"The presented method makes it possible to efficiently capture, isolate and concentrate virus particles, which may improve the sensitivity of existing diagnostic tools and analytical tests," says Professor Bernd Abel of the Institute of Technical Chemistry at Leipzig University. The nanofibrils used – small, needle-like structures – are based on the EF-C peptide, which was first described in 2013 by Professor Jan Münch from Ulm University and Ulm University Medical Center. EF-C is a peptide consisting of twelve amino acids that forms nanoscale fibrils almost instantaneously when dissolved in polar solvents. These can also be applied to magnetic particles. "Using the EF-C peptide as an example, our work shows how peptide fibrils on magnetic particles can have a completely new functionality – the more or less selective binding of viruses. Originally, fibrils of this kind were more likely to be associated with neurodegenerative diseases," adds Dr Torsten John, co-first author of the study and former doctoral researcher under Professor Abel at Leipzig University. He is now a junior researcher at the Max Planck Institute for Polymer Research in Mainz, Germany.
"Increasing the local concentration and isolating viruses from samples are critical to increasing the sensitivity of diagnosing viral infections," says Professor Münch. The researchers from Ulm and Leipzig have presented such a method for the concentration and isolation of HIV particles. In their study, they show how PNFs can be used effectively to separate HIV particles from solutions without relying on centrifugation. This innovative method uses special magnetic microbeads to specifically bind and magnetically separate virus particles, preserving their activity and infectivity. This is significant for new genetic engineering processes, for example. The study highlights the importance of the new method for HIV research and diagnostics, as well as for other applications in viral research. By improving the efficiency with which virus particles can be concentrated and isolated, this technology and the new hybrid material could help to improve the diagnosis of infections and the monitoring of resistance.