At the Faculty of Pharmacy of the Basque Public University (UPV/EHU) the Pharmacokinetics, Nanotechnology and Gene Therapy research team is using nanotechnology to develop new formulations that can be applied to drugs and gene therapy. Specifically, they are using nanoparticles to design systems for delivering genes and drugs; this helps to get the genes and drugs tothe point of action so that they can produce the desired effect.

The research team has shown that lipid nanoparticles, which they have been working on for several years, are ideal for acting as vectors in gene therapy. Gene therapy is a highly promising alternative for diseases that so far have no effective treatment. It consists of delivering a nucleic acid, for example, a therapeutic gene, to modulate the expression of a protein that is found to be altered in a specific disease, thus reversing the biological disorder.

The main obstacle is that the genetic material cannot be formulated in conventional pharmaceutical ways, because it becomes degraded within the organism and cannot perform its function. To overcome this obstacle, viral vectors are normally used and they are able to deliver the therapeutic gene to the cells in which it has to act. However, as Dr Alicia Rodriguez explains, “viral vectors have a great drawback because they have a great potential to develop tumours. That is why there is a lot of interest in developing non-viral vectors, like vectors based on lipid nanoparticles.”

“In this respect,” adds Dr Rodriguez, “we have for several years been working to develop formulations for treating degenerative retina diseases, diseases for which there is currently no effective curative or palliative treatment and which causes blindness in the patients who in many cases are very young people. "The research they have done has borne fruit already, and they have in fact managed to develop a vector capable of making a protein express itself in the eyes of rats after ocular delivery.

Another application of lipid nanoparticles is to develop new formulations to deliver drugs that are not particularly soluble or which are difficult to absorb. Dr Rodriguez explained the problem with these drugs: “40% of the new pharmacologically active molecules are reckoned to be insoluble or not very soluble in water; that prevents many of these potentially active molecules from ever reaching the clinic because of the problems involved in developing a safe, effective formulation.”

The Faculty of Pharmacy’s research team has shown that the strategy of encapsulating drugs of this type in lipid nanoparticles is effective: “They are spheres made of lipids and they have very small particleswhich encase the drug. That way, the absorption of the drug given orally can be increased,” points out Dr Rodriguez.

This story is reprinted from material from
Basque Research, with editorial changes made by Materials Today. The views expressed in this article do not necessarily represent those of Elsevier. Link to original source.