Squalene is a natural lipid precursor, which plays a crucial role in the biosynthesis of sterols in the cells. It is 100% biocompatible, not toxic and is able to strongly interact with the cells. This makes it very promising for creating highly efficient drugs and drug delivery systems. The so-called “squalenoylation” technology is based on the conjugation of squalenic acid with a variety of drugs. The resulting conjugated molecules spontaneously self-assemble into nanoparticles, which deliver efficiently the drugs into the target cells. Currently, anticancer (gemcitabine, doxorubicin), antiviral (dideoxycytidine) and neuroprotective (adenosine) drugs were used in this technology with great success. The next steps of these technology are to improve the ADME (Administration, Delivery, Metabolism and Excretion) profiles of the squalene-based drugs and to provide selectivity to target cells in order to reduce the side effects of therapy.
In this project we focused on interaction of squalene-based drugs with the membranes, which is crucial for an effective transport of the drugs into the cells, and their selectivity to the membranes of different composition and curvature, which may serve for targeted delivery and action, especially in oncology for discrimination between normal and cancer cells.