UV photonic integrated circuits for far-field structured illumination autofluorescence microscopy

Here, the authors develop a UV-compatible photonic integrated circuit for structured illumination microscopy on a conventional wide-field microscope. Operating at a wavelength of 360 nm, they generate switchable far-field fringe patterns, and demonstrate autofluorescence imaging of yeast cells. Ultra-violet (UV) light has still a limited scope in optical microscopy despite its potential advantages over visible light in terms of optical resolution and of interaction with a wide variety of biological molecules. The main challenge is to control in a robust, compact and cost-effective way UV light beams at the level of a single optical spatial mode and concomitantly to minimize the light propagation loss. To tackle this challenge, we present here photonic integrated circuits made of aluminum oxide thin layers that are compatible with both UV light and high-volume manufacturing. These photonic circuits designed at a wavelength of 360 nm enable super-resolved structured illumination microscopy with conventional wide-field microscopes and without modifying the usual protocol for handling the object to be imaged. As a biological application, we show that our UV photonic chips enable to image the autofluorescence of yeast cells and reveal features unresolved with standard wide-field microscopy.

Automated summary

The authors developed a UV-compatible photonic integrated circuit for structured illumination microscopy on a conventional wide-field microscope. The photonic circuits, designed at a wavelength of 360 nm, enable super-resolved imaging with UV light and do not require modification of the traditional imaging protocol. As a biological application, the UV photonic chips revealed features that cannot be resolved using standard wide-field microscopy.