High-resolution tomographic imaging of a human cerebellum: comparison of absorption and grating-based phase contrast

Schulz, Georg; Weitkamp, Timm; Zanette, Irène; Pfeiffer, Franz; Beckmann, Felix; Dávid, Christian; Rutishauser, Simon; Reznikova, E.; Müller, Bert

doi:10.1098/rsif.2010.0281

Cited by 144 publications

(114 citation statements)

References 49 publications

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“…From its first implementations up to this day, grating interferometry has been mainly exploited for imaging biological soft-tissue samples (8,9,16,17,21). However, other classes of samples, such as paleontological specimens, can also benefit from the high sensitivity of the phase and darkfield signals provided by this technique.…”

Section: Resultsmentioning

confidence: 99%

“…The δ resolution in the standard and SWI volumes was very similar despite the drastic difference in dose and number of images: δ resolutions of 4.7 × 10 −10 and 4.9 × 10 −10 were obtained, respectively, with the standard and SWI acquisition schemes (note that similar values have been measured in ref. 9). δ values can be converted into Hounsfield units for the phase signal (HU-P) as described in ref.…”

Section: Resultsmentioning

confidence: 99%

“…It gives access to differential phase contrast (DPC) at ultrahigh sensitivity (density differences down to 0.5 mg∕cm 3 can be routinely resolved) (8,9). XGI also provides dark-field images of the sample that reveal the presence of scattering structures on the nanoscale (10).…”

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confidence: 99%

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Trimodal low-dose X-ray tomography

Zanette

Bech

Rack

et al. 2012

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

111

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X-ray grating interferometry is a coherent imaging technique that bears tremendous potential for three-dimensional tomographic imaging of soft biological tissue and other specimens whose details exhibit very weak absorption contrast. It is intrinsically trimodal, delivering phase contrast, absorption contrast, and scattering (“dark-field”) contrast. Recently reported acquisition strategies for grating-interferometric phase tomography constitute a major improvement of dose efficiency and speed. In particular, some of these techniques eliminate the need for scanning of one of the gratings (“phase stepping”). This advantage, however, comes at the cost of other limitations. These can be a loss in spatial resolution, or the inability to fully separate the three imaging modalities. In the present paper we report a data acquisition and processing method that optimizes dose efficiency but does not share the main limitations of other recently reported methods. Although our method still relies on phase stepping, it effectively uses only down to a single detector frame per projection angle and yields images corresponding to all three contrast modalities. In particular, this means that dark-field imaging remains accessible. The method is also compliant with data acquisition over an angular range of only 180° and with a continuous rotation of the specimen.

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

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Trimodal low-dose X-ray tomography

Zanette

Bech

Rack

et al. 2012

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

111

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“…The choice of the photon energy for heterogeneous tissue using phase-contrast CT, rather than absorption contrast, is easier, as the real part of the refractive index varies much less with elemental composition than the absorbance [3]. Therefore, both absorption and phase-contrast imaging provide complementary information [4,5]. Other techniques including magnetic resonance microscopy and histology are also complementary [6].…”

Section: Introductionmentioning

confidence: 99%

X-ray microscopy of soft and hard human tissues

Müller

Schulz

Deyhle

et al. 2016

AIP Conference Proceedings

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“…These imaging techniques yield only information on surface-near regions and volumes restricted to cubic micrometers. In the last decade, the tissue preparation and high-resolution hard X-ray tomography has been advanced to reveal individual unstained cells in cubic millimeter brain volumes [1,2] with phase contrast. More recently, sufficient contrast for cell imaging in single distance propagation mode [3] or even with lab-based conventional approaches [4] was obtained by embedding brain specimens in paraffin.…”

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Visualization and Segmentation of Cells in Unstained Paraffin-Embedded Cerebral Tissue

et al. 2018

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The three-dimensional visualization of cerebral cells is a challenging task. The human brain with a weight of about 1 kg contains around 10 12 cells. Currently, brain cells are imaged by optical and electron microscopies. These imaging techniques yield only information on surface-near regions and volumes restricted to cubic micrometers. In the last decade, the tissue preparation and high-resolution hard X-ray tomography has been advanced to reveal individual unstained cells in cubic millimeter brain volumes [1,2] with phase contrast. More recently, sufficient contrast for cell imaging in single distance propagation mode [3] or even with lab-based conventional approaches [4] was obtained by embedding brain specimens in paraffin. This allows improving the spatial resolution from the regime of grating interferometry, limited by the grating period, usually in the range of a few micrometers, to subcellular length-scales. Such data lend themselves for (semi-)automatic cellular und subcellular structure segmentation. Several thousand Purkinje cells were visualized and segmented within a ~40 mm 3 cerebellum specimen. Individual dendritic trees of Purkinje cells were visualized from the same specimen with higher resolution scans.The cerebellum was excised from a donated body of a 73-year old male in accordance with the Guidelines of the Ethical committee Northwestern Switzerland. It was embedded in paraffin following fixation in 4% histological-grade buffered formalin and dehydration in ethanol. Two cylinders with diameters 2.6 and 6.0 mm were cut from the paraffin blocks by means of hollow punches. Singledistance propagation phase contrast micro computed tomography was performed at the beamlines ID19 (European Synchrotron Radiation Facility, Grenoble, France) and Diamond Manchester Imaging Branchline I13-2 (Diamond Light Source, Didcot, UK) in local mode. Measurements at ID19 were performed with pink beam with a mean photon energy of 19.45 keV at 1.75 µm pixel length. 2004 equiangular projections were acquired over 360° with a FReLoN 2K CCD camera with 1 s exposure per projection after 80 cm propagation distance. At I13-2, 19 keV monochromatic beam energy and 0.45 µm pixel length were used. Projections were acquired with a pco.4000 camera (PCO AG, Kelheim, Germany) with 8 s exposure time at 2400 equiangular steps over 180° and 5 cm propagation distance. Phase retrieval was performed with the algorithm proposed [5] and implemented in the software package ANKAphase [6]. Reconstruction of the tomographic volumes was performed with the filtered backprojection routine implemented in MATLAB R2014b (Simulink, The MathWorks, Inc., USA). After tomographic measurements, the specimens were re-embedded into larger paraffin blocks for histological

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High-resolution tomographic imaging of a human cerebellum: comparison of absorption and grating-based phase contrast

Cited by 144 publications

References 49 publications

Trimodal low-dose X-ray tomography

Trimodal low-dose X-ray tomography

X-ray microscopy of soft and hard human tissues

Visualization and Segmentation of Cells in Unstained Paraffin-Embedded Cerebral Tissue

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