Resolution enhancement techniques in microscopy

Cremer, Christoph; Masters, Barry R.

doi:10.1140/epjh/e2012-20060-1

Cited by 145 publications

(137 citation statements)

References 208 publications

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“…Because of diffraction, conventional microscopes cannot resolve structure details that are closer than half the wavelength of the detected light (19), limiting the lateral resolution to ;200 nm. This barrier seemed to be insuperable for more than a century, but today's superresolution light-optical technologies can bypass it (20)(21)(22)(23)(24)(25)(26)(27)(28)(29)(30)(31)(32)(33). Therefore, we hypothesized that using optical superresolution technology would enable us to study cellular carbon ion radiation effects at the nanometer scale.…”

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confidence: 99%

Superresolution light microscopy shows nanostructure of carbon ion radiation‐induced DNA double‐strand break repair foci

et al. 2016

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Carbon ion radiation is a promising new form of radiotherapy for cancer, but the central question about the biologic effects of charged particle radiation is yet incompletely understood. Key to this question is the understanding of the interaction of ions with DNA in the cell's nucleus. Induction and repair of DNA lesions including double-strand breaks (DSBs) are decisive for the cell. Several DSB repair markers have been used to investigate these processes microscopically, but the limited resolution of conventional microscopy is insufficient to provide structural insights. We have applied superresolution microscopy to overcome these limitations and analyze the fine structure of DSB repair foci. We found that the conventionally detected foci of the widely used DSB marker gH2AX (Ø 700-1000 nm) were composed of elongated subfoci with a size of ∼100 nm consisting of even smaller subfocus elements (Ø 40-60 nm). The structural organization of the subfoci suggests that they could represent the local chromatin structure of elementary DSB repair units at the DSB damage sites. Subfocus clusters may indicate induction of densely spaced DSBs, which are thought to be associated with the high biologic effectiveness of carbon ions. Superresolution microscopy might emerge as a powerful tool to improve our knowledge of interactions of ionizing radiation with

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confidence: 99%

Superresolution light microscopy shows nanostructure of carbon ion radiation‐induced DNA double‐strand break repair foci

et al. 2016

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“…With the advent of various superresolution methods (14), particularly single-molecule localization microscopy (SMLM)-based methods (15)(16)(17) and recently developed strategies for labeling DNA (18,19), it is now possible to study DNA structures at the molecular scale. The underlying principle of most SMLM-based methods is to label molecules of interest with fluorescent moieties that can reversibly switch between a fluorescent state and a stable dark…”

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Superresolution imaging reveals structurally distinct periodic patterns of chromatin along pachytene chromosomes

Prakash

Fournier

Redl

et al. 2015

Proc. Natl. Acad. Sci. U.S.A.

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During meiosis, homologous chromosomes associate to form the synaptonemal complex (SC), a structure essential for fertility. Information about the epigenetic features of chromatin within this structure at the level of superresolution microscopy is largely lacking. We combined single-molecule localization microscopy (SMLM) with quantitative analytical methods to describe the epigenetic landscape of meiotic chromosomes at the pachytene stage in mouse oocytes. DNA is found to be nonrandomly distributed along the length of the SC in condensed clusters. Periodic clusters of repressive chromatin [trimethylation of histone H3 at lysine (Lys) 27 (H3K27me3)] are found at 500-nm intervals along the SC, whereas one of the ends of the SC displays a large and dense cluster of centromeric histone mark [trimethylation of histone H3 at Lys 9 (H3K9me3)]. Chromatin associated with active transcription [trimethylation of histone H3 at Lys 4 (H3K4me3)] is arranged in a radial hair-like loop pattern emerging laterally from the SC. These loops seem to be punctuated with small clusters of H3K4me3 with an average spread larger than their periodicity. Our findings indicate that the nanoscale structure of the pachytene chromosomes is constrained by periodic patterns of chromatin marks, whose function in recombination and higher order genome organization is yet to be elucidated.

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“…Four blue dips were clearly resolved when using the enhancer, whereas only three orange , where A max and A min are the maximum and minimum detected amplitudes, respectively. 37 Without the enhancer, the obtained contrast was 0.14, and it increased by approximately 4.4 times up to 0.62 when the enhancer was used. Figure 8 shows the results of nondestructive imaging of the IC card with and without the enhancer at 125 GHz.…”

Section: Demonstration Of Subwavelength Imaging Using the Resolumentioning

confidence: 95%

“…We note that visualizing the generated terajet is important because it directly relates to the point spread function (PSF), and all imaging results can be considered to be the convolution of the PSF with the real objects. 11,37 The EO sensor was moved in the near-field region to visualize the THz-wave distribution. The E-plane was parallel to the XZ-plane.…”

Section: Introductionmentioning

confidence: 99%

Enhancement of spatial resolution of terahertz imaging systems based on terajet generation by dielectric cube

et al. 2017

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The terahertz (THz, 0.1–10 THz) region has been attracting tremendous research interest owing to its potential in practical applications such as biomedical, material inspection, and nondestructive imaging. Those applications require enhancing the spatial resolution at a specific frequency of interest. A variety of resolution-enhancement techniques have been proposed, such as near-field scanning probes, surface plasmons, and aspheric lenses. Here, we demonstrate for the first time that a mesoscale dielectric cube can be exploited as a novel resolution enhancer by simply placing it at the focused imaging point of a continuous wave THz imaging system. The operating principle of this enhancer is based on the generation—by the dielectric cuboid—of the so-called terajet, a photonic jet in the THz region. A subwavelength hotspot is obtained by placing a Teflon cube, with a 1.46 refractive index, at the imaging point of the imaging system, regardless of the numerical aperture (NA). The generated terajet at 125 GHz is experimentally characterized, using our unique THz-wave visualization system. The full width at half maximum (FWHM) of the hotspot obtained by placing the enhancer at the focal point of a mirror with a measured NA of 0.55 is approximately 0.55λ, which is even better than the FWHM obtained by a conventional focusing device with the ideal maximum numerical aperture (NA = 1) in air. Nondestructive subwavelength-resolution imaging demonstrations of a Suica integrated circuit card, which is used as a common fare card for trains in Japan, and an aluminum plate with 0.63λ trenches are presented. The amplitude and phase images obtained with the enhancer at 125 GHz can clearly resolve both the air-trenches on the aluminum plate and the card’s inner electronic circuitry, whereas the images obtained without the enhancer are blurred because of insufficient resolution. An increase of the image contrast by a factor of 4.4 was also obtained using the enhancer.

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Resolution enhancement techniques in microscopy

Cited by 145 publications

References 208 publications

Superresolution light microscopy shows nanostructure of carbon ion radiation‐induced DNA double‐strand break repair foci

Superresolution light microscopy shows nanostructure of carbon ion radiation‐induced DNA double‐strand break repair foci

Superresolution imaging reveals structurally distinct periodic patterns of chromatin along pachytene chromosomes

Enhancement of spatial resolution of terahertz imaging systems based on terajet generation by dielectric cube

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