Measurement in Science Bioassays and Immunoassays Karim Meeran 23 October 2009.
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Transcript of Measurement in Science Bioassays and Immunoassays Karim Meeran 23 October 2009.
Assay
• Method of measuring concentration of a hormone in body fluid (usually serum).
• Previously used “bioassay”
Bioassay
• Administer extract of pituitary to animal and observe
• (eg: LH would very slowly cause testicular enlargement).
Immunoassay
• Because antibody could bind to a particular protein, this could be used to measure the amount of a substance.
• Make antibody by giving protein to animal of different species
• Assay for human adrenomedullin
• Give adrenomedullin to rabbits until they make antibodies (few months)
• Collect blood from the rabbits
• Use that blood to mop up antigen
Principles of RIA
• Have known amount of radioactive adrenomedullin.
• Add unknown amount of unlabelled adrenomedullin
• Add measured amount of antibody
• Add a second antibody against the first
• Mix and spin
Principles of RIA
• The second antibody may be a mouse anti rabbit antibody.
• This will be bound to a solid particle that will sink when centrifuged.
Immunoassays
• Method of measuring concentration of a hormone in a body
• Two methods: - Competitive Assays
- Sandwich Assays
• Both work on the principle of enzyme specificity.
Competitive assays
• For a given peptide (P) we are able to produce antibodies by administering the peptide to a different species.
E.g.: human peptide to rabbit.
• Let the rabbit make antibodies (Abr), after a couple months remove the blood and it will have Ab for this P
Competitive assays
• Have Ab to P and we need to be able to accurately measure P. How do we do this:
• Make a Radioactive version of the peptide (Phot) and an Abm to the rabbit produce
• Abr into a mouse. But this Abm we also covalently attach to a particle of charcoal so it is heavier.
Competitive Assays
A mixture of P and Phot
Addition of Abr which bind specifically to the peptides but cannot discriminate which ones are hot
Competitive Assays
A mixture of P and Phot
Addition of Abr which bind specifically to the peptides but cannot discriminate which ones are hot
Competitive Assays
A mixture of P and Phot
Addition of Abr which bind specifically to the peptides but cannot discriminate which ones are hot
Addition of excess Abm which binds to the Abr
Competitive Assays
A mixture of P and Phot
Addition of Abr which bind specifically to the peptides but cannot discriminate which ones are hot
Addition of excess Abm which binds to the Abr
Competitive Assays
A mixture of P and Phot
Addition of Abr which bind specifically to the peptides but cannot discriminate which ones are hot
Addition of excess Abm which binds to the Abr
Spin
Competitive Assays
Following centrifugation, the supernatant and pellet need to be separated.
Count BOUND radiation.
Count FREE radiation
Competitive Assays
Following centrifugation, the supernatant and pellet need to be separated.
Count BOUND radiation.
50%
Count FREE radiation
50%
Competitive Assays
Following centrifugation, the supernatant and pellet need to be separated.
Count BOUND radiation.
50%
Count FREE radiation
50%
Repeat for different concentrations of P
Competitive Assays
A mixture of P and Phot
Addition of Abr which bind specifically to the peptides but cannot discriminate which ones are hot
Competitive Assays
A mixture of P and Phot
Addition of Abr which bind specifically to the peptides but cannot discriminate which ones are hot
Competitive Assays
A mixture of P and Phot
Addition of Abr which bind specifically to the peptides but cannot discriminate which ones are hot
Addition of excess Abm which binds to the Abr
Spin
Competitive Assays
Following centrifugation, the supernatant and pellet need to be separated.
Count BOUND radiation.
Count FREE radiation
Competitive Assays
Following centrifugation, the supernatant and pellet need to be separated.
Count BOUND radiation.
100%
Count FREE radiation
0%
Competitive Assays
Following centrifugation, the supernatant and pellet need to be separated.
Count BOUND radiation.
100%
Count FREE radiation
0%
Repeat for different concentrations of P
Competitive Assays
A mixture of P and Phot
Addition of Abr which bind specifically to the peptides but cannot discriminate which ones are hot
Competitive Assays
A mixture of P and Phot
Addition of Abr which bind specifically to the peptides but cannot discriminate which ones are hot
Competitive Assays
A mixture of P and Phot
Addition of Abr which bind specifically to the peptides but cannot discriminate which ones are hot
Addition of excess Abm which binds to the Abr
Spin
Competitive Assays
Following centrifugation, the supernatant and pellet need to be separated.
Count BOUND radiation.
66%
Count FREE radiation
33%
Repeat for different concentrations of P
Summary
Zero blue peptide gives 100% bound radiation.
Three blue peptide gives 66% bound radiation.
Twelve blue peptides gives 33% bound radiation.
This is the basis of how it works but for each assay we do using the antibodies we have we must run a series of these to obtain a reference curve.
Six blue peptide gives 50% bound radiation.
Competitive Assays
Set up a series of tubes with known varying concentrations of P (achieved by serial dilution).
1 2 3 4
Competitive Assays
Set up a series of tubes with known varying concentrations of P (achieved by serial dilution).
To all of these we add a set amount of Phot.1 2 3 4
Competitive Assays• To each of these we add a set amount of Abr.
• This will bind randomly to the hot and cold peptides.
• Then add second antibody
1 2 3 4
Competitive Assays• If the amount of Phot causes 1000 counts
• When we add Abm and centrifuge the mixtures we will be able to detect different amounts of radiation from the light and heavy regions of the mixtures.
1 23 4
667 counts
333 counts 500 counts 667 counts
500 counts 333 counts 0 counts
1000 counts
Competitive Assays• If the amount of Phot causes 1000 counts
• When we add Abm and centrifuge the mixtures we will be able to detect different amounts of radiation from the light and heavy regions of the mixtures.
12 3
12 added
667 counts
None added
0 counts
1000 counts
B/F = infinite
6 added
500 counts
500 counts
B/F=1.0
3 added
333 counts
Heavy
Light
667 counts
B/F =2.0
333 counts
B/F=0.5
Competitive assays
• This has allowed us to set up a graph which shows the counts against concentration of P.Counts
B/F ratio
2
1
0.5
0 3 6 12 Conc. Of P
Competitive assays• We perform the same thing to a P of
unknown concentration, adding same amount of Phot and Abr and Abm as before.
• The count we get will allow us to extrapolate the value of P off the graph.
Counts
B/F ratio
2
1
0.5
0 3 6 12 Conc. Of P
Immunoradiometric assay
• Two antibodies (monoclonal) to different epitopes of the protein.
• The first is bound to the tube.
• The second is radioactive.
Sandwich Assays
• This is a different assay type but using the same principle of antibody specificity.
• Except we use MONOCLONAL antibodies.
• Therefore more expensive and takes longer.
• But more precise.
Sandwich Assays• Here we are attaching one antibody (Abc)
to a surface.
• This Abc is specific to one part of the peptide (P) ie: the N-terminus
• We then expose the surface to P
• We wash way any remaining solution
Sandwich Assays
• We then create an antibody (Abh) which is Radioactive
• This Abh is specific to the C-terminus of P.
• This is added to the surface.
• The excess solution is then washed away.
Sandwich Assays
• As we did in the competetive assays we need to create a refrence chart for this assay. This is done by using different concentrations of P but set amount of Abc and Abh.
• We can then measure the concentration of P in our unknown solution.
Sandwich Assays
• But in this type of assay we get a different sort of graph to extrapolate from.
Radioactive Count
Conc. Of P