Ryuji Igarashi scite author profile

Recent developments of imaging techniques have enabled fluorescence microscopy to investigate the localization and dynamics of intracellular substances of interest even at the single-molecule level. However, such sensitive detection is often hampered by autofluorescence arising from endogenous molecules. Those unwanted signals are generally reduced by utilizing differences in either wavelength or fluorescence lifetime; nevertheless, extraction of the signal of interest is often insufficient, particularly for in vivo imaging. Here, we describe a potential method for the selective imaging of nitrogen-vacancy centers (NVCs) in nanodiamonds. This method is based on the property of NVCs that the fluorescence intensity sensitively depends on the ground state spin configuration which can be regulated by electron spin magnetic resonance. Because the NVC fluorescence exhibits neither photobleaching nor photoblinking, this protocol allowed us to conduct long-term tracking of a single nanodiamond in both Caenorhabditis elegans and mice, with excellent imaging contrast even in the presence of strong background autofluorescence.

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Distance Determination in Proteins inside Xenopus laevis Oocytes by Double Electron−Electron Resonance Experiments

Igarashi

et al. 2010

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DEER (double electron-electron resonance) enables the observation of long-range dipole interactions (1.5-8 nm) between electron spin centers and has become a unique method for structural analysis of site-directed spin-labeled (SDSL) proteins. The method was applied to proteins inside eukaryotic cells, Xenopus laevis oocytes. DEER measurements of the oocytes, into which SDSL-ubiquitin derivates were injected, gave rise to interpretable signals and allowed us to perform in situ analyses of the interspin distances of the proteins.

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pH Nanosensor Using Electronic Spins in Diamond

et al. 2019

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Nanoscale measurements provide insight into the nano world. For instance, nanometric spatiotemporal distribution of intracellular pH is regulated by and regulates a variety of biological processes. However, there is no general method to fabricate nanoscale pH sensors. Here, we, to endow pH-sensing functions, tailor the surface properties of a fluorescent nanodiamond (FND) containing nitrogen-vacancy centers (NV centers) by coating the FND with an ionic chemical layer. The longitudinal relaxation time T 1 of the electron spins in the NV centers inside a nanodiamond modified by carboxyl groups on the particle surface was found to depend on ambient pH between pH 3 and pH 7, but not between pH 7 and pH 11. Therefore, a single particle of the carboxylated nanodiamond works as a nanometer-sized pH meter within a microscopic image and directly measures the nanometric local pH environment. Moreover, the pH dependence of an FND was changed by coating it with a polycysteine layer, which contains a multitude of thiol groups with higher pK a. The polycysteine-coated nanodiamond obtained a pH dependence between pH 7 and pH 11. The pH dependence of the FND was also observed in heavy water (D2O) buffers. This indicates that the pH dependence is not caused by magnetic noise induced by 1H nuclear spin fluctuations, but by electric noise induced by ion exchanges. Via our method, the sensitive pH range of the nanodiamond pH sensor can potentially be controlled by changing the ionic layer appropriately according to the target biological phenomena.

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Ryuji Igarashi

Real-Time Background-Free Selective Imaging of Fluorescent Nanodiamonds in Vivo

Distance Determination in Proteins inside Xenopus laevis Oocytes by Double Electron−Electron Resonance Experiments

pH Nanosensor Using Electronic Spins in Diamond

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