Accessible adaptive optics and super-resolution microscopy to enable improved imaging

<p>Many of the recent innovations in biological imaging have revolved around the quest for greater resolving power, ultimately culminating in the advent of super-resolution microscopy techniques. However, all microscopy techniques are vulnerable to optical aberrations which distort the light wavefront. This leads to a gulf between theoretical and practical resolution for an imaging system. For super-resolution techniques, this can lead to reconstruction artifacts or the failure of the imaging technique entirely.</p> <p>Implementing adaptive optics (AO) in microscopy has already been shown to be highly effective at reducing these aberrations and yielding significant improvements to image quality and resolution in numerous proof of principle systems. Despite this, AO technology has yet to be widely adopted in microscopy. This is for two principle reasons. Firstly, AO implementations to date have not been robust or generalised which makes transferring them between microscopy systems, imaging modalities and sample type troublesome to impossible. Secondly, AO implementations to date have not been accessible to typical microscope users and instead have been the purview of AO microscopy specialists.</p> <p>This thesis presents a generalised, robust implementation for AO; Microscope-AOtools. This implementation has all the necessary methods for setting up and operating an adaptive element in microscopy. It has a flexible, modular design which allows for easy transfer between imaging systems, modalities, hardware configurations and sample types. These methods are integrated into Microscope-Cockpit for user accessibility. The evidence of these claims are substantiated by a detailed description of Microscope-AOtools’ successful deployment on both a spinning disk confocal system and a bespoke, upright structured illumination microscope with a range of sample types.</p>