Sucrose Hemolysis 

Sucrose Hemolysis 

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The reference range of hemolysis on sucrose hemolysis testing (screening and confirmatory tests) is listed below. ^[1]

See the list below:

No hemolysis visible – Negative result

Hemolysis present – Positive result

Hemolysis findings in supernate are as follows:

< 5% – Inconsequential or negative

6-10% – Questionable or borderline

>10% – Positive

The reference range does not vary with age, gender, race, or ethnicity. Note that the percentage of hemolysis on sucrose hemolysis test can vary based on the temperature at which the test is performed, the type of blood used (defibrinated or whole blood), and recent multiple blood transfusions that can dilute the percentage of paroxysmal nocturnal hemoglobinuria (PNH) cells. Therefore, the test must be run at an appropriate temperature, with appropriated blood type and an adequate history of recent blood transfusions to avoid false positives and negative results, respectively. ^[1]

See the list below:

Positive result – Hemolysis present, need to run further confirmatory test

Negative result – No hemolysis

See the list below:

< 5% hemolysis – Inconsequential or negative

6-10% hemolysis – Borderline or questionable; found in some leukemia, aplastic anemia, autoimmune hemolytic anemia, megaloblastic anemia, and myelofibrosis

>10% hemolysis – Positive, diagnostic for paroxysmal nocturnal hemoglobinuria (results should be correlated with acid lysis/Ham test or flow cytometry); also found in congenital dyserythropoietic anemia type II.

All results are subjected to vary with temperature changes, level of complement in serum, type of blood used, and recent multiple blood transfusions.

Washed red blood cells are incubated in an isotonic sucrose solution containing normal ABO compatible serum. At low ionic concentrations, RBCs absorb complement components from serum. Because PNH RBCs are much more sensitive than normal red cells, they hemolyze under these conditions. Normal RBCs do not. At the end of the incubation period, the mixture is examined for hemolysis.

See the list below:

False positive results – Aplastic anemia, autoimmune hemolytic anemia, megaloblastic anemia, heparin use, ethylenediaminetetraacetic acid (EDTA) use, higher temperature of incubation, use of defibrinated blood

False negative – Low complement levels, recent blood transfusions

To minimize variables, the following should be noted:

Temperature: 23 º C is an appropriate temperature because non-PNH blood cells are more stable at this temperature. More hemolysis is seen if the cells are incubated at 37 ºC in non-PNH cells, whereas negligible change in percentage of hemolysis is appreciated in PNH cells.

Hematocrit: With dilution of the blood, a higher percentage of hemolysis is seen, with negligible effect on the visible hemolysis.

Type of blood: Defibrinated blood should not be used because false positive results can occur in non-PNH blood disorders.

Complement levels: Low levels in the serum can be interpreted as a false negative.

Calcium and magnesium levels: These ions are used in complement-mediated hemolysis; thus, restoring the ions in blood helps decrease the chance of false negative results.

Blood transfusion: This can dilute the percentage of PNH cells, resulting in a false negative.

Percent of PNH cells: As the number of PNH cells varies from 10-80%, the percent of hemolysis also varies with the number of cells available in the blood.

See the list below:

Pretest preparation – No preparations before the test; heparin, EDTA, defibrinated blood, blood without anticoagulant are avoided

Specimen – Blood (whole blood, citrated)

Ideal amount – 2.7 mL whole blood, 5 mL of blue top

Minimum required blood – 2.4 mL of whole blood

Container – Blue top, keep at room temperature, 23ºC

Method – 1 part citrated whole blood, 9 parts of sugar water/sucrose solution incubated for 30 minutes; centrifuge and observe supernate for hemolysis

See the list below:

Pretest preparation – No preparations before the test; heparin, EDTA, defibrinated blood, blood without anticoagulant are avoided

Specimen – Blood (whole blood, citrated)

Ideal amount – 2.7 mL whole blood, 5 mL of blue top

Minimum required blood – 2.4 mL of whole blood

Container – Blue top, keep at room temperature, 23 º C

Method

To 1 mL of patient blood, add normal saline (sodium chloride 0.85%). Mix and centrifuge at high speed for 5 minutes.

From supernatant, prepare washed cell 50% solution.

Add 3 drops of cells from washed cell tube and 3 drops of normal saline.

Add reagent and incubate as shown below.

Transfer mixtures to a cuvet and record optical density (OD) at wavelength 540 nm and calculate the percentage of hemolysis using the following formula: % Hemolysis = OD test/OD total X 100

The incubation information using Drabkin reagent is as follows: ^[2]

After complete 30 minutes incubation, remix blood-serum tube (250 mcL, mix incubation 10 min).

After complete 30 minutes incubation, remix blank tube (250 mcL, mix incubation 10 min).

After complete 5 minutes, centrifuge of remaining blood-sucrose tube from the supernatant (250 mcL, mix incubation 10 min).

Paroxysmal nocturnal hemoglobinuria is a rare clonal hematopoietic stem-cell disorder (approximately 1-2 cases per 1 million people in the US) with protean clinical manifestations. ^[3] The disease manifests with complement-mediated intravascular hemolysis, smooth muscle dystonia, and thrombosis.

Virtually all clinical manifestations of PNH result from the absence of a class of cell membrane proteins known as glycophosphatidylinositol (GPI)-anchored proteins. At least 2 of these GPI-anchored proteins (CD55 and CD59) normally function as complement regulatory proteins; their absence from PNH erythrocytes explains the complement-mediated hemolysis that is characteristic of PNH. PNH erythrocytes are vulnerable to complement activation through any of these pathways; however, the alternative pathway is in a state of continuous activation, which explains why hemolysis can occur at any time in patients with PNH.

Historically, in order to diagnose PNH, the first test done is the sugar water test/sucrose hemolysis test. In this test, the RBCs are exposed to low isotonic solution. Erythrocytes of PNH, adsorb complement on their surfaces when exposed to such solution in the presence of serum in the reaction mixture. and that results in hemolysis of the erythrocytes. The visible hemolysis(no OD measured, sugar water test) or the percentage of hemolysis (OD measurement, sucrose hemolysis test) defines the results of the test.

In order to decrease the manual error, the sugar water test (which was earlier used as screening test) is not done. Currently, the sucrose hemolysis test is used as the screening test. The results are then confirmed with the Ham test or flow cytometry.

Nocturnal hemoglobinuria, jaundice, and anemia indicate PNH as the most likely diagnosis.

The tests are also used for the following:

Classical PNH, PNH with aplastic anemia or myelodysplastic syndrome, subclinical PNH in patients with aplastic anemia

Hemolytic anemia of obscure origin

Congenital dyserythropoietic anemia type 2

Sucrose hemolysis testing is sensitive but is less specific for PNH because some RBCs hemolyze from autoimmune hemolytic anemias, leukemia, and aplastic anemia to a minor degree.

The sucrose lysis test has been the standard screening test for PNH. More than 5% hemolysis is considered positive for PNH. The sucrose hemolysis test can also be used to determine complement lysis sensitivity.

In a retrospective study of laboratory tests for PNH, the RBCs of several patients gave conflicting results when different testing procedures were used. Reports in the literature described an association of PNH with various lymphoproliferative and myeloproliferative disorders; testing procedures for PNH should be more carefully controlled for a better understanding of the nature of the membrane defect. Certain standards should be maintained, such as incubation at room temperature (23ºC) and the use of freshly prepared sugar solutions, oxalated or citrated blood, human serum, adequate calcium, magnesium, and complement levels in human serum.

For many years, the Ham test has been the standard way to identify the PNH clone among RBCs. ^[4] Only one other disease is associated with a positive Ham test result: hereditary erythroid multinuclearity with positive acidified serum (HEMPAS) or congenital dyserythropoietic anemia (CDA) type 2, which can be readily differentiated from PNH by the medical history, bone marrow aspirate morphology, and a negative sucrose hemolysis test result. Hence, the Ham test is highly specific for PNH.

Although these tests are inexpensive and simple to perform, they are more labor intensive and less sensitive due to the short half-life of circulating PNH RBCs and the other variables that affects percentage of hemolysis.

Flow cytometry (FCM) has replaced the Ham test as the definitive test for PNH. Usually, CD55 and CD59 are both measured by FCM; depressed levels of both of these glycoproteins are consistent with PNH. FCM identification of small PNH clones (< 5%) shows greater sensitivity than the Ham test. ^{[5, 3]}

Hartmann RC, Jenkins DE Jr, Arnold AB. Diagnostic specificity of sucrose hemolysis test for paroxysmal nocturnal hemoglobinuria. Blood. 1970 Apr. 35(4):462-75. [Medline].

Sucrose Hemolysis Test Presentation. Available at http://site.iugaza.edu.ps/wael/files/SUCROSE-HEMOLYSIS-TEST.ppt. Accessed: 2012.

Besa E. Paroxysmal Nocturnal Hemoglovinuria; PNH Workup. Medscape. Available at http://emedicine.medscape.com/article/207468-overview. Accessed: 2011.

Van Leeuwen A. Davis Comprehensive Laboratory and Diagnostic Handbook. 4th Ed. Unbound Medicine; 2009. [Full Text].

ARUP Laboratory Test References. Available at http://www.aruplab.com.

Daniels R. Delmar’s Guide to laboratory and Diagnostic Tests. Delmar Cengage Learning; 2009.

Shivani Garg, MD, MBBS Fellow, Department of Rheumatology, Emory University School of Medicine

Shivani Garg, MD, MBBS is a member of the following medical societies: American College of Physicians, American College of Rheumatology

Disclosure: Nothing to disclose.

Anthony P Scarpaci, MD Attending Physician, Medical Oncology/Hematology Associates, Albert Einstein Health Network

Disclosure: Nothing to disclose.

Eric B Staros, MD Associate Professor of Pathology, St Louis University School of Medicine; Director of Clinical Laboratories, Director of Cytopathology, Department of Pathology, St Louis University Hospital

Eric B Staros, MD is a member of the following medical societies: American Medical Association, American Society for Clinical Pathology, College of American Pathologists, Association for Molecular Pathology

Disclosure: Nothing to disclose.

Sucrose Hemolysis 

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