When macroscopic appearance is turbid, milky or bloody, a significant dilution is usually necessary.

If leukocyte esterase is detected, a color change occurs on the reagent pad after the strip is dipped in the urine sample. Be sure to follow the manufacturer's directions for read-time and test interpretation. A positive leukocyte esterase test indicates the presence of granulocytic white blood cells. Lymphocytes do not contain granules, and would not produce a positive leukocyte esterase test. Positive results should be confirmed by performing a microscopic examination on the sediment; being aware that white blood cells may be absent if they are lysed, yet releasing their esterases into the specimen. Positive results may occasionally be found in random specimens from females due to contamination of the specimen by vaginal discharge.

The second group of cells are the leukocytes or white blood cells (WBC's). The leukocytes can be divided into two groups: granulocytes and mononuclear cells. Leukocytes are involved in various ways with the body's defense mechanisms. The cell shown by the red arrow is a mononuclear cell, in this case a monocyte. The cell shown by the blue arrow is a granulocyte, in this case a neutrophil. These cells will be presented in much more detail later.

Neutrophils have a relatively short life span.They are produced in the bone marrow, and when they reach the band or segmented stages are released into the peripheral blood.They remain there for approximately ten hours before randomly entering body tissues.Neutrophils in the blood stream can be divided into circulating granulocyte pool(CGP) and marginating granulocytic pool (MGP).The white blood cell count reflects the cells in the circulating pool.The cells in the marginating pool move quickly into the circulating pool when needed.During an infection the neutrophil concentration of the peripheral blood can increase almost immediately due to the shift of these cells from the marginating pool and release from the bone marrow storage pool, if needed.Neutrophils then migrate to areas of tissue damage or infection.Neutrophils do not reenter the blood stream from the tissues, thus end their life in the tissues either as a result of phagocytosis or senescence.

HIV is caused by the Human Immunodeficiency virus.When HIV enters a person's bloodstream, it attacks and kills the T-helper cells. These cells are part of a group of white blood cells known as lymphocytes, which are essential to the body in fighting off infections.As these cells are lost, so is the body's ability to fight infection.

Also known as Complete Blood Count (CBC) and is run on whole blood.Blood is tested for quantity and quality of different blood cell types, including: White Blood Cells (WBC Count) Red Blood Cells (RBC Count) Platelets (Platelet Count) Blood is also tested for hemoglobin & hematocrit (H&H).

When a blood sample is left standing without anticoagulant, it forms a coagulum or blood clot. The clot contains coagulation proteins, platelets, and entrapped red and white blood cells.

White blood cells also stain gram negative and usually have a segmented nucleus. Their average diameter is about 12 microns.

View control smears under oil immersion. If the control smears stained correctly, read the remainder of the smears.Look at the direct smear macroscopically to locate the stained area.Examine the direct smear under oil immersion and find an area that is properly decolorized.Examine at least ten fields in an area that is properly decolorized.Identify the following nonbacterial cell types: epithelial cells, white blood cells, red blood cells, yeast and hyphae.Look for microorganisms and record their characteristics.Quantitate each type of element found and record on the work card.Interpret the direct smear result.Report the direct smear finding.

The Gram stain reaction, shape, and arrangement of bacteria, and the presence or absence of intracellular organisms must be noted on the worksheet.Examples:Gram positive cocci in chains are present.Gram negative diplococci, intracellular, are present within white blood cells.Quantitate by approximating the average number of each cell type seen in 10 oil immersion fields, and record as:Many = More than 15/fieldModerate = 4-15/fieldFew = 1-3/fieldOccasional = 2-10/10 fieldsRare = 0-2/10 fields

Gram negative cocci which occur in pairs with their adjacent sides flattened, giving them a coffee bean appearance, are typical of the genus Neisseria. Neisseria gonorrhea is commonly found within white blood cells; these organisms must be carefully sought within genital tract specimens, and their presence or absence should be specifically noted in the report.The presence of intracellular gram negative bacilli in a purulent male urethral smear is presumptive evidence of gonococci, but this assumption cannot be made in a female. Beware of other organisms which resemble gonococci but are found extracellularly, such as Acinetobacter lwoffi, which must be distinguished biochemically.

Round cells in semen are of two types: immature sperm and white blood cells. To determine the percentage of white blood cells (specifically granulocytes) a special leukocyte screening test must be done. This test involves staining for the peroxidase enzyme present in the granulocytes.The 1999 WHO manual contains a protocol for doing this test (Appendix III). There is also at least one test kit on the market for this assessment (Leukoscreen: Bioscreen, Inc.).Laboratories with particular expertise in doing CBC and assessing granulocytes in stained blood smears may be able to do a differential count by this method rather than using a biochemical test for leukocyte screening.

Cellular casts consists of a Tamm-Horsfall mucoprotein matrix containing red or white blood cells, renal tubular epithelial cells, or a mixture of these cell types. All cellular casts originate from the distal tubules. The presence of cellular casts is always abnormal.

Urine sediment may also contain white blood cells (WBCs). Most of the WBCs in urine are segmented neutrophils. Since it is possible that lymphocytes, monocytes, and/or eosinophils may be present, the cells in urine can be stained if it is necessary to differentiate them. The segmented neutrophil just above center of the image to the right shows a distinct nucleus. When viewing urinary sediment under the microscope, the fine focus adjustment must be used to identify white blood cells. White blood cells swell in dilute alkaline urine and the cytoplasmic granules exhibit brownian movement resulting in “glitter cells.” These cells lyse rapidly. “Glitter cells” are most easily seen when viewed under phase-contrast microscopy.

Under phase contrast and high power magnification, white blood cells look much darker and the nuclear detail is quite distinct.

In this field there is a combination of white blood cells and cuboidal epithelium. Enumeration is difficult because of the similarity of the cells.

Under phase contrast, Trichomonas organisms appear much darker than the surrounding white blood cells.

The following pages in this presentation includes a series of white blood cell abnormalities that may be identified in a peripheral blood smear. Many of the cases will simulate the practice of a peripheral smear review by a hematology morphologist. He/she must asses what responses in patient care may be triggered by the clinician attempting to interpret the reported findings on a peripheral smearObservations of white blood cell abnormalities in the peripheral blood smear should be reported so as to direct the physician to an immediate specific diagnosis, such as: (1) atypical lymphocytes suggesting infectious mononucleosis rather than leukemia, (2) toxic granules in neutrophils as in acute infections, or atypical granules suggesting a genetic disorder, (3) an unusual mix of cells, such as too many or too few neutrophils, monocytes, or other myeloid cells, and (4) the presence of giant platelets, myelocytes, or other cells suggesting a myelodysplastic syndrome.In summary, laboratory data should be presented to clinicians in a user friendly way to promote effective decision making. The design of the data base of information must be directed toward providing clinically helpful information clearly and quickly in order to facilitate appropriate action in terms of optimizing patient care outcomes.d

The term leukemoid reaction is used to describe peripheral white blood cells that on the stained blood smear may have some resemblances to leukemia cells. Quantatively in a leukemoid reaction, the neutrophil count is >50,000 cumm with more immature cells, particularly myelocytes, than are usually present in toxic left shift syndromes. The presence of immature cells in a leukemoid reaction awakens thoughts of leukemia. Great care must be taken to make a distinct differentiation between aberrant white blood cell proliferations and a benign but exaggerated granulocytic proliferative response. Our material is from a 1-month-old girl with Down's syndrome. Her total white blood count was 37,000/mm3 interpreted as leukocytosis with left shift. Leukocytosis with a left shift, and leukemoid reactions with high alkaline phosphatase are conditions to be mindful of in patients with Down's syndrome. The alkaline phosphatase score is high in leukemoid reactions, low in granulocytic leukemia.

Illustrated in the upper and lower photographs are two-lobed, eye glass ("pince nez") nuclei of neutrophils typical for patients with Pelger-Huet anomaly. In addition to the characteristic two lobes connected by a delicate bridge, the dense, homogeneous nuclear chromatin helps to define Pelger-Huet anomaly. Since the peripheral blood smear did not support the diagnosis of appendicitis in this patient, and since abdominal pain localized to the right lower quadrant never developed, the boy was hydrated with intravenous fluid and observed. After hydration, his constitutional symptoms improved and the abdominal pain subsided. In fact, the lad was back on the ski slopes the next afternoon. People entering high altitude where the humidity may be very low are susceptible to dehydration and may experience symptoms related to mountain sickness. Therefore, close observation and hydration may be the best practice in monitoring patients with stories and findings similar to this one. A further lesson here is that technologists must be alert to the possibility of Pelger-Huet anomaly if a high white blood cell count with a high percentage of band neutrophils with strikingly uniform morphology and without toxic granulation are found. Inappropriate therapy or an invasive procedure as was contemplated here may be avoided by a proper smear assessment and clinical corroboration.