Agglutination - LM 335 - PDF

Summary

These notes cover agglutination, a visible aggregation of particles caused by antigen-antibody reactions. The process is shown to be two steps, sensitization, and lattice formation. The notes also cover different types of agglutination reactions, such as direct and passive reactions; and various enhancement methods are also discussed. These notes provide a comprehensive understanding of agglutination reactions from their basic principles to clinical applications, and highlight several strategies for enhancing their efficiency.

Full Transcript

Section 2-Part 3

Agglutination
LM 335
Dr. Hassan Kofahi
Agglutination
Agglutination is a visible aggregation of particles caused by an antigen-
antibody reactions.
Agglutination occurs when one of the reactants (Antigen or antibody) is
particulate.
The antibodies that produce agglutination reactions are often called
agglutinins.
The antigen must be exposed on the surface of the particle and each
particle must have multiple epitopes.
Types of particles used in agglutination reactions include:
Erythrocytes (agglutination of RBCs is often called hemagglutination)
Bacterial cells
Inert carriers such as latex particles.
Agglutination is a two-step process:
1. Sensitization
2. Lattice formation
Sensitization
An initial reaction in which the Antigen binds to the antibody.
Each antibody molecule binds to a single epitope.
No cross-links yet. No visible aggregates yet.
This step is affected by the affinity of the antibody and the nature of the epitopes
hidden epitopes are less likely to bind to the antibody than exposed epitopes.
Lattice formation
At this step, Antibodies bridge the gaps between particles in such a
way that one antibody molecule binds to one epitope on each of two
different particles.
Affected by:
Ionic strength
pH
Temperature
Ab:Ag ratio
Zeta potential
Erythrocytes carry a slight negative charge on their surface.
In an ionic solution, red cells surround themselves with cations to form an
ionic cloud.
Because of these charges, cells repel one another which keeps them about
25 nm apart.
IgG antibodies often cannot bridge the distance between the cells, because
of their small size and restricted flexibility at the hinge region.
Visible reactions with IgG often require the use of enhancement
techniques.
IgM molecules has a diameter of 35 nm, which makes them better
agglutinins.
Enhancement of lattice formation
1. Reducing the surface charges of the RBCs:
Reducing the surface charges allow the RBCs to get closer to each other and
enhance the agglutination.
This can be achieved by:
Reducing the ionic strength of the buffer by using low ionic strength saline (LISS).
Addition of albumin (5%-30%) to the reaction. Albumin neutralizes the surface charges
on the RBCs.
Using enzymes
e.g. Bromelin, papain, trypsin, and ficin
Reduce the surface charges of the RBCs by cleaving chemical groups and decreasing
hydration.
e.g. Ficin cleaves sialoglycoproteins from the RBC surface.
Enhancement of lattice formation (continued)
2. Centrifugation: Increases cell-cell contact (physically).
4. Temperature:
IgM reacts best between 4°C and 27°C (cold-reacting).
IgG reacts best between 30°C and 37°C (warm-reacting).
6. pH: most of Ag-Ab reactions occur when the pH is 6.5-7.5.
7. The use of antihuman globulin reagent (will be discussed later).
Agglutination reactions: advantages
Easy to perform
Require no complicated equipment
Relatively inexpensive.
Quick
Can be performed as needed (no need to batch specimens).
Generally, qualitative. Can be semi-quantitative.
Types of agglutination reactions
1. Direct agglutination
2. Passive (indirect) agglutination
3. Reverse passive agglutination
4. Agglutination inhibition
Direct agglutination
Occurs when the antigens are found naturally on a particle.
e.g. ABO blood grouping: the antigens are found naturally on RBCs.
e.g. Widal test: the antigens are found naturally on a bacteria.
Can be used to test for antigens or antibodies
e.g. ABO blood grouping is done by using known antisera to test the types of
antigens present on the RBCs.
e.g. Widal test: known bacterial suspensions (different Salmonella serotypes)
are used to test the presence of antibodies in patients’ sera.
Direct agglutination

Antigens are present naturally Antibodies Visible agglutination
on a particle
Passive (indirect) agglutination
Used when the antigen is soluble.
The antigen is attached to an insoluble particle.
i.e. the particles become coated with an antigen not normally found on their surface.
Types of particles used for this purpose
RBCs
Latex particles
Gelatin
The particles are coated with a known antigen to detect antibodies.
e.g. Streptolysin O-coated latex particles are used to detect the presence of
antibodies in the serum against group A streptococci.
e.g. Viral antigen-coated RBCs are used to detect antibodies against Hepatitis B,
Hepatitis C and many other viruses.
Passive (indirect) agglutination
Reverse Passive Agglutination
In this technique, the particles are coated with the antibody instead
of the antigen.
The antibody is oriented in a way that retain its activity, with the
antigen-binding sites facing outward and ready to bind their antigens.
This test is used to detect antigens.
e.g. Grouping of streptococci by using suspensions of latex particles coated
with group-specific antibodies.
e.g. C-reactive protein (CRP) is detected and semi-quantified with latex
particles coated with anti-CRP antibodies.
e.g. The rapid slide test for detecting rotavirus in fecal sample using latex
particles coated with specific antibody that reacts with the rotavirus antigen.
Reverse Passive Agglutination
Agglutination inhibition
In this technique, soluble antigens (in the patient sample) compete with
particulate antigens (indicator particles) on binding the limited antibody-
combining sites.
The test is performed in two steps:
First, the patient sample is incubated with a limited amount of reagent antibody that
is specific against the antigen to be tested.
Then, indicator particles coated with the same antigen are added to the reaction.
Results:
Positive result: if the patient sample contains the antigen of interest, the free
antigens in the sample will bind to the antibodies, leaving no free antibody to react
with the indicator particle no agglutination.
Negative result: If the patient sample has no free antigens, the reagent antibody is
able to react with the indicator particles visible agglutination.
Agglutination inhibition Reagent
antibodies

This technique is used for
detecting drugs, such as heroin
and cocaine.
Hemagglutination inhibition
uses the same principle except
that the particles used are
RBCs.
Agglutination: interpretation of the results
Large number of agglutination kits are commercially available for the
detection of wide variety of antigens or antibodies.
Semiquantitative results can be obtained by performing a serial 2-fold
dilution of the sample. The titer can be determined as the reciprocal of the
highest dilution giving a positive result.
The agglutination reactions are performed in test tubes, microtiter plates
or on glass/cardboard slides.
Tubes and microtiter plates are usually used for Hemagglutination
reactions.
In the tube-method, the tubes are centrifuged and then shaken to see if
the cell pellet can be evenly resuspended.
Tube method: interpretation of the results
Microtiter plate method: interpretation of the
results.
Interpretation of the test is done on the
basis of the cell sedimentation pattern.
A dark red, smooth button at the bottom
of the microtiter well indicates a negative
result.
Positive
In a positive reaction the cells spread
across the well’s bottom.
Negative
Slide method: interpretation of results

Latex agglutination results
Hemagglutination results
Antihuman globulin-mediated agglutination
Is a technique for detecting the reactions of non-agglutinating
antibodies (IgG) by adding a second antibody.
Also known as coombs' test.
Used when the RBCs are sensitized with IgG, but no visible
agglutination occur.
The second antibody is an antihuman globulin antibody
Made in animals.
Recognize and bind to the Fc region of human IgG bound to the sensitized
RBCs.
The antihuman globulin antibody is able to bridge the gaps between
the sensitized RBCs and allow the lattice formation and agglutination.
Direct antihuman globulin (coombs’) test
Used to detect in vivo
sensitization of RBCs.
Used for diagnosing
some autoimmune
diseases.
e.g. Autoimmune
hemolytic anemia,
hemolytic disease of
the newborn.
Called direct because
the patient’s RBCs are
tested directly as they
come from the body
Indirect antihuman globulin (coombs’) test
Used to determine the
presence of a particular
antibody in a patient
sample.
Sensitization of RBCs
occurs in vitro.
You will learn more about
Coombs’ test in the blood
banking course.
Agglutination: quality control and quality
assurance
General guidelines:
Always run positive and negative controls parallel to patient sample.
If the results of the controls are not as expected, the test is invalid.
Follow the manufacturers' instructions carefully.
Store the reagents properly.
Do not use expired reagents.