A technique for quick fixation of whole Drosophila and other small insects for scanning electron microscopy

A procedure for fixing small insects in natural postures for scanning electron microscopy is reported. Anesthetized insects are partially restrained using a depression slide and a coverslip while preliminary fixation is carried out and wings and legs are positioned with a fine brush. Following this, fixation is completed and the insect is prepared for scanning electron microscopy by essentially standard procedures, which may include critical point drying. Figures illustrate, however, that critical point drying is not necessary for more rigid parts of the exoskeleton. Use of this procedure assures naturally disposed parts even when only a single specimen is available.     

A New Method Using Hexamethyldisilazane for Preparation of Soft Insect Tissues for Scanning Electron Microscopy

A new rapid procedure for preparing soft internal tissues from insects that allows air drying was found to compare favorably with tissues prepared by critical point drying. In the new procedure, tissues were fixed in 1% glutaraldehyde, dehydrated through a graded ethanol series, immersed in hexamethyldisilazane (HMDS) for 5 minutes, and air dried. Tissues prepared by both the HMDS treatment and by critical point drying were coated with gold for scanning electron microscopy. Tissues prepared by the HMDS treatment did not shrink or distort upon air drying and excellent surface detail was preserved. The HMDS treatment required about 5 minutes, whereas the critical point drying procedure required about 1.5 hours.     

On processing field and culture samples of desmids (Desmidiales,chlorophyta) for scanning electron microscopy

A procedure is outlined for preparing both field collected and laboratory grown desmid populations for scanning electron microscopy which avoids the use of the potentially hazardous chemicals glutaraldehyde and osmium tetroxide and reduces preparation time substantially. FAA is utilized both in fixation and mucilage removal, and living material can be prepared for critical point drying in as little as 90 min. Limitations of this procedure are outlined briefly and the use of SEM material in systematic studies is commented upon.     

A new method using hexamethyldisilazane for preparation of soft insect tissues for scanning electron microscopy

A new rapid procedure for preparing soft internal tissues from insects that allows air drying was found to compare favorably with tissues prepared by critical point drying. In the new procedure, tissues were fixed in 1% glutaraldehyde, dehydrated through a graded ethanol series, immersed in hexamethyldisilazane (HMDS) for 5 minutes, and air dried. Tissues prepared by both the HMDS treatment and by critical point drying were coated with gold for scanning electron microscopy. Tissues prepared by the HMDS treatment did not shrink or distort upon air drying and excellent surface detail was preserved. The HMDS treatment required about 5 minutes, whereas the critical point drying procedure required about 1.5 hours.     

Conditions critical for optimal visualization of bacteriophage adsorbed to bacterial surfaces by scanning electron microscopy.

The potential of scanning electron microscopy as a tool for the detection of viruses on cell surfaces has been studied using bacteriophage P1 adsorbed to Shigella dysenteriae as a model system. Viral particles were readily detectable by scanning electron microscopy on the surface of infected cells which were fixed with glutaraldehyde followed by postfixation in OsO4 and prepared by critical point drying. The virus-studded surface of the infected cells differed markedly from the relatively smooth surfaces of uninfected control cells. Examination of the same preparations with transmission electron microscopy revealed numerous viral particles adsorbed to the surfaces of infected cells, whereas the control cells were free of viruses as expected. Glutaraldehyde fixation alone did not preserve the surface detail of infected cells: cells adsorbed with viruses were not distinguishable from control cells by scanning electron microscopy although by transmission electron microscopy viruses could be visualized. Air drying from water or absolute alcohol resulted in unsatisfactory preservation as compared to the appearance of infected cells prepared by the critical point method. Thus, scanning electron microscopy is capable of resolving viral particles on cell surfaces, but detection of these particles is completely dependent both on the method of fixation and on the technique of drying used.     

Vapor Fixation of Intractable Fungal Cells for Simple and Versatile Scanning Electron Microscopy

Imaging of exudation of conidia from fruiting bodies by scanning electron microscopy is challenging because of the difficulty in achieving specimen fixation that enables conidia to be immobilized from fruiting bodies. Conidia in chains borne on conidiophores are readily dissipated on coming in contact with liquid fixatives before fixation becomes effective. Two phialide‐forming fungi including Aspergillus and Penicillium species, and a pycnidium‐forming fungus Fusicoccum species were subjected to a vapor fixation procedure for scanning electron microscopy rather than conventional immersion fixation procedures. The intractable fungi were exposed to the vapor of 2% glutaraldehyde and 2% osmium tetroxide each for at least 2 h, subsequently followed by gold coating. Through the vapor fixation, excellent retention of conidial chains in phialides was achieved in this study. It appeared that conidial masses from pycnidia were usually held together in globose to oval drops. The simple vapor fixation procedure for preserving delicate fungal cells could be widely used for routine applications to facilitate morphological characterization of diverse plant pathogenic fungi as they are in ex planta ecological niches during the saprophytic phase as well as in host parts during the parasitic phase.     

A Comparison of Techniques Useful for Preparing Nematodes for Scanning Electron Microscopy

Second-stage juveniles of Meloidogyne incognita were prepared by several different techniques for scanning electron microscopy (SEM). Sequential fixation in the cold (4-8 C) was superior to rapid fixation at room temperature, glutaraldehyde and glutaraldehyde-formalin were better fixatives than formalin alone, and critical point drying with carbon dioxide or Freon gave similar results that were only slightly better than air drying with Freon. Freeze drying sequentially fixed nematodes from 100% ethanol in liquid propane produced the best preserved specimens with the fewest artifacts. Specimens of various free-living and plant-parasitic nematodes were prepared for SEM by freeze drying. This technique was adequate for most genera but unsatisfactory for a few. Although each genus may require a different procedure for optimum preservation of detail, sequential fixation with glutaraldehyde and freeze drying are comparable and often superior to commonly used techniques for preparing nematodes for SEM.     

Improved Procedures for Electron Microscopic Visualization of the Cytoskeleton of Cultured Cells

We have developed an improved electron microscopic procedure appropriate for correlative light and electron microscopy of the cytoskeleton. The procedure is based on detergent extraction, chemical fixation, critical point drying, and platinum/carbon coating of cultured cells and the improvements consist of modifications which are minor individually but collectively of substantial impact. They are: inclusion of polyethylene glycol into the extraction medium; cell lysis at room temperature; fixation by sequential application of glutaraldehyde, tannic acid, and uranyl acetate; horizontal position of specimens during dehydration and drying; and uranyl acetate treatment during dehydration. As a result, we have obtained a greatly improved quality of electron microscopic images together with a high consistency of results. Long and straight actin filaments were clearly seen in stress fibers and newly formed lamellipodia. Their polarity was distinctly revealed by decoration with myosin subfragment 1. Depletion of actin from cytoskeletons by gelsolin treatment allowed for better visualization of myosin, intermediate filaments, and microtubules. Intermediate filaments exposed by this treatment exhibited numerous side projections in a hitherto unreported millipede-like appearance. The suggested procedure was compatible with immunogold labeling as demonstrated with an antibody to tubulin. Correlative light and electron microscopy of cells microinjected with a fluorescent derivative of myosin II was reliable and efficient, producing a close resemblance between the two kinds of images.     

Scanning electron microscopy preparation protocol for differentiated stem cells

The lack of an established protocol for scanning electron microscopy (SEM) studies on stem cells differentiating into adipogenic lineage led us to develop a protocol for the preparation of differentiated adult bone marrow-derived mesenchymal stem cells (BMSC) for SEM. This protocol describes the procedure to maintain and preserve the structural organization of cellular components following differentiation, for morphological and physical characterization. The fixation of the differentiated cells was followed by dehydration using methanol, and vacuum desiccation before microscopy. The use of longer chain alcohols as dehydrating agents was avoided in our method to reduce the dissolution of lipid deposits in cells, thus allowing the maintenance of their structural integrity. The time period for the processing of samples was reduced by avoiding the osmium tetroxide postfixation and critical point drying. Thus, this protocol helps in determining the potential, fate, and degree of stem cell differentiation. This may be useful for SEM analysis of differentiated cells, especially those grown on various scaffolds.     

A simplified method for preparing rotifer trophi for scanning electron microscopy

A simple, quick technique for the preparation of rotifer trophi for scanning electron microscopy is described. The method permits visual monitoring of the extraction process and does not require critical point drying of the specimens. Micrographs showing fine, structural detail of the hard parts of the mastax of representatives of the following genera are presented:Asplanchna, Conochilus, Filinia, Hexarthra, Keratella, Proalides, Synchaeta, andTrichocerca.     

A method for preservation of soft tissues of marine teleosts for scanning electron microscopy

Soft, internal tissues of marine teleosts have been preserved for scanning electron microscopy in 2% glutaraldehyde in half-strength flounder saline; the osmolality of this fixative approximated the plasma osmolality of marine teleosts. Fixation was followed by washing, dehydration and Freon critical point drying. This procedure has revealed surface features of renal tubules of Anoplogaster and swimbladder of Melanonus     

Methods for imaging Shewanella oneidensis MR-1 nanofilaments

Nanofilament production by Shewanella oneidensis MR-1 was evaluated as a function of lifestyle (planktonic vs. sessile) under aerobic and anaerobic conditions using different sample preparation techniques prior to imaging with scanning electron microscopy. Nanofilaments could be imaged on MR-1 cells grown in biofilms or planktonically under both aerobic and anaerobic batch culture conditions after fixation, critical point drying and coating with a conductive metal. Critical point drying was a requirement for imaging nanofilaments attached to planktonically grown MR-1 cells, but not for cells grown in a biofilm. Techniques described in this paper cannot be used to differentiate nanowires from pili or flagella.     

Use of a Tissue Sectioner to Expose Internal Structures of Biological Samples for Scanning Electron Microscopy

A procedure yielding sections of unembedded biological samples for observation by scanning electron microscopy is described. Sections of samples, fixed and hardened in OsO₄, were obtained in quantity with a tissue sectioner. Subsequent treatments to osmium-coat cut surfaces were employed prior to critical point drying. The procedure yields cleanly cut surfaces through cells and cytoplasmic organelles which are retained in their normal position. Sections of apple leaf and mouse kidney are illustrated. Sections can be readily cut in a desired plane with less structural damage than is typically encountered by other sectioning or dissection techniques.     

Use of a tissue sectioner to expose internal structures of biological samples for scanning electron microscopy.

A procedure yielding sections of unembedded biological samples for observation by scanning electron microscopy is described. Sections of samples, fixed and hardened in OsO4, were obtained in quantity with a tissue sectioner. Subsequent treatments to osmium-coat cut surfaces were employed prior to critical point drying. The procedure yields cleanly cut surfaces through cells and cytoplasmic organelles which are retained in their normal position. Sections of apple leaf and mouse kidney are illustrated. Sections can be readily cut in a desired plane with less structural damage than is typically encountered by other sectioning or dissection techniques.     

A Simple Drying Method for Field Emission Scanning Electron Microscopy for Chromosomes

Hexamethyldisilazane treatment and subsequent air drying of spread plant chromosomes is compared with critical point drying. The two procedures are equivalent for preparing chromosomes for examination by field emission scanning electron microscopy at low voltage.     

Preparation techniques for the electron microscopy of granular sludge from an anaerobic digester

Several fixation and dehydration techniques for scanning and transmission electron microscopy of glycocalyx and microbial populations within granules from an upflow anaerobic sludge blanket digester purifying a brewery wastewater were compared. Sputter-cryo and freeze-drying techniques prior to scanning electron microscopy (SEM) allowed viewing of the glycocalyx. In contrast standard fixation and dehydration techniques were suitable for examination of underlying microbial populations by both SEM and transmission electron microscopy.     

Correlation of Scanning and Transmission Electron Microscopy on the Same Tissue Sample

Tissue processed for scanning electron microscopy (SEM) in a critical point bomb utilizing Freon-13 showed excellent subsurface preservation when prepared for transmission electron microscopy (TEM). The critical point method is the only commercially available SEM preparation technique in which the quality of preservation will not limit microscopists in efforts to correlate SEM and TEM observations.     

Structure of the endothelium of the thoracic and abdominal aorta of intact rats studied by various methods of preparation and handling of the specimens

By means of scanning and transmissive electron microscopy structural peculiarities of endothelium of the thoracic and abdominal parts of the intact rat aorta have been studied at various regimens of preparation and making specimens . The greatest changes endotheliocytes (EC) undergo at using immersion fixation after dissection of the aortal segments. These changes are less pronounced at immersion fixation in situ. A decreased perfusion pressure results in appearance of intimal folds and microfolds on the surface of EC. Increasing time for washing more than 1 min results in appearance of inflations and craters on the surfice of EC. For analysis by means of transmissive electron microscopy it is not necessary to remove blood completely out of the vascular bed. The most essential factor is to maintain perfusion pressure at the average systolic level in the given area of the vessel. However, to make the analysis by means of scanning electron microscopy this method is not suitable. The most optimal condition for initial stages of preparing vessels for morphological investigation is their washing for 1 min in the medium 199 with addition of heparin (10 units/ml) during no more than 1 min with a subsequent perfusive fixation in 2.5% solution of glutaraldehyde in the medium 199 no less than 5 min under the average arterial pressure in the given area of the vessel.     

Comparison between direct methods for determination of microbial cell volume: electron microscopy and electronic particle sizing.

Size frequency distributions of different phototrophic and heterotrophic microorganisms were determined by means of scanning and transmission electron microscopy and electronic particle sizing. Statistically significant differences existed among the three techniques used in this study. Cells processed for electron microscopy showed lower mean cellular volumes than those processed for electronic particle sizing, reflecting a shrinkage by factors ranging from 1.1 to 6.2 (mean, 2.3). Processing of cells for scanning electron microscopy caused higher shrinkage than processing for transmission electron microscopy. Shrinkage was dependent neither on the size nor on the cell wall type of the microorganism. When processed for scanning electron microscopy, phototrophic bacteria were strongly shrunken, whereas heterotrophic microorganisms were less affected. A direct relationship existed among phototrophic bacteria between percentage of shrinkage and specific pigment content. This was probably a consequence of the pigment extraction by organic solvents during the dehydration process, previous to the critical point drying, necessary to examine the specimens under the scanning electron microscope.     

Ultrastructural study of the internal organs of ixodid ticks in the scanning electron microscope

The structure of the surfaces of midgut and salivary glands in hungry and engorged females of Hyalomma asiaticum was studied by means of scanning electron microscopy. Preparations were fixed in glutaraldehyde osmium and then dehydrated by the critical point method and gold or platinum coating Different periods of fixation at room temperature or at 4 degrees C did not affect the condition of surface structures of gut and salivary glands.