Complete blood count

Complete Blood Count
Diagnostics

Schematics (also called "Fishbones") of shorthand for complete blood count commonly used by clinicians. The shorthand on the right is used more often in the US. Hgb=Hemoglobin, WBC=White blood cells, Plt=Platelets, Hct=Hematocrit.
MeSH D001772
MedlinePlus 003642
eMedicine 94020
Reference range Hgb: 120–175 g/L;
WBC: 3.5–11 × 109/L;
Plt: 140–450 × 109/L;
Hct: 31–53%
LOINC Codes for CBC, e.g., 57021-8
HCPCS-L2 G0306

A complete blood count (CBC), also known as a complete blood cell count, full blood count (FBC), or full blood exam (FBE), is a blood panel requested by a doctor or other medical professional that gives information about the cells in a patient's blood, such as the cell count for each cell type and the concentrations of various proteins and minerals. A scientist or lab technician performs the requested testing and provides the requesting medical professional with the results of the CBC.

Blood counts of various types have been used for clinical purposes since the 19th century. Automated equipment to carry out complete blood counts was developed in the 1950s and 1960s.[1]

The cells that circulate in the bloodstream are generally divided into three types: white blood cells (leukocytes), red blood cells (erythrocytes), and platelets (thrombocytes). Abnormally high or low counts may indicate the presence of many forms of disease, and hence blood counts are amongst the most commonly performed blood tests in medicine, as they can provide an overview of a patient's general health status. A CBC is routinely performed during annual physical examinations in some jurisdictions.

Medical uses

Complete blood counts are done to monitor overall health, to screen for some diseases, to confirm a diagnosis of some medical conditions, to monitor a medical condition, and to monitor changes in the body caused by medical treatments.[2]

For patients who need blood transfusion, a blood count may be used to get data which would help plan an amount of treatment.[3] In such cases, the person should have only one blood count for the day, and the transfusion of red blood cells or platelets should be planned based on that.[3] Multiple blood draws and counts throughout the day are an excessive use of phlebotomy and can lead to unnecessary additional transfusions, and the extra unnecessary treatment would be outside of medical guidelines.[3]

Procedure

CBC being performed in a hospital using an Abbott Cell-Dyn 1700 automatic analyzer.

A phlebotomist collects the sample through venipuncture, drawing the blood into a test tube containing an anticoagulant (EDTA, sometimes citrate) to stop it from clotting. The sample is then transported to a laboratory. Sometimes the sample is drawn off a finger prick using a Pasteur pipette for immediate processing by an automated counter.

In the past, counting the cells in a patient's blood was performed manually, by viewing a slide prepared with a sample of the patient's blood (a blood film, or peripheral smear) under a microscope. Presently, this process is generally automated by use of an automated analyzer, with only approximately 10–20% of samples now being examined manually.

Automated blood count

Complete blood count performed by an automated analyser. Differentials not seen here.

Most blood counts today include a CBC count and leukocyte differential count (LDC) (that is, not just the total WBC count but also the count of each WBC type, such as neutrophils, eosinophils, basophils, monocytes, and lymphocytes). More sophisticated modern analyzers can provide extended differential counts, which include hematopoietic progenitor cells, immature granulocytes, and erythroblasts.[4]

The blood is well mixed (though not shaken) and placed on a rack in the analyzer. This instrument has flow cells, photometers and apertures that analyze different elements in the blood. The cell counting component counts the numbers and types of different cells within the blood. The results are printed out or sent to a computer for review.

Blood counting machines aspirate a very small amount of the specimen through narrow tubing followed by an aperture and a laser flow cell. Laser eye sensors count the number of cells passing through the aperture, and can identify them; this is flow cytometry. The two main sensors used are light detectors and electrical impedance. The instrument measures the type of blood cell by analyzing data about the size and aspects of light as they pass through the cells (called front and side scatter). Other instruments measure different characteristics of the cells to categorize them.

Because an automated cell counter samples and counts so many cells, the results are very precise. However, certain abnormal cells in the blood may not be identified correctly, requiring manual review of the instrument's results and identification of any abnormal cells the instrument could not categorize.

In addition to counting, measuring and analyzing red blood cells, white blood cells and platelets, automated hematology analyzers also measure the amount of hemoglobin in the blood and within each red blood cell. This is done by adding a diluent that lyses the cells which is then pumped into a spectro-photometric measuring cuvette. The change in color of the lysate equates to the hemoglobin content of the blood. This information can be very helpful to a physician who, for example, is trying to identify the cause of a patient's anemia. If the red cells are smaller or larger than normal, or if there is a lot of variation in the size of the red cells, this data can help guide the direction of further testing and expedite the diagnostic process so patients can get the treatment they need quickly.

Manual blood count

Manual blood counts use a light microscope, usually with a specialized microscope slide, which is called a hemocytometer.
This shows the view through the microscope of the specialized hemocytometer slide. The built-in grid simplifies counting cells by helping the technician keep track of which cells have already been counted.

Hemocytometers (counting chambers that hold a specified volume of diluted blood and divide it with grid lines) are used to calculate the number of red and white cells per litre of blood. (The dilution and grid lines are needed because there are far too many cells without those aids.)

To identify the numbers of different white cells, a blood film is made, and a large number of white blood cells (at least 100) are counted. This gives the percentage of cells that are of each type. By multiplying the percentage with the total number of white blood cells, the absolute number of each type of white cell can be obtained.

Manual counting is useful in cases where automated analyzers cannot reliably count abnormal cells, such as those cells that are not present in normal patients and are only seen in peripheral blood with certain haematological conditions. Manual counting is subject to sampling error because so few cells are counted compared with automated analysis. A manual count will also give information about other cells that are not normally present in peripheral blood, but may be released in certain disease processes.

Medical technologists examine blood film via a microscope for some CBCs, not only to find abnormal white cells, but also because variation in the shape of red cells is an important diagnostic tool. Although automated analysers give fast, reliable results regarding the number, average size, and variation in size of red blood cells, they do not detect cells' shapes. Also, some normal patients' platelets will clump in EDTA anticoagulated blood, which causes automatic analyses to give a falsely low platelet count. The person viewing the slide in these cases will see clumps of platelets and can estimate if there are low, normal, or high numbers of platelets.

Included tests

A scanning electron microscope (SEM) image of normal circulating human blood. One can see red blood cells, several knobby white blood cells including lymphocytes, a monocyte, a neutrophil, and many small disc-shaped platelets.

A complete blood count will normally include:

White cells

Red cells

Hemoglobin

Hematocrit

MCV

MCH

MCHC

RDW


Platelets

Results

An example report format for a complete blood count. Note that test names, measurement units and reference ranges may vary between countries and laboratories. Patient results should always be interpreted using the units and reference ranges from the laboratory that produced the results.

Example of reference ranges for blood tests of white blood cells.[8]

Interpretation

Certain disease states are defined by an absolute increase or decrease in the number of a particular type of cell in the bloodstream. For example:

Type of Cell Increase Decrease
Red Blood Cells (RBC) erythrocytosis or polycythemia anemia or erythroblastopenia
White Blood Cells (WBC): leukocytosis leukopenia
lymphocytes lymphocytosis lymphocytopenia
granulocytes: granulocytosis granulocytopenia or agranulocytosis
– –neutrophils – –neutrophilia – –neutropenia
– –eosinophils – –eosinophilia – –eosinopenia
– –basophils – –basophilia – –basopenia
Platelets thrombocytosis thrombocytopenia
All cell lines pancytopenia

Many disease states are heralded by changes in the blood count:

References

  1. Verso, ML (May 1962). "The Evolution of Blood Counting Techniques" (PDF). Read at a meeting of the Section of the History of Medicine, First Australian Medical Congress 8: 149–58. doi:10.1017/s0025727300029392. PMC 1033366. PMID 14139094. Retrieved 9 September 2013.
  2. Mayo Clinic (14 February 2014). "Complete blood count (CBC) Why it's done - Tests and Procedures". mayoclinic.org. Retrieved 29 July 2014.
  3. 1 2 3 American Association of Blood Banks (24 April 2014), "Five Things Physicians and Patients Should Question", Choosing Wisely: an initiative of the ABIM Foundation (American Association of Blood Banks), retrieved 25 July 2014, which cites
    • Napolitano, LM; Kurek, S; Luchette, FA; Corwin, HL; Barie, PS; Tisherman, SA; Hebert, PC; Anderson, GL; Bard, MR; Bromberg, W; Chiu, WC; Cipolle, MD; Clancy, KD; Diebel, L; Hoff, WS; Hughes, KM; Munshi, I; Nayduch, D; Sandhu, R; Yelon, JA; American College of Critical Care Medicine of the Society of Critical Care, Medicine; Eastern Association for the Surgery of Trauma Practice Management, Workgroup (Dec 2009). "Clinical practice guideline: red blood cell transfusion in adult trauma and critical care.". Critical Care Medicine 37 (12): 3124–57. doi:10.1097/CCM.0b013e3181b39f1b. PMID 19773646.
  4. Buttarello, M; Plebani, M (Jul 2008). "Automated blood cell counts: state of the art.". American journal of clinical pathology 130 (1): 104–16. doi:10.1309/EK3C7CTDKNVPXVTN. PMID 18550479.
  5. 1 2 3 4 5 6 7 David C., Dugdale (19 March 2012). "CBC: MedlinePlus Medical Encyclopedia". MedlinePlus. United States National Library of Medicine. Retrieved 29 July 2014.
  6. 1 2 3 4 "Complete Blood count with Differential". RbCeus.com. 2013. Retrieved 2014-11-21.
  7. "RBC indices". MedlinePlus: U.S. National Library of Medicine. Retrieved 1 June 2013.
  8. References at Reference ranges for blood tests#White blood cells 2

External links

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