Recent advances of single molecule/particle imaging with optical microscopic methods

Zhongju Ye; Hua Liu; Lehui Xiao

doi:10.1360/N032018-00199

SCIENTIA SINICA Chimica

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SCIENTIA SINICA Chimica, Volume 49 , Issue 5 : 787-800(2019) https://doi.org/10.1360/N032018-00199

Recent advances of single molecule/particle imaging with optical microscopic methods

Zhongju Ye , Hua Liu , Lehui Xiao ^*

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ReceivedAug 27, 2018
AcceptedSep 13, 2018
PublishedOct 30, 2018

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Abstract

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国家自然科学基金(21522502)

super-resolution imaging

optical microscopic imaging

single-particle catalysis

single-molecule detection

single-particle tracking

References

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Figure 1
Schematic diagram of single-molecule detection. (A) Schematic illustration of biomarker detection using scattering-based single particle intensity measurement with a dark-field microscope [44]. (B) Schematic diagram of the light path for the optical microscopic imaging of single nanoparticle and the principle of the color-coded SPD for PPi assay [45]. (C) Schematic diagram of the light path for the optical microscopic imaging of UCNPs and the principle of digital immunosorbent assay by single-particle enumeration [50]. (D) Detection of adenosine molecules based on the single molecule photobleaching measurement [51]. (E) Telomerase detection by single molecule stochastic binding of the telomeric repeats, single-molecule fluorescent trajectories in the presence and absence of telomerase [52] (color online).
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Figure 2
Single-particle tracking. (A) Schematic representation of the diverse lateral diffusion of molecular components on the cell surface [57]. (B) Schematic diagram of TAT-modified GNPs diffusion on lipid membrane [61]. (C) Dual-view optics for single particle translational and rotational tracking [69]. (D) Influenza viruses moving along different configurations of microtubules [71] (color online).
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Figure 3
(A) Super-resolution imaging permits the nature and morphology of intracellular Aβ_1-42 aggregates to be probed in situ [82]. (B) Super-resolution imaging and analysis of cell-surface glycoproteins [88]. (C) A sequence of fluorescence microscopy images showing the blinking behavior of an E. coli labeled with 20% PCBM-doped PFBT CPNs [89]. (D) Super-resolution imaging of single molecules in a conjugated hotspot region [90] (color online).
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Figure 4
Single-particle catalysis and super-resolution imaging. (A) Single-turnover detection of single-Au-nanoparticle catalysis [102]. (B) Autocorrelation functions of the τ_off (a) and τ_on (b) from the turnover trajectory of a single 9.1 nm Au-nanoparticle; dependence of the activity fluctuation rate of the τ_off reaction (c) and the τ_on reaction (d) [96]. (C) Quantitative reaction kinetics of a single Au@mSiO₂ nanorod at subparticle resolution [106]. (D) Spatially resolved activity quantitation on single Au@mSiO₂ nanoplates [107] (color online).

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Recent advances of single molecule/particle imaging with optical microscopic methods

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