General Principles of Intellectual Property: Concepts of Intellectual Proper...
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Immunodiffusion principles and application
1. Immunodiffusion techniques
⢠APPLICATIONS
⢠To determine relative concentrations of Antibodies / Antigens.
⢠To compare Antigens or
⢠To determine the relative purity of an Antigen preparation.
⢠For disease diagnosis.
⢠Serological surveys.
The combination of antibody (Ab) with antigen(Ag) is the fundamental
reaction of immunology.
ď Primary binding tests
ď Secondary binding tests
ď Tertiary binding tests
2. Principle
⢠Soluble Ab & soluble Ag interacting in aqueous solution form
lattice that develops into insoluble visible precipitate.
⢠Soluble Ag: Toxins, toxoids, proteins, carbohydrates, glycoproteins,
Liproproteins
⢠Both qualitatively & quantitatively in solutions & gels.
⢠Formation of Ag-Ab lattice depends on the valency of both Ag &
Ab:
Ab must be bivalent Fab fragments
- Ag must be bivalent / polyvalent.
3. Precipitation
â˘Insoluble complexes
â˘Visible to the eyes
4. Precipitation Curve
⢠Zone of Equivalence
optimum precipitation
⢠Prozone
excess antibody is present
⢠Postzone
excess antigen is present
Prozone and Postzone
phenomena are negative
reactions.
5. Immunodiffusion
Precipitation Reactions
ďą Immunodiffusion
o Radial Immunodiffusion (Mancini method).
o Ouchterlony Double Diffusion
ďą Electrophoresis
o Rocket Immunoelectrophoresis
o Immunoelectrophoresis
⢠Precipitation is best demonstrated
⢠Random movement of Ag or Ab to form Ag-Ab complexes in medium, such as gel.
6. MEDIUM
ď Agar - high molecular weight complex polysaccharide
- from seaweed
ď Agarose- purified agar
- Used to help stabilize the diffusion process
and allow visualization of precipitin bands.
ď 0.3 â 1.5 % Agar concentration: diffusion of most reactants
ď Agarose- more preferred than agar
Agar has strong negative charge;
Agarose has almost none (no charge)
- interactions between gel and reactants are minimized.
7. Passive Immunodiffusion
⢠Passive diffusion method in which a concentration gradient is
established for an antigen and/or antibody
- diffusion of reactants to form Ag - Ab reactions without
electric current to speed up reaction.
Rate of Diffusion
1. Size of particles
2. Temperature
3. Gel viscosity
4. Amount of hydration
5. Interactions between matrix and reactants.
8. Immunodiffusion Techniques
⢠Radial Immunodiffusion
- A single diffusion technique where Ab is put into
gel and Ag is measured by the size of a precipitin
ring formed when it diffused out in all directions
from a well cut into the gel.
⢠Ouchterlony Double Diffusion
- Both Ab and Ag diffuse from wells into a gel
medium.
9. Radial Immunodiffusion
⢠Ag is added to an
antibody rich media.
⢠The two continue to
react until the zone of
equivalence is
reached.
⢠The area of ring is a
measure of the Ag
concentration.
10. ⢠Method
â Ab in gel
â Ag in a well
⢠Interpretation
â Diameter of ring is
proportional to the
concentration
⢠Quantitative
â Ig levels
13. Wells are cut in the gel
Reactants are added in the well
Incubate (12-48 hrs) in a moist chamber
Precipitin lines will form
(where the moving front of the antigen meets antibody)
14. The density of the line reflects the amount of immune complexes formed
16. ⢠Antibody that is multispecific
is placed in the central well
⢠Different antigens are placed
in surrounding wells
0.5% Amido-black
0.5% Coomassie
Brilliant Blue
**Position of the precipitin bands between wells allows for the antigens
to be compared with one another.
17. Diffusion patterns
ďŹ Fusion of lines at their
junction to form an arc
- Serologic identity /
presence of common epitope
ďŹ Crossed lines
- Demonstrates 2 separate
reactions
- Compared antigens shared no
common epitopes
ďŹ Fusion of 2 lines with spur
- Partial identity
18. IMMUNOELECTROPHORESIS
⢠Double-diffusion technique that utilizes electric current to enhance
results.
⢠SPEED, Specificity.
⢠Introduced by Grabar and Williams in 1953.
⢠Combine immunodiffusion with electrophoresis
⢠Can be used for semiquantitaion of wide range of antigens
⢠Qualitative
⢠Antigen source: serum.
19. Electrophoresis Techniques
⢠Electrophoresis separates molecules according to differences in
their electrical charge.
â Rocket Immunoelectrophoresis
â Countercurrent Immunoelectrophoresis
20. Principle
2 step process
Trough is cut in
Trough is cut in
the gel parallel
the gel parallel
Antigen from
Antigen from electrophoresed
electrophoresed to the line of
to the line of
serum
serum separation
separation
â˘â˘doublediffusion
double diffusion Antiserum is
Antiserum is
occurs at right
occurs at right
Incubate: 18-
Incubate: 18-
24 hours placed in the
placed in the
angles to the
angles to the 24 hours
trough
trough
electrophoresis
electrophoresis
separation
separation
â˘â˘Precipitinlines
Precipitin lines
develop where Ag-
develop where Ag- Lines or arcs shape, intensity and
Lines or arcs shape, intensity and
Ab combination
Ab combination location: compared with normal serum
location: compared with normal serum
takes place.
takes place. control
control
23. ⢠Method
â Ags are separated by electrophoresis
â Ab is placed in trough cut in the agar
⢠Interpretation
â Precipitin arc represent individual antigens
24. Uses
⢠Immunodeficiencies can be detected by this procedure, if no
precipitin band is formed for a particular Ig.
⢠Overproduction of serum proteins.
⢠Deficiencies in complement can also be detected.
⢠Identification of monoclonal protein
â Free kappa and lambda light chains
⢠May be used to identify urine proteins.
⢠Testing normal & abnormal proteins in serum/urine.
⢠Purity of Ag.
25. Countercurrent electrophoresis
Method
â Ag and Ab migrate toward each other by electrophoresis
â Used only when Ag and Ab have opposite charges
- +
Ag Ab
⢠Qualitative- Rapid.
⢠Detection of Antinuclear- Ribonuclear protein.
26. Rocket Immunoelectrophoresis
( LAURELL TECHNIQUE )
⢠One dimension electroimmunodiffusion
- Adaptation of RID
⢠Electrophoresis is used to facilitate migration of antigen in agar
- Ag diffuses out of the well: precipitation begins
- Change in Ag concentration: dissolution and reformation of
precipitate.
End result: precipitin line = conical-shaped, resembles a racket
⢠. The height of the racket is measured
- Height of the racket is directly proportional to the amount of
antigen present
⢠Racket electrophoresis is more rapid than RID.
28. Uses of Racket Immunoelectrophoresis
⢠Quantitate Igs
- (using a buffer = pH 8.6)
⢠Assay of proteins
- When concentration is too
low to be detected by
nephelometry and too high
for RID
- Ex: alpha-fetoprotein, Igs
in urine and spinal fluid,
Complement components
in body fluid.
29. Applications
⢠Screening tool for differentiation of more than 30 serum proteins.
- Major classes of immunoglobulins
⢠Used for the detection of:
- Myelomas
- Malignant lypmhomas
- Other lymphoproliferative disorder.
Hinweis der Redaktion
Performed in an agarose gel supported by a glass slide or polyester film
Area of ring: measure of Ag concentration: compared to a standard curve using Ags of known concentration
Why would we want to combine immunodiffusion with electrophoresis? SPEED, Specificity Two step process
Modification of IEP technique - Antigen ( proteins ) undergo electrophoresis in a supporting agarose gel with specific antibody previously mixed into the gel. As antigen moves thru the gel , antigen-antibody complexes form creating visible precipitation lines in the shape of long arches or ârocketsâ. The length of these ârocketsâ is proportional to the concentration of antigen.