Abstract
Microscopies have become pillars of our characterization tools to observe biological systems and assemblies. Correlative and synchronous use of different microscopies relies on the fundamental assumption of non-interference during images acquisitions. In this work, by exploring the correlative use of Atomic Force Microscopy and confocal-Fluorescence-Lifetime Imaging Microscopy (AFM-FLIM), we quantify cross-talk effects occurring during synchronous acquisition. We characterize and minimize optomechanical forces on different AFM cantilevers interfering with normal AFM operation as well as spurious luminescence from the tip and cantilever affecting time-resolved fluorescence detection. By defining non-interfering experimental imaging parameters, we show accurate real-time acquisition and two-dimensional mapping of interaction force, fluorescence lifetime and intensity characterizing morphology (AFM) and local viscosity (FLIM) of gel and fluid phases separation of supported lipid model membranes. Finally, as proof of principle by means of synchronous force and fluorescence spectroscopies, we precisely tune the lifetime of a fluorescent nanodiamond positioned on the AFM tip by controlling its distance from a metallic surface. This opens up a novel pathway of quench sensing to image soft biological samples such as membranes since it does not require tip-sample mechanical contact in contrast with conventional AFM in liquid.
Highlights
Real space observation of biomolecules at high resolution is crucial to address fundamental biological questions
We focus on the coupling between a confocal spot and an Atomic Force Microscopy (AFM) tip/cantilever with the aim to investigate and quantify photothermal induced deflection resulting from the presence of metal coating at the cantilever backside[32], radiation pressure exerted on the tip[33] due to the scattering of the confocal spot and tip/cantilever luminescence[16]
The emitted fluorescence photons are collected by the objective, focused on a pinole, recollimated, filtered by an emission filter and focused on an Avalanche Photodiode (APD) connected to a Time-Correlated Single Photon Counting (TCSPC) card
Summary
Some recently developed super-resolution techniques such as Stimulated Emission Depletion Microscopy (STED)[2], Stochastic Optical Reconstruction Microscopy (STORM)[3], Photoactivated Localization Microscopy (PALM)[4] and MINFLUX5 have bypassed the diffraction limit and improved the lateral resolution down to a few nanometers While they do have some drawbacks both in terms of photo-toxicity or acquisition speed, their popularity nowadays reflects their coming of age. Synchronicity is of high importance as it permits to follow dynamical biological processes It allows the acquisition of optical images while a force is applied by the AFM tip in pump and probe experiments, for instance, monitoring the response of a living cell to an AFM tip indentation or during single-molecule manipulation[23,24]. This type of illumination is not suitable for thick samples such as cells, since the tip will be positioned at the apical cellular membrane axial position, out of the evanescent excitation field
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