Imaging of early conifer embryogenic tissues with the environmental scanning electron microscope

This article describes the usage of non-commercial environmental scanning electron microscope (ESEM) for the visualization of plant extracellular matrix in Abies alba and Abies numidica. Non sputter-coated samples free of using the common fixation technique observed at the relatively low humidity of the air environment with the pressure 550 Pa and the low temperature of the sample from −18 to −22°C give surprisingly very good results that show the natural structure of the tissues. This seems to be generally applicable. Moreover, a specially designed ionization detector of secondary electrons and a YAG:Ce³⁺ detector of backscattered electrons were used for better comparison.     

Paraneuronal pseudobranchial neurosecretory cells in scorpion catfish Heteropneustes fossilis: an environment scanning electron microscope and transmission electron microscope study

Yadav, L., Sengar, M., Zaccone, D. and Gopesh, A. 2011. Paraneuronal pseudobranchial neurosecretory cells in scorpion catfish Heteropneustes fossilis: an environment scanning electron microscope and transmission electron microscope study. —Acta Zoologica (Stockholm) 00 : 1–8. Pseudobranchial neurosecretory system (PNS), found in the gill region of certain groups of teleosts, falls under the category of the ‘diffuse neuroendocrine system’ (DNES). The cells belonging to the system share morpho‐functional features with the paraneuronal cells observed in respiratory tract and airway surfaces of higher vertebrates. On the basis of the experimental observations, a role in condition of hypoxia has been recorded for this system. In an attempt to elucidate the ultrastructure of pseudobranchial neurosecretory cells, present investigation was undertaken using environment scanning electron microscope (ESEM) and TEM in an air‐breathing catfish, Heteropneustes fossilis. The external morphology of PNS under ESEM appeared as a mass of cells supplied with nerves and blood capillaries. Each cell mass is made up of numerous pear‐shaped neurosecretory cells, confirmed by neurosecretion‐specific acid violet stain. The TEM investigation of the cells revealed the presence of different sizes of dense‐cored vesicles in the cytoplasm, which was observed as granular cytoplasm under light microscope. Presence of large number of mitochondria in the cytoplasm confirmed active involvement of these cells in the physiology of fishes. Although lacuna prevails regarding the exact function of this system of fish, its probable role in hypoxic condition and surfacing behavior are speculated.     

Scanning electron microscope histochemistry: The use of backscattered electrons to identify epidermal Langerhans cells in the scanning electron microscope

Summary Epidermal sheets reacted for ATPase were examined in the scanning electron microscope and images based on atomic number contrast formed by collecting the backscattered electrons. Langerhans cells lying within the tissue were revealed and could be related to surface structures by reference to conventional secondary electron images.     

Dimensional changes in cells and tissues during specimen preparation for the electron microscope

Studies on dimensional changes incurred during preparation of tissue specimens for the transmission and scanning electron microscopes are reviewed, with emphasis on quantitative measurements pertinent to morphometry and three-dimensional reconstruction. The scope of the review includes fixation, dehydration, plastic embedment, critical-point drying, and freeze-drying. Recommendations are presented for monitoring dimensional changes; a strategy for the choice of method of specimen preparation is outlined.     

Dimensional changes in cells and tissues during specimen preparation for the electron microscope.

Studies on dimensional changes incurred during preparation of tissue specimens for the transmission and scanning electron microscopes are reviewed, with emphasis on quantitative measurements pertinent to morphometry and three-dimensional reconstruction. The scope of the review includes fixation, dehydration, plastic embedment, critical-point drying, and freeze-drying. Recommendations are presented for monitoring dimensional changes; a strategy for the choice of method of specimen preparation is outlined.     

Ultrastructure of human spleen in transmission and scanning electron microscope

Despite new information concerning functional morphology of spleen, there are still some inaccuracies mostly regarding the spleen blood circulation. Billroth’s (splenic) cords are formed from three-dimensional network of fibroblastic reticular cells located among branched sinuses. Results from our study using scanning electron microscopy confirm an intimate contact between adjacent reticular cells and erythrocytes. Arterial terminals can be observed in the Billroth’s cords. The wall of sinuses reminds a sieve and it is lined with a special type of endothelium. In electron microscope, endothelial cells look like rods oriented parallel to the longitudinal axis of sinuses. Based on our observations fibroblastic reticular cells change to fixed phagocytes under no circumstances, hence they do not participate in phagocytosis. They may have a recognition function for cells circulating around them. According to our opinion, the open and the closed blood circulation are present in the human spleen simultaneously. Blood flowing in the closed circulation can help “absorption” of extra-vascular liquid and the blood elements into the vascular lumen. Due to sporadic occurrence of smooth muscle cells in the capsule and trabeculae, we assume that human spleen is not a blood reservoir, unlike the spleen in some other animals.     

Serial section scanning electron microscopy (S3EM) on silicon wafers for ultra-structural volume imaging of cells and tissues

High resolution, three-dimensional (3D) representations of cellular ultrastructure are essential for structure function studies in all areas of cell biology. While limited subcellular volumes have been routinely examined using serial section transmission electron microscopy (ssTEM), complete ultrastructural reconstructions of large volumes, entire cells or even tissue are difficult to achieve using ssTEM. Here, we introduce a novel approach combining serial sectioning of tissue with scanning electron microscopy (SEM) using a conductive silicon wafer as a support. Ribbons containing hundreds of 35 nm thick sections can be generated and imaged on the wafer at a lateral pixel resolution of 3.7 nm by recording the backscattered electrons with the in-lens detector of the SEM. The resulting electron micrographs are qualitatively comparable to those obtained by conventional TEM. S(3)EM images of the same region of interest in consecutive sections can be used for 3D reconstructions of large structures. We demonstrate the potential of this approach by reconstructing a 31.7 μm(3) volume of a calyx of Held presynaptic terminal. The approach introduced here, Serial Section SEM (S(3)EM), for the first time provides the possibility to obtain 3D ultrastructure of large volumes with high resolution and to selectively and repetitively home in on structures of interest. S(3)EM accelerates process duration, is amenable to full automation and can be implemented with standard instrumentation.     

Identification of cells by backscattered electron imaging of silver stained bulk tissues in scanning electron microscopy

Anuran tadpole tail muscle was stained en bloc by a modified light microscope silver stain for light microscopy and freeze-fractured in liquid nitrogen after partial dehydration with ethanol. The fractured specimens were observed in both secondary electron and backscattered electron modes in a scanning electron microscope. Since the cell nuclei specifically stained with silver provided high contrast against the unstained background due to atomic number contrast of backscattered electron image, various cells were easily identified by a comparison of secondary electron images and compositional images of backscattered electron signals.     

A simple method for scanning electron microscope preparation of cells grown in multiwell culture plates

The closeness of wells in multiwell tissue culture plates makes it difficult to remove individual ones without distributing the adjacent wells. Moreover, critical point drying frequently introduces artifact into the culture monolayer grown on plastic substrate. These problems make it difficult to process such cultures for scanning electron microscopy. However, for cell kinetic and correlative morphological studies on primary cultures derived from 7,12-dimethylbenz(alpha)anthracene(DMBA)-induced mammary tumors, we have found that Falcon 24-well tissue culture plates are excellent for maintenance of cells and are convenient to use. By plating the cells in alternating, diagonally disposed wells and while the cells are still in the buffer, individual wells can be cut from a multiwell plate without disturbing the cells in adjacent wells. The isolated wells can be used to carry out scanning electron microscope preparation. The height of the well is reduced with a scalpel prior to critical point drying; the remaining well is useful as a handle in mounting the dried sample to stubs for subsequent coating and viewing. Critical point drying and coating of monolayer samples on Falcon plastic are described. The results do not suggest that any artifacts are introduced in our preparations.     

Myofibrillogenesis in vitro as seen with the scanning electron microscope

The present study describes an experimental approach whereby myofibrillogenesis and the three-dimensional arrangement of myofibrils present within cultured skeletal muscle cells can be examined using the scanning electron microscope. This procedure uses cells that have been cultured on gold-coated coverslips, and treated with Triton X-100 to extract the cell membrane and the soluble cytoplasm. Subsequent electroconductive staining by treatment with thiocarbohydrazide and osmium allows the myofibrils to be visualized. The images of myofibrils in various states of development observed by this method generally accords to those previously reported by transmission electron microscopy. Cell elongation and adhesion to the substrate causes mechanical stress from different directions which meet at branchings of the cultured myotubes. Many myofibrils are observed to run in the direction of the inferred stress lines.     

Improved coating and fixation methods for scanning electron microscope autoradiography

A simple apparatus for emulsion coating is described. The apparatus is inexpensive and easily assembled in a standard glass shop. Emulsion coating for scanning electron microscope autoradiography with this apparatus consistently yields uniform layers. When used in conjunction with newly described fixation methods, this new approach produces reliable autoradiographs of undamaged specimens.     

Immunospecific labeling of mouse lymphocytes in the scanning electron microscope

Bone marrow-derived (B) and thymus-derived (T) Balb/c mouse lymphocytes were identified in the scanning electron microscope (SEM) by the immunospecific attachment of one of several kinds of large-molecular-weight markers distinguishable in SEM. These markers (tobacco mosaic virus, keyhole limpet hemocyanin, bushy stunt virus, and bacteriophage T4) could be modified with hapten groups and linked with anti-hapten antibody, in an indirect (sandwich) scheme, to hapten-modified anti-cell-surface antibody bound to the cell surface. Hapten-modified antibodies to B cell antigens (goat anti-mouse-immunoglobulin) or to T cell antigens (rabbit anti-mouse brain) were employed to identify these two lymphoid cell types in unfractionated spleen, mesenteric lymph node, bone marrow, and thymus cell populations. The topography of B cells was always indistinguishable from that of T cells. No surface features were found to be unique to either cell type. In suspension, the majority of B and T cells had one or no microvilli regardless of the tissue source of the labeled cells. Cells in suspension that had microvilli (usually 10% of the total cell population) were always unlabeled. However, after cell contact with a glass surface, approximately half of both the B and T cell populations had a villous topography.