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Micro-computed tomography with the highly intense, monochromatic X
rays produced by the synchrotron is a superior method to nondestructively
measure the local absorption in three-dimensional space. Because
biological tissues and cells consist mainly of water as the surrounding
medium, higher absorbing agents have to be incorporated into the
structures of interest. Even without X-ray optics such as refractive lens,
one can uncover the stain distribution with the spatial resolution of
about 1 μm. Incorporating the stain at selected cell compartments, for
example, binding to the RNA/DNA, their density distribution becomes
quantified. In this communication, we demonstrate that tomograms obtained
at the beamlines BW2 and W2 (HASYLAB at DESY, Hamburg, Germany) and 4S
(SLS, Villigen, Switzerland) clearly show that the RNA/DNA-stained HEK
293 cell clusters have a core of high density and a peripheral part of
lower density, which correlate with results of optical microscopy. The
inner part of the clusters is associated with nonvital cells as the result
of insufficient oxygen and nutrition supply. This necrotic part is
surrounded by (6 ± 1) layers of vital cells.
On September 1, 2006, the Microscopy and Microanalysis
electronic submission and review website went live. Our publisher,
Cambridge University Press, has teamed with ScholarOne to provide this
service. From now on all manuscript submissions to this journal must be
made electronically through the following website:
The design and construction of a double-hexapole aberration corrector
has made it possible to build the prototype of a spherical-aberration
corrected transmission electron microscope dedicated to high-resolution
imaging on the atomic scale. The corrected instrument, a Philips CM200 FEG
ST, has an information limit of better than 0.13 nm, and the spherical
aberration can be varied within wide limits, even to negative values. The
aberration measurement and the corrector control provide instrument
alignments stable enough for materials science investigations. Analysis of
the contrast transfer with the possibility of tunable spherical aberration
has revealed new imaging modes: high-resolution amplitude contrast,
extension of the point resolution to the information limit, and enhanced
image intensity modulation for negative phase contrast. In particular,
through the combination of small negative spherical aberration and small
overfocus, the latter mode provides the high-resolution imaging of weakly
scattering atom columns, such as oxygen, in the vicinity of strongly
scattering atom columns. This article reviews further lens aberration
theory, the principle of aberration correction through multipole lenses,
aspects for practical work, and materials science applications.
This issue of Microscopy and Microanalysis contains
contributions presented at the Frontiers of Electron Microscopy in
Materials Science (FEMMS) meeting held in Kasteel Vaalsbroek, The
Netherlands, on September 25–30, 2005. Tenth in the series of
biennial conferences, the meeting focused on the latest developments in
the field of advanced instrumentation and application of electron
microscopy in materials science. The international character of this
series of conferences was once again emphasized by the presence of over
140 delegates whose interests include academia, national laboratories, and
industry from 16 countries representing all areas of the globe.
In 1956 Duncumb and Cosslett developed the first imaging method capable of showing the location of elements in a solid with a spatial resolution of a micrometer. This technique was dubbed “X-ray mapping” probably because a separate image was used to show the presence or absence of each element within the field of view. Since its first demonstration, X-ray mapping has become one of the most popular and useful methods of X-ray microanalysis. It has been widely applied in areas of biology, chemistry, physics, geology, environmental science, and materials science.
Cell Biology and Microscopy: A symposium dedicated to the memory of Hans Ris
We at Oxford Instruments were interested to read the article published
in Microscopy and Microanalysis by Newbury (2005). Although our
own views differ from those of Dr. Newbury in some respects, we do agree
that this is an important matter. If this article generates an interest in
the ability of a system and a user to accurately identify elements in a
spectrum and encourages people to assess the quality of the qualitative
analysis provided by a microanalysis system, then we believe this article
has served a very useful purpose. After all, accurate element
identification is the core requirement for a microanalysis system.
We have implemented and tested a new automatic method for the montage
synthesis and three-dimensional (3D) reconstruction of large tissue
volumes from confocal laser scanning microscopy data (CLSM). This method
relies on maximization of the phase correlation between adjacent images.
It was tested on a large specimen (a murine heart) that was cut into a
number of individual sections with thickness appropriate for CLSM. The
sections were scanned horizontally (in-plane) and vertically
(perpendicular to the optical planes) to produce “tiles” of a
3D volume. Phase correlation maximization was applied to the montage
synthesis of in-plane tiles and 3D alignment of optical slices within a
given physical section. The performance of the new method is
evaluated.
Cell Biology and Microscopy: A symposium dedicated to the memory of Hans Ris
I am pleased to respond to the letter from Simon Burgess commenting on
my article, “Misidentification of Major Constituents by Automatic
Qualitative Energy Dispersive X-ray Microanalysis: A Problem That
Threatens the Credibility of the Analytical Community” (Newbury,
2005). First, I am grateful for the words of
support for my article, even if inevitably qualified, expressed in Mr.
Burgess's letter. In response to his specific comments (in boldface),
I offer the following:
This review traces the development of X-ray mapping from its beginning 50 years ago through current analysis procedures that can reveal otherwise obscure elemental distributions and associations. X-ray mapping or compositional imaging of elemental distributions is one of the major capabilities of electron beam microanalysis because it frees the operator from the necessity of making decisions about which image features contain elements of interest. Elements in unexpected locations, or in unexpected association with other elements, may be found easily without operator bias as to where to locate the electron probe for data collection. X-ray mapping in the SEM or EPMA may be applied to bulk specimens at a spatial resolution of about 1 μm. X-ray mapping of thin specimens in the TEM or STEM may be accomplished at a spatial resolution ranging from 2 to 100 nm, depending on specimen thickness and the microscope. Although mapping has traditionally been considered a qualitative technique, recent developments demonstrate the quantitative capabilities of X-ray mapping techniques. Moreover, the long-desired ability to collect and store an entire spectrum at every pixel is now a reality, and methods for mining these data are rapidly being developed.
The aim of this study was to examine the suitability of digital image
analysis, using the KS400 software system, for the morphometric evaluation
of the tissue response after prosthesis implantation in an animal model.
Twenty-four female pigs aged 10 weeks were implanted with infrarenal
Dacron® prostheses for 14, 21, 28, and 116 days. Following the
explantation and investigation of the neointima region, the expression of
beta-1-integrin, the proliferation rate by means of Ki-67 positive cells,
and the intima thickness were evaluated as exemplary parameters of the
tissue response after implantation. Frozen tissue sections were
immunohistochemically stained and subsequently examined using
computer-aided image analysis. A maximum expression of 32.9% was observed
for beta-1-integrin 14 days after implantation, gradually declining over
time to 9.8% after 116 days. The proliferation rate was found to be 19% on
day 14, increasing to 39% on day 21 with a subsequent gradual decline to
5% after 116 days. The intima thickness increased from 189.9 μm on day
14 to 1228.0 μm on day 116. In conclusion, digital image analysis was
found to be an efficient and reproducible method for the morphometric
evaluation of a peri-prosthetic tissue response.
A novel approach for nanoscale imaging and characterization of the
orientation dependence of electromechanical properties—vector
piezoresponse force microscopy (Vector PFM)—is described. The
relationship between local electromechanical response, polarization,
piezoelectric constants, and crystallographic orientation is analyzed in
detail. The image formation mechanism in vector PFM is discussed.
Conditions for complete three-dimensional (3D) reconstruction of the
electromechanical response vector and evaluation of the piezoelectric
constants from PFM data are set forth. The developed approach can be
applied to crystallographic orientation imaging in piezoelectric materials
with a spatial resolution below 10 nm. Several approaches for data
representation in 2D-PFM and 3D-PFM are presented. The potential of vector
PFM for molecular orientation imaging in macroscopically disordered
piezoelectric polymers and biological systems is discussed.
Aberration correctors using hexapole fields have proven useful to
correct for the spherical aberration in electron microscopy. We
investigate the limits of the present design for the hexapole corrector
with respect to minimum probe size for the scanning transmission electron
microscope and discuss several ways in which the design could be improved
by rather small and incremental design changes for the next generation of
advanced probe-forming systems equipped with a gun monochromator.
The design of the microvasculature of cerebellum and nontegmental
rhombencephalic areas was studied in eight adult Acipenser ruthenus L. by
scanning electron microscopy of vascular corrosion casts and
three-dimensional morphometry. Gross vascularization was described and
diameters and total branching angles of parent and daughter vessels of
randomly selected arterial and capillary bifurcations (respectively,
venous mergings) were measured. With diameters ranging from 15.9 ±
1.9 μm (cerebellum; mean ± S.D.) to 15.9 ± 1.7 mm
(nontegmental rhombencephalon; mean ± S.D.) capillaries in
Acipenser were significantly (p ≥ .05) smaller than
in cyclostomes (18–20 μm) but significantly thicker than in
higher vertebrates and men (6–8 μm). With the exception of the
area ratio β (i.e., sum of squared daugther diameters divided by
squared diameter of parent vessel) of the venular mergings in the
nontegmental rhombencephalon, no significant differences (p ≥
.05) existed between the two brain areas. Data showed that arteriolar and
capillary bifurcations and venular mergings are optimally designed in
respect to diameters of parent vessel to daughter vessels and to branching
(merging) angles. Quantitative data are discussed both in respect to
methodical pitfalls and the optimality principles possibly underlying the
design of vascular bifurcations/mergings in selected brain areas of a
nonteleost primitive actinopterygian fish.
Initial results from an ultrahigh-vacuum (UHV) third-order spherical
aberration (Cs) corrector for a dedicated scanning transmission electron
microscopy, installed at the National Institute for Materials Science,
Tsukuba, Japan, are presented here. The Cs corrector is of the dual
hexapole type. It is UHV compatible and was installed on a UHV column. The
Ronchigram obtained showed an extension of the sweet spot area, indicating
a successful correction of the third-order spherical aberration Cs. The
power spectrum of an image demonstrated that the resolution achieved was
0.1 nm. A first trial of the direct measurement of the fifth-order
spherical aberration C5 was also attempted on the basis of a
Ronchigram fringe measurement.
Performing reflection-mode (backscatter-mode) confocal microscopy on
cells growing on reflective substrates gives images that have improved
contrast and are more easily interpreted than standard reflection-mode
confocal micrographs (Keith et al., 1998).
However, a number of factors degrade the quality of images taken with the
highest-resolution microscope objectives in this technique. We here
describe modifications to reflection-enhanced backscatter confocal
microscopy that (partially) overcome these factors. With these
modifications of the technique, it is possible to visualize structures the
size—and refractility—of individual microtubules in intact
cells. Additionally, we demonstrate that this technique, in common with
fluorescence techniques such as standing wave widefield fluorescence
microscopy and 4-Pi confocal microscopy, offers improved resolution in the
Z-direction.
Electron-excited X-ray mapping is a key operational mode of the scanning electron microscope (SEM) equipped with energy dispersive X-ray spectrometry (EDS). The popularity of X-ray mapping persists despite the significant time penalty due to the relatively low output count rates, typically less than 25 kHz, that can be processed with the conventional EDS. The silicon drift detector (SDD) uses the same measurement physics, but modifications to the detector structure permit operation at a factor of 5–10 times higher than conventional EDS for the same resolution. Output count rates as high as 500 kHz can be achieved with 217 eV energy resolution (at MnKα). Such extraordinarily high count rates make possible X-ray mapping through the method of X-ray spectrum imaging, in which a complete spectrum is captured at each pixel of the scan. Useful compositional data can be captured in less than 200 s with a pixel density of 160 × 120. Applications to alloy and rock microstructures, ultrapure materials with rare inclusions, and aggregate particles with complex chemistry illustrate new approaches to characterization made practical by high-speed X-ray mapping with the SDD.Note: The Siegbahn notation for characteristic X-rays is commonly used in the field of electron beam X-ray spectrometry and will be used in this article. The equivalent IUPAC notation is indicated in parentheses at the first use.In this article, the following arbitrary definitions will be used when referring to concentration (C) ranges: major: C > 0.1 (10 wt%), minor: 0.01 ≤ C ≤ 0.1 (1–10 wt%), and trace: C < 0.01 (1 wt%).