Obtaining high
resolution data from a large volume of brain tissue in an
automated and reliable process
By Christel
Genoud, Gatan
Morphometry is an important and growing discipline
within neuroscience. Theoretical models of neuronal circuits
require 3D information over extensive volumes. Current models
are based on real data obtained from serial sectioning brain
tissue and subsequent reconstruction to show components present,
for example synapses, axons, dendrites. Realistic and meaningful
analysis requires morphometric analysis at the ultrastructural
level over large sample volumes. Large volumes are required
in order to be statistically relevant and usable for model
building.
Electron microscopy is key to providing information
at the ultrastructural level.
Until now, the classical method to obtain
such data was serial sections collected on grids and observed
in the TEM. This is a long and difficult process requiring
much skill. Sections are obtained as ribbons using an ultra-microtome.
Ribbons must be divided manually. Multiple sections are then
collected on grids using the surface tension of water near
the diamond knife. Sections on grids are processed in various
chemicals. All these steps are risky as the grids or sections
can be broken. Only one broken grid compromises the entire
series of sections because it introduces an important gap
in the series.
A revolutionary solution called 3View, from
Gatan, uses serial block face scanning electron microscopy
(SBFSEM). This new method automates the cutting and imaging
of the specimen. Grids are no longer used because sections
are not cut for collection. It is the block of tissue itself
that is directly introduced inside the scanning electron microscope
and its surface is repeatedly shaved and scanned in order
to obtain a stack of aligned images. The raw images obtained
can be directly exported to software for reconstruction and
quantification. Image stack alignment is due to the inherent
design and stability of the system and typically does not
require software post-processing. The following article will
describe the main steps necessary to obtain this kind of data.
Case study: imaging ~ 10,000 synapses
in a volume of mouse cortex using 3View.
1. Tissue processing
Like any microscopy technique optimum results,
especially spatial resolution in 3D, are often achieved by
following certain protocols. In the case of 3View specimen
preparation, two key considerations are the level of contrast
shown by the specimen, and the resilience of the embedding
resin to the electron beam radiation. For a given specimen,
higher image contrast is achieved by increasing experimental
variables such as the beam energy and the number of injected
electrons per pixel point. However, such higher injection
conditions have other detrimental effects on the specimen
and imaging quality, for example the cutting quality, additional
scattering associated with the gas required to compensate
the injected charge, as well as the depth resolution of the
3D data. For this reason, a specimen optimised to give the
highest possible 3D resolution data whilst minimizing the
acquisition timeframe, is one with high contrast in the tissue,
and embedded in a medium relatively resistant to electron
beam damage. In this particular case, after fixation, the
tissue has been postfixed in osmium tetroxide with ferrocyanide.
In a further step, uranyl acetate has been used to enhance
the contrast of some organelles. Epoxy based resins (e.g.
epon, durcupan) are superior and in this case the resin used
was durcupan.
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Figure 1 Contrast and resin optimization.
The tissue has been processed following a protocol
with high osmium content.. This image is 2048x2048
pixels with each pixel being 12nm square.
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2. Immunohistochemistry
3View is a technique compatible with immunohistochemistry.
However, only pre-embedding techniques are suitable because
SBFSEM is not based on the observations of sections but on
the imaging of the block face. The pre-embbeding method used
in this case study of a mouse cortexis described. Once the
tissue is fixed, it is cut into thick sections and a protein
antibody called parvalbumine is employed. Parvalbumine is
known to be specific to a subset of inhibitory neurons in
the cortex and its presence is used in the classification
of the inhibitory interneurons of the cortex. The secondary
antibody is biotinilated and DAB is used for staining. Following
the DAB staining, tissue is processed with a classical embedding
protocol. It is important to ensure penetration of the antibody
inside the tissue. If the aim is to follow a labelled structure,
one must check that the labelling is not restricted to the
surfaces of the section but has penetrated through all the
section.
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Figure 2 Example of pre-embedding labelling visualised
with 3View. The tissue has been processed for immunochemistry
with DAB staining. This image shows a section through
the apical dendrite of a cortical neuron. A protruding
spine making a synapse is visible.
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3. Trimming of the block
Once embedded, the tissue should be trimmed before being inserted
in the 3View microtome. The piece of tissue to be observed
is glued on the top of a specimen holder specific to 3View.
In this example, the specimen has been trimmed to obtain a
rectangular or trapezoidal surface of approx 300x400 microns.
Two sides are parallel and are trimmed at 45 degrees. The
2 other sides are trimmed at 90 degrees. When tissue is stained,
it is important to trim the pyramid in order to centre the
labelled structure on the pyramid. Specimen preparation including
block trimming is advised because it can influence the stability
of the stacks, especially when automated cuts of extensive
acquisition times are required.
4. Setting of the microscope
Once the sample is ready to be cut, it is placed on the 3View
ultramicrotome. The 3View ultramicrotome is already attached
to the door of the SEM and can be operated out of the chamber.
In this open configuration of the microscope, a binocular
optical microscope can be adjusted on the door and the sample
set relative to the diamond knife. This is made convenient
via a camera fixed on the optical microscope. When the sample
has been adjusted with respect to the diamond knife, the door
is closed and the SEM evacuated. The face of the block is
now positioned just below the pole piece of the SEM.
5. Cutting and image acquisition
All the cutting and acquisition parameters are entered into
Gatan’s DigitalMicrograph software. Settings are chosen
in order to fit the magnification and speed of scanning with
the field of view and the resolution required. The focus is
adjusted at the same time and is then valid for the entire
acquisition session.
Detection is via a backscattered electron detector (BSED)
, designed especially for low kV work on biological specimens.
The cutting and imaging process is based on the repetition
of the following steps:
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- The specimen is raised |
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- The diamond knife shaves the surface and then moves
away |
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- Imaging the freshly cut block face
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The advantages are the following:
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- The block is stable so it is always the same field
of view that is scanned and in focus. Hence all images
are aligned at the time of acquisition. |
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- The upwards movement of the block sets the depth of
shaving of the surface. It was set to 50 nm in this case
but this can be adjusted according to requirements. |
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- The cutting and imaging processes are automatic and
do not require attendance near the microscope during the
session. The system can typically work overnight. |
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- A file of images (image ‘stack’) is obtained
that is directly exportable to software for analysis and
reconstruction. |
This illustration is based on 800 sections
obtained in approx 14 hours. The parameters have been chosen
in order to have a field of view of 20 by 20 microns with
a voxel size of 10x10x50 nm showing entire cell bodies of
neurons as well as the synapses present on them. 800 sections
x 50nm means that 40 microns of depth in the tissue has been
cut and can be sequentially seen in Digital Micrograph
With this acquisition, the identification
of ~ 10,000 synapses present in the volume of tissue investigated
would be possible (Rodney et al, 2004).
6. Three dimensional (3D) visualisation
and rendering
Alignment allows projection in all axes and
visualisation in all desired planes. Gatan can provide an
additional tool called the DigitalMicrograph 3D Visualisation
Tool, allowing 3D visualisation as well as 3D automatic rendering
from any image stack. With this tool, the stacks can be visualised
as volumes and can be rotated, projected on all the different
axes and sliced through. Examples are shown in figure 3.
Figure 3 Examples of 3D visualisation possible with the
Gatan Visualisation Tool. This module allows visualisation
in different planes
7. Image exportation and reconstruction
In this case study, images have been exported and saved in
TIFF format in an ascending numerical order. The TIFF images
were opened in the reconstruction software and a manual segmentation
of a neuron present in the images performed (figure 4) as
well as identification of the synapses. Because the tissue
is labelled for parvalbumin, we can determine which of the
synapses are made with inhibitory interneurons expressing
parvalbumin.
Figure 4 Example of reconstruction
software (Reconstruct, GNU General public licence version
2) showing an image from the stack with the neuron of interest
manually segmented. The window on the right shows the superposition
of all the traces done and the scaffold of the neuron. This
scaffold of traces is converted by the software into a volume
having a homogeneous surface allowing our eyes to visualise
a structure in 3D.
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Gatan
Inc. Corporate Headquarters, 5933 Coronado Lane, Pleasanton,
CA 94588
Tel. (925) 463 0200 Fax. (925) 463 0204
Contact: info@gatan.com
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