Difference between revisions of "Radioimmunoassay"
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==Introduction== | ==Introduction== | ||
| − | The radioimmunoassay (RIA) is a sensitive technique used to detect the presence of antigen in a sample using radiolabelled antibodies. Developed in the 1960's, the RIA proved a powerful tool in antigen detection, although the procedure was soon overtaken by ELISA, which | + | The radioimmunoassay (RIA) is a sensitive technique used to detect the presence of antigen in a sample using radiolabelled antibodies. Developed in the 1960's, the RIA proved a powerful tool in antigen detection, although the procedure was soon overtaken by ELISA, which utilises enzymes rather than radioactive labels. RIAs are still used today however, to measure: |
*Hormone levels in blood and tissue fluids | *Hormone levels in blood and tissue fluids | ||
*Serum proteins | *Serum proteins | ||
| Line 17: | Line 8: | ||
==Principle== | ==Principle== | ||
| − | *The general priniciple behind the RIA is the competitive binding of a | + | *The general priniciple behind the RIA is the competitive binding of a radiolabeled antigen and unlabeled antigen to a high-affinity antibody. |
| − | * | + | *Labeled antigen is mixed with antibody until binding sites are saturated |
| − | *Samples of | + | *Samples of unlabeled antigen (unknown concentration) are added in progressively increasing amounts |
**The two different antigens compete for the binding sites on the antibody | **The two different antigens compete for the binding sites on the antibody | ||
| − | **As the concentration of | + | **As the concentration of unlabeled antibody increases, more labeled antigen will be displaced |
| − | *The decrease in bound- | + | *The decrease in bound-radiolabeled antigen is measured - an indication of the amount of antigen present in sample |
==Technique== | ==Technique== | ||
| − | *The antigen is often | + | *The antigen is often labeled with a gamma-emitting isotope, e.g. iodine-125 |
| − | **Beta- | + | **Beta-emitting isotopes such as tritium are also often used |
| − | # Determine the amount of antibody required to bind ~50% of | + | # Determine the amount of antibody required to bind ~50% of radiolabeled antigen in mixture- ''required to ensure the number of epitopes presented by labeled antigen exceeds number of antibody binding sites'' |
| − | # Add | + | # Add unlabeled antigen to mixture |
# Separate antigen-antibody complex from free antigen by precipitation | # Separate antigen-antibody complex from free antigen by precipitation | ||
# Measure radioactivity in precipitate | # Measure radioactivity in precipitate | ||
*There are various methods to separate the antigen-antibody complexes from the free antigen: | *There are various methods to separate the antigen-antibody complexes from the free antigen: | ||
| − | **Precipitate complexes using secondary isotype-specific | + | **Precipitate complexes using secondary isotype-specific anti-immunoglobulin |
| − | **If complex contains IgG, it can be removed by mixing with formalin-killed ''Staphylococcus aureus''- protein A of ''S. aureus'' has a high affinity for IgG | + | **If complex contains [[IgG]], it can be removed by mixing with formalin-killed ''Staphylococcus aureus''- protein A of ''S. aureus'' has a high affinity for [[IgG]] |
| − | *** Removal of the complex by either of these methods leaves an amount of free | + | *** Removal of the complex by either of these methods leaves an amount of free labeled antigen in the supernatant (liquid section from precipitation)- the radioactivity of this can be measured and the value taken away from the total amount of labeled antigen added (known amount)= amount of bound labeled antigen |
**A number of solid-phase RIAs have been developed | **A number of solid-phase RIAs have been developed | ||
| − | ***Sometimes the antibody can be absorbed onto the surface- the amount of | + | ***Sometimes the antibody can be absorbed onto the surface- the amount of radiolabeled antigen bound to the beads can be measured after washing |
***Antibody can be immobilised on PVC or polystyrene | ***Antibody can be immobilised on PVC or polystyrene | ||
| + | |||
==Applications== | ==Applications== | ||
*As the technique requires small amounts of sample it can be conducted on 96-well microtiter plates and large numbers of samples can be tested | *As the technique requires small amounts of sample it can be conducted on 96-well microtiter plates and large numbers of samples can be tested | ||
| − | **RIA used in this way has been employed in the detection of the hepatitis B surface antigen in donor blood, reducing the occurrence of hepatitis infections as a result of blood transfusions | + | **RIA used in this way has been employed in the detection of the hepatitis B surface antigen in donor blood, reducing the occurrence of hepatitis infections as a result of blood transfusions in humans |
*Measuring plasma levels of hormones and controlled substances | *Measuring plasma levels of hormones and controlled substances | ||
| − | *Measuring anti-DNA antibodies present in systemic lupus erythematosus (SLE) | + | *Measuring anti-DNA antibodies present in [[SLE|systemic lupus erythematosus (SLE)]] |
| − | =Drawbacks= | + | ==Drawbacks== |
Although the RIA is a very sensitive test, and therefore widely-used, there are disadvantages to its use: | Although the RIA is a very sensitive test, and therefore widely-used, there are disadvantages to its use: | ||
| − | *The | + | *The substances being used are radioactive |
*Gamma radiation needs special counting equipment for detection | *Gamma radiation needs special counting equipment for detection | ||
*Iodine is naturally concentrated in the thyroid gland, whether radioactive or not, and incorporated into thyroxine | *Iodine is naturally concentrated in the thyroid gland, whether radioactive or not, and incorporated into thyroxine | ||
Consequently, ELISA has largely overtaken RIA as a preferred diagnostic tool | Consequently, ELISA has largely overtaken RIA as a preferred diagnostic tool | ||
| + | |||
| + | |||
| + | {{review}} | ||
| + | <br><br> | ||
| + | {{Jim Bee 2007}} | ||
| + | [[Category:Immunological Testing]] | ||
Latest revision as of 16:53, 17 March 2012
Introduction
The radioimmunoassay (RIA) is a sensitive technique used to detect the presence of antigen in a sample using radiolabelled antibodies. Developed in the 1960's, the RIA proved a powerful tool in antigen detection, although the procedure was soon overtaken by ELISA, which utilises enzymes rather than radioactive labels. RIAs are still used today however, to measure:
- Hormone levels in blood and tissue fluids
- Serum proteins
- Drugs
- Vitamins
- Levels can be detected when as low as 0.001 micrograms per millilitre, therefore this technique can be use to detect trace amounts of drug
Principle
- The general priniciple behind the RIA is the competitive binding of a radiolabeled antigen and unlabeled antigen to a high-affinity antibody.
- Labeled antigen is mixed with antibody until binding sites are saturated
- Samples of unlabeled antigen (unknown concentration) are added in progressively increasing amounts
- The two different antigens compete for the binding sites on the antibody
- As the concentration of unlabeled antibody increases, more labeled antigen will be displaced
- The decrease in bound-radiolabeled antigen is measured - an indication of the amount of antigen present in sample
Technique
- The antigen is often labeled with a gamma-emitting isotope, e.g. iodine-125
- Beta-emitting isotopes such as tritium are also often used
- Determine the amount of antibody required to bind ~50% of radiolabeled antigen in mixture- required to ensure the number of epitopes presented by labeled antigen exceeds number of antibody binding sites
- Add unlabeled antigen to mixture
- Separate antigen-antibody complex from free antigen by precipitation
- Measure radioactivity in precipitate
- There are various methods to separate the antigen-antibody complexes from the free antigen:
- Precipitate complexes using secondary isotype-specific anti-immunoglobulin
- If complex contains IgG, it can be removed by mixing with formalin-killed Staphylococcus aureus- protein A of S. aureus has a high affinity for IgG
- Removal of the complex by either of these methods leaves an amount of free labeled antigen in the supernatant (liquid section from precipitation)- the radioactivity of this can be measured and the value taken away from the total amount of labeled antigen added (known amount)= amount of bound labeled antigen
- A number of solid-phase RIAs have been developed
- Sometimes the antibody can be absorbed onto the surface- the amount of radiolabeled antigen bound to the beads can be measured after washing
- Antibody can be immobilised on PVC or polystyrene
Applications
- As the technique requires small amounts of sample it can be conducted on 96-well microtiter plates and large numbers of samples can be tested
- RIA used in this way has been employed in the detection of the hepatitis B surface antigen in donor blood, reducing the occurrence of hepatitis infections as a result of blood transfusions in humans
- Measuring plasma levels of hormones and controlled substances
- Measuring anti-DNA antibodies present in systemic lupus erythematosus (SLE)
Drawbacks
Although the RIA is a very sensitive test, and therefore widely-used, there are disadvantages to its use:
- The substances being used are radioactive
- Gamma radiation needs special counting equipment for detection
- Iodine is naturally concentrated in the thyroid gland, whether radioactive or not, and incorporated into thyroxine
Consequently, ELISA has largely overtaken RIA as a preferred diagnostic tool
 |
This article has been peer reviewed but is awaiting expert review. If you would like to help with this, please see more information about expert reviewing. |
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Originally funded by the RVC Jim Bee Award 2007 |