Superchiral near fields detect virus structure

Optical spectroscopy can be used to quickly characterise the structural properties of individual molecules. However, it cannot be applied to biological assemblies because light is generally blind to the spatial distribution of the component molecules. This insensitivity arises from the mismatch in length scales between the assemblies (a few tens of nm) and the wavelength of light required to excite chromophores (≥150 nm). Consequently, with conventional spectroscopy, ordered assemblies, such as the icosahedral capsids of viruses, appear to be indistinguishable isotropic spherical objects. This limits potential routes to rapid high-throughput portable detection appropriate for point-of-care diagnostics. Here, we demonstrate that chiral electromagnetic (EM) near fields, which have both enhanced chiral asymmetry (referred to as superchirality) and subwavelength spatial localisation (∼10 nm), can detect the icosahedral structure of virus capsids. Thus, they can detect both the presence and relative orientation of a bound virus capsid. To illustrate the potential uses of the exquisite structural sensitivity of subwavelength superchiral fields, we have used them to successfully detect virus particles in the complex milieu of blood serum. Bioimaging: Spotting viral signatures with ‘superchiral’ light A technique that uses twisted light fields to detect biomolecular structures could find application as a low-cost clinical tool for screening viruses. The protein coatings around many viruses, such as the turnip yellow mosaic virus (TYMV), have complex polyhedral shapes that are difficult to resolve with conventional optical microscopes. Malcolm Kadodwala from the University of Glasgow and other colleagues in the United Kingdom now report that ‘superchiral’ light — localized fields generated by metal nanostructures that spiral as they travel — are sensitive to the asymmetric polyhedral of TYMV. By spectroscopic measurements of particle rotations in superchiral light at different frequencies, the team identified specific asymmetric signals that correlated to virus alignment on gold photonic substrates. This approach was then used to determine TYMV levels in human blood serum spiked with the virus.