Nanoparticles as a possible solution to antibiotic resistance
Around one in 3,300 children in Germany is born with mucoviscidosis. A characteristic of this illness is that one channel albumen on the cell surface is disturbed by mutations. Thus, the amount of water of different secretions in the body is reduced, which creates a tough mucus. As a consequence, inner organs malfunction. Moreover, the mucus blocks the airways. Thus, the self-regulatory function of the lung is disturbed, the mucus is colonized by bacteria and chronic infections follow.
Scientists of the Friedrich Schiller University Jena, Germany, succeeded in developing a much more efficient method to treat the often-lethal airway infections. Nanoparticles that transport the antibiotics more efficiently to their destination are crucial. “Typically, the drugs are applied by inhalation in the body. Then they make a complicated way through the body to the pathogens and many of them don’t make it to their destination,” states Prof. Dr Dagmar Fischer of the chair for Pharmaceutical Technology at the University of Jena.
The active particles need to have a certain size to be able to reach the deeper airways and not to bounce off somewhere else before. Ultimately, they have to penetrate the thick layer of mucus on the airways as well as the lower layers of the bacteria biofilm. To overcome the strong defense, the researchers encapsulated the active agents, like the antibiotic Tobramycin, in a polyester polymer. Thus, they created a nanoparticle, which they then tested in the laboratory. Pletz’s research group had developed new test systems to mimic the situation of the chronically infected CF-lung. The scientists discovered that their nanoparticle travels more easily through the sponge-like net of the mucus layer and is finally able to kill off the pathogens without any problems. Moreover, an additionally applied coating of polyethylenglycol makes it nearly invisible for the immune system. “All materials of a nanocarrier are biocompatible, biodegradable, nontoxic and therefore not dangerous for humans,” the researcher says.
However, the Jena scientists don’t know yet exactly why their nanoparticle fights the bacteria so much more efficiently. But they seek clarification in the year ahead. “We have two assumptions: Either the much more efficient transport method advances significantly larger amounts of active ingredients to the center of infection, or the nanoparticle circumvents a defense mechanism that the bacterium has developed against the antibiotic,” Fischer explains. “This would mean, that we succeeded in giving back its impact to an antibiotic, which had already lost it through a development of resistance of the bacteria.”
“More specifically, we assume that bacteria from the lower layers of the biofilm transform into dormant persisters and hardly absorb any substances from outside. In this stadium, they are tolerant to most antibiotics, which only kill off self-dividing bacteria. The nanoparticles transport the antibiotics more or less against their will to the inner part of the cell, where they can unfold their impact,” researcher Mathias Pletz adds.
Additionally, the Jena research team had to prepare the nanoparticles for the inhalation. Because at 200 nanometers the particle is too small to get into the deeper airways. “The breathing system filters out particles that are too big as well as those which are too small,” Dagmar Fischer explains. “So, we are left with a preferred window of between one and five micrometers.” The Jena researchers also have promising ideas for resolving this problem.
The scientists from Jena are at this point already convinced to have found a very promising method to fight respiratory infections of patients with mucoviscidosis. Thus they may be able to contribute to a higher life expectancy of those affected. “We were able to show that the nanoparticle coating improves the impact of the antibiotics against biofilm by a factor of 1,000,” Fischer says.
