High-resolution spectral self-interference fluorescence microscopy

Understanding the structural reconfiguration of a biomolecular receptor remains a topic of particular interest to the biosensing community. This is because conformationally changing receptors are commonly employed in biosensors to harness their capability to bind specifically to their target. Often, such receptors are attached to surfaces so that binding can be transduced into a measurable response. Doing so, however, can impose constraints on the possible configurations they can adopt. Such constraints can ultimately influence, for example, their receptor−target binding models or their affinity, which is essential to provide the desired analytical performances in biosensors. Motivated by the idea of gaining further insights into the impact of surface attachment on conformationally switching receptors attached to surfaces, we explore here the various surface-based techniques capable of monitoring structural changes. We decided to narrow our survey to techniques that have been applied to the investigation of nucleic acids to provide an overview of their key features. We envision that this will bring a broader perspective of the field and the challenges ahead with the hopes of "finding the switch" in surface-attached biomolecular receptors.

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Toward nanometer-scale resolution in fluorescence microscopy using spectral self-interference

Swan

Moiseev

Cantor

et al. 2003

IEEE J. Select. Topics Quantum Electron.

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We introduce a new fluorescence microscopy technique that maps the axial position of a fluorophore with subnanometer precision. The interference of the emission of fluorophores in proximity to a reflecting surface results in fringes in the fluorescence spectrum that provide a unique signature of the axial position of the fluorophore. The nanometer sensitivity is demonstrated by measuring the height of a fluorescein monolayer covering a 12-nm step etched in silicon dioxide. In addition, the separation between fluorophores attached to the top or the bottom layer in a lipid bilayer film is determined. We further discuss extension of this microscopy technique to provide resolution of multiple layers spaced as closely as 10 nm for sparse systems.Index Terms-Fluorescence microscopy, interference, spectroscopy, ultra high-optical resolution.

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High-resolution spectral self-interference fluorescence microscopy

Cited by 3 publications

References 20 publications

Optical Interference Near Surfaces: Interference Substrates

Optical Interference Near Surfaces: Interference Substrates

“Binding” or “Binding and Switching”? A Perspective on Resolving Conformational Changes of Surface-Attached Biomolecular Receptors

Toward nanometer-scale resolution in fluorescence microscopy using spectral self-interference

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