Difference between revisions of "Team:SDU-Denmark/Tour72"

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     Kim CS, et al. Cellular imaging of endosome entrapped small gold nanoparticles, 2015 Jun 10;2:306-15. doi: 10.1016/j.mex.2015.06.001. <a target="blank_" href="10.1016/j.mex.2015.06.001">(Doi)</a>
 
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Revision as of 20:42, 9 September 2015

Medical aspects

Even though there is no doubt that peptide aptamers are potential rivals of traditional antibodies in medicine and therapy, some hurtles have to be defeated before clinical implementation will be possible.

Which modification do the peptide aptamer need?

It is necessary with
  • an effector mechanism that can either activate the immune system or in some how kill the antigen or the cell that the antigen is bound to. Traditional antibodies have a Fab region, that bind to microbes of which they have specificity. Activation of the immune respons is conducted through their Fc region that interacts with Fc receptors on cell surfaces of lymphocytes and/or other effector cells of the immune system (e.g. natural killer cells). Such an effector mechanism or something similar have to be attached to the peptide aptamer if an effect is desired.
  • a suitable size to avoid an respons from the human immune system. The bigger molecule the larger risk of immunogenicity. If the immune system develops immunization against the peptide aptamer it will not have any function at all.
  • adjustable half-life so it can be used as a treatment for both quickly directed therapy and for chronic diseases. If the target is cancer cells or something that just needs to be detected, then there is no need for a long half-life. On the other hand peptide aptamers targeted at chronic diseases have to have a very long degradation time, so the patients do not have to inject the drug too often.

How can peptide aptamers treat disease?

  • By attaching small gold nanoparticles (sAuNPs) to the peptide aptamer it would be possible to detect the aptamer inside the body and target fx radiotherapi: Recent studies have proved small gold nanoparticles (sAuNPs) as excellent vehicles for drug delivery and cancer therapy. sAuNPs are proven as excellent vehicles especially because of their high biocompatibily, large surface-to-volume ratio and strong diffusivity. Reference: Kim CS, et al. Cellular imaging of endosome entrapped small gold nanoparticles, 2015 Jun 10;2:306-15. doi: 10.1016/j.mex.2015.06.001. (Doi)

Which of these things have we been able to accomplish already?