Buffers and reagents

Coating antigen to microplate

Blocking

Incubation with the antibody

Detection

Analysis of data:

Antigen or antibody should be diluted in coating buffer to immobilize them to the wells:

For 1 L buffer:

3.03 g Na2CO3

6.0 g NaHCO3

Add distilled water to a final volume of 1000 mL, check the pH and adjust to 9.6

For 1 L 10x buffer:

23.2 g Na2HPO4 (MW: 358.14 g)

2.0 g KCl (MW: 74.56 g)

2.0 g K3PO4 (MW: 212.27 g)

80.0 g NaCl ((MW: 58.4 g))

Add distilled water to a final volume of 1000 mL, check the pH and adjust to 7.4 For a 1x solution, mix 1 part of the 10x solution with 9 parts distilled water.

Commonly used blocking agents are 1-5% BSA , serum, non-fat dry milk, casein, gelatin in PBS.

Usually PBS or TBS with detergent such as 0.05% (v/v) Tween20.

Primary and secondary antibody should be diluted in 1x blocking solution to reduce non-specific binding.

For 100 mL solution:

Mix 10.85 mL of the 98% H2SO4 with 89.15 mL distilled water, drop by drop.

For 100 mL solution:

3 g NaOH (MW: 40.00 g)

Add distilled water to a final volume of 100 mL.

1. Dilute the antigen to a final concentration of 20 μg/mL in PBS or other carbonate buffer. Coat the wells of a PVC microtiter plate with the antigen by pipeting 50 μL of the antigen dilution in the top wells of the plate. Dilute down the plate as required. Test samples containing pure antigen are usually pipeted onto the plate at less than 2 μg/mL. Pure solutions are not essential, but as a guideline, over 3% of the protein in the test sample should be the target protein (antigen). Antigen protein concentration should not be over 20 μg/mL as this will saturate most of the available sites on the microtitre plate. Ensure the samples contain the antigen at a concentration that is within the detection range of the antibody.

2. Cover the plate with an adhesive plastic and incubate for 2 h at room temperature, or 4℃ overnight. The coating incubation time and temperature may require some optimization.

3. Remove the coating solution and wash the plate twice by filling the wells with 200 μL PBS. The solutions or washes are removed by flicking the plate over a sink. The remaining drops are removed by patting the plate on a paper towel.

1. Block the remaining protein-binding sites in the coated wells by adding 200 μL blocking buffer per well.

2. Cover the plate with an adhesive plastic and incubate for at least 2 h at room temperature or, if more convenient, overnight at 4℃. The blocking incubation time and temperature may require some optimization.

3. Wash the plate twice with 200 μL PBS.

1, Add 50-100 μL of the antibody, diluted at the optimal concentration (according to the manufacturer's instructions) in blocking buffer immediately before use.

2. Cover the plate with an adhesive plastic and incubate for 2 h at room temperature. This incubation time and temperature may require optimization. Although 2 hours is usually enough to obtain a strong signal, if a weak signal is obtained, stronger staining will often observed when incubated overnight at 4℃.

3. Wash the plate four to five times with PBS.

1. Dispense 50-100 μL of the substrate solution per well with a multichannel pipet or a multipipet.

2. After sufficient color development (if it is necessary) add 100 μL of stopping solution to the wells.

3. Read the absorbance (optical density) of each well with a plate reader.

Note: some enzyme substrates are considered hazardous (potential carcinogens), therefore always handle with care and wear gloves. Although many different types of enzymes have been used for detection, horse radish peroxidase (HRP) and alkaline phosphatase (ALP) are the two widely used enzymes employed in ELISA assay. It is important to consider the fact that some biological materials have high levels of endogenous enzyme activity (such as high ALP in alveolar cells, high peroxidase in red blood cells) and this may result in non-specific signal. If necessary, perform an additional blocking treatment with levamisol (for ALP) or with 0.3% solution of H2O2 in methanol (for peroxidase).

For most applications pNPP (p-Nitrophenyl-phosphate) is the most widely used substrate. The yellow color of nitrophenol can be measured at 405 nm after 15-30 min incubation at room temperature. (This reaction can be stopped by adding equal volume of 0.75 M NaOH).

The substrate for HRP is hydrogen peroxide. Cleavage of hydrogen peroxide is coupled to oxidation of a hydrogen donor which changes color during reaction.

Add TMB solution to each well, incubate for 15-30 min, add equal volume of 2 M H2SO4 and read the optical density at 450 nm.

The end product is measured at 492 nm. Be aware that the substrate is light sensitive so keep and store it in the dark.

The end product is green and the optical density can be measured at 416 nm.

Some enzyme substrates are considered hazardous (potential carcinogens), therefore always handle with care and wear gloves.

Prepare a standard curve from the data produced from the serial dilutions with concentration on the x axis (log scale) vs absorbance on the Y axis (linear). Interpolate the concentration of the sample from this standard curve.