Complete blood count

Schematics (also sometimes called "Fishbones") of shorthand for complete blood count commonly used by physicians. The shorthand on the right is used more often in the US. Hgb=Hemoglobin, WBC=White blood cells, Plt=Platelets, Hct=Hematocrit.

A complete blood count (CBC), also known as full blood count (FBC) or full blood exam (FBE) or blood panel, is a test requested by a doctor or other medical professional that gives information about the cells in a patient's blood. A lab technician (diploma holder) or technologist (bachelor holder) performs the requested testing and provides the requesting Medical Professional with the results of the CBC. A CBC is also known as a "hemogram".

Alexander Vostek is widely regarded as being the first person to use the complete blood count for clinical purposes. Reference ranges used today stem from his clinical trials in the early 1960s. These experiments largely utilised domesticated greyhounds because of their easy bleedability and trusting temperaments.

The cells that circulate in the bloodstream are generally divided into three types: white blood cells (leukocytes), red blood cells (erythrocytes), and platelets or 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.

Contents

Methods

Samples

A phlebotomist collects the specimen, in this case blood is drawn in a test tube containing an anticoagulant (EDTA, sometimes citrate) to stop it from clotting, and transported to a laboratory.

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 under a microscope (a blood film, or peripheral smear). Nowadays, this process is generally automated by use of an automated analyzer, with only specific samples being examined manually.

Automated blood count

The blood is well mixed (though not shaken) and placed on a rack in the analyzer. This instrument has many different components to 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. Within this tubing, there are sensors that count the number of cells going through it, and can identify the type of cell; this is flow cytometry. The two main sensors used are light detectors, and electrical impedance. One way the instrument can tell what type of blood cell is present is by size. 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 be identified incorrectly, and require manual review of the instrument's results and identify 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 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's 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.

Automated blood counting machines include the Beckman Coulter LH series, Sysmex XE-2100, Siemens ADVIA 120 & 2120, the Abbott Cell-Dyn series,and the Mindray BC series.

Manual blood count

Counting chambers that hold a specified volume of diluted blood (as there are far too many cells if it is not diluted) are used to calculate the number of red and white cells per litre of blood.

To identify the numbers of different white cells, a blood film is made, and a large number of white 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.

The advantage of manual counting is that blood cells that may be misidentified by an automated counter can be identified visually. It is, however, subject to human error and sampling error because so few cells are counted compared with automated analysis.

Results

For examples of standard values, see Reference ranges for blood tests#Hematology.

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:

Red cells

White cells

A complete blood count with differential will also include:

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.

Platelets

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

Serology: blood tests
Metabolic panel/
plasma osmolality
BMP: electrolytes (Na+/K+, Cl-/HCO3-) • renal function, BUN-to-creatinine ratio (BUN/Creatinine) • Glucose • Ca
CMP: BMP + protein tests (Human serum albumin, Serum total protein) • liver function tests (ALP, ALT, AST, Bilirubin)
Iron
Total iron-binding capacity • Serum iron • Transferrin saturation
Acid-base homeostasis
Arterial blood gas/Arterial blood gas sampling • Base excess • Anion gap • CO2 content
Clotting
vWF: Ristocetin induced platelet agglutination

clotting factors: Prothrombin time • Partial thromboplastin time

other/general coagulation: Bleeding time • Thrombin clotting time  • Ecarin clotting time • Dilute Russell's viper venom time • Thromboelastography

fibrinolysis: Euglobulin lysis time • D-dimer
Blood sugar
Glucose test • Glucose tolerance test • Glycemia • Noninvasive glucose • C-peptide • Fructosamine • Random glucose test • Glycosylated hemoglobin
Endocrine
ACTH stimulation test • Thyroid function tests
CBC/Red blood cell indices
Mean corpuscular hemoglobin • Mean corpuscular hemoglobin concentration • Mean corpuscular volume • Hematocrit
Infections
viral: HIV (HIV test, BDNA test)

bacterial: syphilis (VDRL, Rapid plasma reagin, Wassermann test, FTA-ABS) • rickettsia (Weil-Felix test) • helicobacter (HelicoCARE direct) • streptococcus (Antistreptolysin O titre)

other: toxoplasmosis (Sabin-Feldman dye test)
Inflammation
C-reactive protein • Erythrocyte sedimentation rate
Fetal hemoglobin
Apt-Downey test • Kleihauer-Betke test
Other
Beutler test • Blood film • Invasive blood pressure • MELISA • RAST test • Cardiac marker (Glycogen phosphorylase isoenzyme BB) • Blood lipids • Tumor marker
see also reference ranges for blood tests