Monoclonal antibodies: Difference between revisions

Monoclonal antibodies are identical antibodies that recognise one specific epitope^[1].

First an antigen is injected into a host organism (e.g. rabbit or mouse). The hosts immune system will the start to produce antibodies against the antigen. To see if the desired antibody has been produced a blood sample of the model organism is then taken-if positive the spleen is removed^[2].

The B-cells in the spleen producing the antibodies are released by being placed in a certain medium. However, the B-cells are unable to survive outside of the host organism very well. To overcome this problem the B-cells are fused with Myeloma cells (a malignant cancer) producing Hybridoma cells which can rapidly divide and continue to produce the antibodies^[3]. The Hybridoma cells are individually separated out and grown in culture. The cultures will now contain identical cells all producing a single immunoglobulin in each generation. All the antibodies produced in the culture are the same and are monoclonal antibodies^[4].

Monoclonal antibodies bind to a specific hormone (hCG) which is released after conception. The monoclonal antibody is usually coated in a substance which is able to change colour depending if the antigen-antibody complex has been formed^[5].

Monoclonal antibodies can be made to specifically recognise cancer cells. The genes encoding specific antibody subunits are cloned, and the area encoding the antigen-binding region is combined with human DNA sequences encoding the rest of the antibody to produce a humanised monoclonal antibody^[6]. Anticancer drugs can be bound to the antibody and released when the antigen-antibody complex has formed. This allows the treatment to directly target the cancer cells and not harm the other healthy cells^[7].