Multidimensional Fluorescence Imaging and Super-resolution Exploiting Ultrafast Laser and Supercontinuum Technology

TL;DR

This thesis develops advanced fluorescence imaging tools, including tunable supercontinuum sources and super-resolved FLIM microscopy, to enhance biological research by achieving super-resolution and detailed molecular insights.

Contribution

It introduces a novel supercontinuum excitation source for FLIM microscopes and a super-resolved STED FLIM microscope capable of imaging beyond the diffraction limit.

Findings

Supercontinuum sources enable versatile FLIM imaging.

Super-resolved STED FLIM achieves imaging beyond diffraction limits.

Demonstrated applications in muscle fibers and immune signaling.

Abstract

This thesis centres on the development of multidimensional fluorescence imaging tools, with a particular emphasis on fluorescence lifetime imaging (FLIM) microscopy for application to biological research. The key aspects of this thesis are the development and application of tunable supercontinuum excitation sources based on supercontinuum generation in microstructured optical fibres and the development of stimulated emission depletion (STED) microscope capable of fluorescence lifetime imaging beyond the diffraction limit. The utility of FLIM for biological research is illustrated by examples of experimental studies of the molecular structure of sarcomeres in muscle fibres and of signalling at the immune synapse. The application of microstructured optical fibre to provide tunable supercontinuum excitation source for a range of FLIM microscopes is presented, including wide-field, Nipkow disk confocal and hyper-spectral line scanning FLIM microscopes. The application of supercontinuum generation to the first super-resolved FLIM microscope is then described. This novel microscope exploited the concept of STED with a femtosecond mode-locked Ti:Sapphire laser providing a tunable excitation beam by pumping microstructured optical fibre for supercontinuum generation and directly providing the (longer wavelength) STED beam. This STED microscope was implemented in a commercial scanning confocal microscope to provide compatibility with standard biological imaging, and exploited digital holography using a spatial light modulator (SLM) to provide the appropriate phase manipulation for shaping the STED beam profile and to compensate for aberrations. The STED microscope was shown to be capable of recording superresolution images in both the lateral and axial planes, according to the settings of the SLM.