A synchrotron X-ray study of the changes occurring in the corneal stroma during processing for electron microscopy

Using a high-intensity synchrotron X-ray source, the structural changes occurring in the corneal stroma were monitored during each stage of several different processing runs for the transmission electron microscope (TEM) and scanning electron microscope (SEM). The parameters studied were interfibrillar spacing, intermolecular spacing, D-periodicity and fibril diameter. The processing schedule that produced the least changes in spacings for TEM specimens involved extended fixation in glutaraldehyde followed by low-temperature embedding in Lowicryl K4M resin. However, interfibrillar material was better preserved after embedding in LR White resin or Nanoplast. Almost every processing stage for electron microscopy produced significant changes in one or more structural parameters in the cornea. Glutaraldehyde fixation significantly increased the intermolecular spacings, while resin infiltration and resin polymerization each resulted in shrinkage of all the spacings monitored. Critical-point drying for SEM specimens resulted in considerable shrinkage in all three spacings, but was still preferable to air drying, which caused reduction in the order of the fibril packing, resulting in loss of the interfibrillar X-ray pattern. Perhaps the most drastic effect was caused by post-fixation in osmium tetroxide, which resulted in loss of the intermolecular pattern, and also increased the amount of shrinkage in the interfibrillar spacings and the D-periodicity which occurred during later stages of processing.     

Assessment of collagen fibril spacing in relation to selected region of interest (ROI) on electron micrographs--application to the mammalian corneal stroma

AIMS: To evaluate measurements of collagen fibril spacing using different shaped regions of interest (ROI) on transmission electron micrograph (TEM) images of rabbit corneal stroma. METHODS: Following glutaraldehyde fixation and phosphotungstic acid staining, TEM images of collagen fibrils in cross section were projected at a final magnification close to 250,000 × to obtain overlays. Interfibril distances (IFDs; center‐to‐center spacing) were measured within different ROIs of the same nominal area (0.25 μm²) but different shape (with the length to width, L:W, ratio from 1:1 to 6:1). The IFD distribution was analyzed, and the 2D organization assessed using a radial distribution analysis. RESULTS: The fibrils had an average diameter of 35.3 ± 3.8 (SD) nm, packing density of 393 ± 4 fibrils / μm² and a fibril volume fraction of 0.39 ± 0.02. IFDs ranged from 29 to 1400 nm depending on the shape of the ROI, with average values ranging from 263 to 443 nm. By artificially selecting IFD data only to a radial distance of 250 nm, the average IFDs were just 145–157 nm. The radial distributions, to 250 nm, all showed a nearest neighbors first peak which shifted slightly from predominantly at 45–54 nm with more rectangular ROIs. The radial distribution profiles could be shown to be statistically different if the ROI L:W ratio was 2:1 or greater. CONCLUSION: Selection of an ROI for assessment of packing density and interfibril distances should be standardized for comparative assessments of TEMs of collagen fibrils. Microsc. Res. Tech., 2011. © 2011 Wiley‐Liss, Inc.     

Cornea and its adaptation to environment and accommodation function in veiled chameleon (Chamaeleo calyptratus): ultrastructure and 3D transmission electron tomography

We investigate the ultrastructural features and 3D electron tomography of chameleon (Chamaeleon calyptratus) which is a native of desert environments of Saudi Arabia. The corneas of the chameleon were fixed in 2.5% glutaraldehyde containing cuprolinic blue in sodium acetate buffer for electron microscopy and tomography, and observed under a JEOL 1400 transmission electron microscope. The thin cornea (21.92 μm) contained 28–30 collagen fibril lamellae. The middle stromal lamellae (from 13 to 19) contained keratocytes with a long cell process and filled with granular material. The CF diameter increased from lamella 1 (30.44 ± 1.03) to Lamella 5 (52.83 ± 2.00) then decreased towards the posterior stoma. The percentage of large CF diameters (55–65 nm) was very high in the lamellae L14 (38.8%) and L15 (85.7%). The mean PGs area of the posterior stroma (448.21 ± 24.84 nm²) was significantly larger than the mean PGs area of the anterior, (309.86 ± 8.2 nm²) and middle stroma 245.94 ± 8.28 nm²). 3D electron tomography showed the distribution of PGs around and over the CF. Variable diameters of CFs in the anterior stroma may provide compact lamellae which may restrict the low wavelength of light. Variable diameters of CFs in the anterior stroma may provide compact lamellae which may restrict the low wavelength of light. This accommodation function is achieved by bending of the cornea. During bending the anterior stroma was stretched and the posterior stroma was compressed due to the presence of small CFs. The middle stroma remained stiff due to the presence of large CFs. Large proteoglycans not only maintain hydration for a longer period of time, but also act as a lubricant to neutralise the shear forces in the anterior and posterior stroma during bending.     

Freeze-substitution and low-temperature embedding of dairy products for transmission electron microscopy

Dairy products are comprised largely of fat, air and water, which makes it difficult to preserve their ultrastructure for electron microscopy. Keeping the samples frozen throughout fixation and embedding protects the structure and distribution of the components of emulsions and foams. Therefore, dairy products were freeze‐substituted and embedded at low temperature (?20 °C) to prepare them for transmission electron microscopy. Whipped cream, ice cream mix and dairy/non‐dairy mixed systems were frozen by plunging in propane, at its boiling point (?187 °C). Ice cream, because it is already frozen, was fractured into 1‐mm³ pieces in liquid nitrogen and then added to frozen fixative (?196 °C). Fixative solution consisted of glutaraldehyde, osmium tetroxide and uranyl acetate dissolved in either methanol or acetone. When material was to be stained after sectioning the fixative was limited to glutaraldehyde in methanol. The temperature was increased step‐wise from ?80 to ?20 °C. Solvent was replaced with resin; the polar resin Lowicryl HM4, the non‐polar resin Lowicryl HM20, LR White and LR Gold were tested. Samples were embedded and polymerized at ?20 °C using ultraviolet light to cross‐link the resin. Methanol proved to be the most effective solvent for substituting the ice; the hydrophobic resin Lowicryl HM20 was the most effective resin for retaining fat structure following osmium fixation.     

Ultrastructural and three‐dimensional study of post‐LASIK ectasia cornea

INTRODUCTION: Post‐laser in situ keratomileusis (LASIK) corneal ectasia is a serious late postoperative complication. Here, we report the ultrastructural features of the post‐LASIK cornea of two patients. METHODS: Two normal corneas (age 24 and 37 years old) and two post‐LASIK ectaic corneas from two patients (A and B) were studied. The “patient A” (age 27 years) underwent penetrating keratoplasty and “patient B” (age 31 years) underwent deep‐anterior lamellar keratoplasty. The excised corneas were processed for light and electron microscopy. A total of 120 images for three‐dimensional (3D) reconstruction were taken by using the software “Recorder” and using a bottom mounted camera “Quemesa” attached to a JOEL 1400 transmission electron microscope. The 3D images were constructed using “Visual Kai” software. RESULTS: In the post‐LASIK cornea, the hemidesmosomes, the basement membrane, and Bowman”s layer were abnormal. The stromal lamellae were thin and disorganized. The collagen fibrils (CFs) diameter and interfibrillar spacing had decreased. Aggregated microfibrils were present in the Bowman's layer and all parts of the stroma. A large number of microfilaments were present at the detachment end of the flap and residual stroma. The 3D images showed the presence of collagen microfibrils and proteoglycans (PGs) within the CF of the normal and post‐LASIK cornea. The collagen microfibrils and PGs within the CFs had degenerated in the post‐LASIK cornea. CONCLUSION: Collagen microfibrils and PGs within the CFs were degenerated, leading to the degeneration of CFs, followed by the disorganization of lamellae in post‐LASIK cornea. The CFs diameter and interfibrillar spacing decreased. Microsc. Res. Tech. 77:91–98, 2014. © 2013 Wiley Periodicals, Inc.     

Molecular and chemical investigations and comparisons of biomaterials for ocular surface regeneration

This study investigated and compared the ultrastructural and chemical properties of representative biomaterials for ocular surface regeneration: a human amniotic membrane (AM) in a basal plate, a human AM in reflected chorion, a preserved AM, and a human corneo‐scleral tissue. Assessments of the morphological differences in the extracellular matrices were evaluated by hematoxylin–eosin, Masson's trichrome (for total collagen), and picrosirius‐red (for newly synthesized collagen) staining. Assessments of the changes in the molecular structures and chemical compositions of the biomaterials for ocular surface regeneration were evaluated by Raman spectroscopy. A placental AM (52 %) was a dense and thick collagenous structure compared to a reflected AM (23 %). The spectroscopy did not obtain any structural information for a preserved AM. The cornea group (100 %, control) and sclera group (104 %) showed the collagen lamellae and interfibrillar spacing, and a slight inflammatory reaction with more fibrous and granulomatous tissues. There was a formation of newly synthesized collagen in a placental AM, while there were few collagen components in a reflected AM. Human AM tissues showed consistent Raman spectra and the characteristic collagen bands, similar to the corneal and scleral tissues. Therefore, these findings suggest that human placental AM and reflected AM are structurally suitable for scleral and corneal surface regeneration, respectively, while human placental or preserved AM and reflected AM are molecularly and chemically suitable for corneal and scleral surface regeneration, respectively. Microsc. Res. Tech. 77:183–188, 2014. © 2013 Wiley Periodicals, Inc.     

Extraction of membrane lipids during fixation,dehydration and embedding of Acholeplasma laidlawii-cells for electron microscopy

The aim of the present investigation was to study the extent to which lipids are extracted from biological membranes during dehydration and embedding procedures carried out at high or low temperatures. Cells of Acholeplasma laidlawii were used as experimental material, since the lipids of this bacterium easily can be radioactively labelled without labelling the rest of the cell, and the lipids are almost entirely located in the cytoplasmic membrane. The cells were fixed at 277 K with glutaraldehyde, sequentially with this reagent and osmium tetroxide, or with glutaraldehyde, osmium tetroxide and uranyl acetate in that order. Loss of lipid during these procedures was negligible. When cells fixed with glutaraldehyde and osmium tetroxide were dehydrated with ethanol at room temperature and embedded in Epon at 333 K, i.e. subjected to a conventional treatment, about 90% of the lipid content of the cells was extracted. The loss was reduced to c. 20% when treatment with uranyl acetate was included in the procedure and the non-polar methacrylate resin Lowicryl HM20 was substituted for Epon. When cells fixed with glutaraldehyde and osmium tetroxide were dehydrated with ethanol at 238 K and embedded in Lowicryl HM20 at room temperature, practically no lipid was extracted. Substitution of the polar methacrylate-acrylate resin Lowicryl K4M for Lowicryl HM20 resulted in the loss of about half of the lipid content of the cells. The use of ethanediol as dehydrating agent instead of ethanol did not diminish the extraction. Cells fixed solely with glutaraldehyde lost about half of their lipid content, even when both dehydration and embedding was performed at 238 K. The lipid material extracted from glutaraldehyde-fixed cells contained slightly more saturated fatty acids than that remaining in the cells. The reverse was true for osmium tetroxide-fixed cells. With respect to lipid species, the extractions were generally rather unspecific.     

Comparison of in vivo and ex vivo cellular structure in rabbit eyes detected by tandem scanning microscopy

Using the tandem scanning microscope, in vivo confocal microscopic images of living eyes were compared to images obtained from ex vivo, freshly enucleated or fixed tissue in the rabbit. In the normal cornea, microscopic details of the superficial epithelium, basal lamina, stromal fibrocyte nuclei, nerves and endothelial cell borders were easily discernible. Removal of the eye from the intact animal resulted in loss of detail with distortion of the normal structural interrelationships within the corneal stroma whilst enhancing details of the corneal epithelium. Formalin fixation further enhanced details of the basal and suprabasal corneal epithelial cell nuclei and the stromal fibrocyte cell borders whilst inducing prominent brightly reflecting folds in the thickened stroma with concomitant enhancement of the edge contrast of the collagen lamellae. These changes appeared to be related, in part, to hydration of the cornea and artefactual pooling of water between structures that may enhance reflectivity by increasing the difference between the refractive index of the cellular and extracellular elements. We conclude that microscopic examination of ex vivo preparations of corneal tissue, although providing increased resolution similar to conventional light microscopic techniques, significantly altered the normal structural relationships and could lead to erroneous measurements of the physiological properties of the tissue as compared to in vivo microscopy of undisturbed, intact tissue.     

A novel technique for flat-embedding cryofixed plant specimens in LR white resin

Acrylic LR White is used preferentially for many research applications because it possesses unique advantages over other commercially available resin types. LR White has low toxicity; its low viscosity and hydrophilic properties enable it to infiltrate specimens with comparative ease, and specimens embedded in LR White take up stains for light microscopy well and tend to retain superior antigenicity relative to other resins. These qualities make LR White a good choice for immunohistochemistry, light microscopy, and transmission electron microscopy. However, LR White does not heat-polymerize in the presence of oxygen, which precludes its use with many commercially available embedding molds. Furthermore, flat-embedding specimens in LR White is often an arduous task. Therefore, in this paper, we report on the development of novel flat-embedding chambers for use with LR White. Another goal of our studies was the rapid fixation of larger specimens. Chemical fixation was inadequate because of the time required for tissue infiltration, but cryofixation quickly and effectively immobilized intracellular organelles. Mean amyloplast positions differed in vertically oriented versus control specimens after chemical fixation, whereas no significant difference was observed after cryofixation. Furthermore, cryofixation provided acceptable preservation at the light microscopy level, even though our specimens were relatively larger. This underscores the utility of cryofixation for light microscopy determination of organelle positioning within plant cells.     

A simple technique to minimize heat damage to specimens during thermal polymerization of LR White in plastic and gelatin capsules

London Resin (LR) White is a commonly used resin for embedding specimens to be used for immuno- and/or cytochemical studies. In some instances, due to either the properties of the specimen or the availability of various reagents and equipment, it becomes necessary and/or more convenient to polymerize LR White using heat rather than chemical accelerators or UV light. It is known, however, that heat can reduce or even eliminate the anti genicity of the tissue being embedded. It is therefore desirable to polymerize specimens at the lowest temperature possible and to remove the specimens from the oven as soon as polymerization is complete. We have developed a technique that provides a visual marker that allows the exothermic polymerization of LR White to be monitored, thus minimizing the amount of time a specimen must stay in the oven while excluding oxygen from capsules of polymerizing LR White.     

Immunofluorescence and protein A-gold techniques in localization of plant pathogen antigens in Lowicryl K4M embedded tissue

This paper investigates the use of Lowicryl K4M in the embedding of apple tissue for immunocytochemistry. The localization of the extracellular protease of the apple pathogen, Nectria galligena Bres., in infected apple tissue by immunofluorescence and protein A-gold immunoelectron microscopy is also described. Infected apple tissue was fixed in 0.5% glutaraldehyde and 4% paraformaldehyde and embedded in Lowicryl K4M at 313 K. The protease was isolated and purified from rotted apple tissue by gel filtration and ion-exchange chromatography. Monospecific antibodies against the protease were raised in rabbits and purified by protein A-affinity chromatography. Incubation of apple tissue sections, infected with N. galligena, with the mono-specific antibody and tetramethylrhodamine isothiocyanate (TRITC)-conjugate, resulted in specific fluorescence of fungal hyphae and cytoplasm of apple cells. Similar localization of colloidal gold particles over hyphae and host cell cytoplasm was demonstrated employing protein A-gold immunochemistry. The low temperature embedding resin Lowicryl K4M appears to provide adequate morphological preservation of apple tissue and excellent retention of antigenicity. TRITC conjugates and protein A-gold may prove useful in immunocytochemical investigations of plant-pathogen interactions.     

Detection of sulfur in fixed and embedded rat peritoneal mast cell granules by X-ray energy dispersive spectroscopy

Purified rat peritoneal mast cells contained 3.3 × 10^?5 gm SO₄ and 2.2 × 10^?8 gm Ca/10⁶ cells. The molar ratio of S/Ca in the whole cell was 600:1. Frozen thin sections of unfixed mast cells contained only sulfur (S) in the granules when examined by X-ray energy dispersive spectroscopy (EDS). Mast cells fixed in 3% glutaraldehyde and 1.5% formaldehyde in 75% ethanol (Et/Ald) or in mixed buffered aldehydes and embedded in Epon 812 or the low viscosity resin diepoxyoctane (DEO) contained S in all granules and Ca in some of the granules measured. Neither element was found in the nucleus, cytoplasm, or resin. Isolated, Et/Ald fixed and embedded granules also contained S. The presence of Ca in the granules was artifactual in that the Ca was absorbed from water in the trough of the diamond knife and/or from the filter paper used to blot the sections dry. This phenomenon was investigated further. Sections of Et/Ald fixed and embedded mast cells were incubated with 5 × 10^?6 to 10^?2 M CaCl₂. Ca was detectable in 100% of the granules incubated at concentrations ≥ 10^?4 M and reached a constant S/Ca ratio of 2.0 at concentrations ≥ 10^?3 M. Ca was not detectable in the nucleus, cytoplasm, or resin at 10^?2 M. A plot of S versus Ca counts from the granules of cells incubated with 10^?2 M CaCl₂ was linear with a slope of 2.0 and a correlation coefficient of 0.88. Et/Ald fixed cells incubated with distilled H₂O had fewer granules containing Ca, 10%, than unincubated cells, 77%. Further, H₂O removed all Ca from Et/Ald fixed cells embedded in DEO. These studies show that S, which is present as SO₄ on the proteoglycan heparin, is readily detectable by X-ray EDS in fixed and embedded cells. An artifact of the technique is that weak anionic sites, which are most probably carboxyl groups on the proteoglycan, can bind the divalent cation Ca and cause spurious localization.     

Observations of human corneal epithelium by tandem scanning confocal microscope

We applied the tandem scanning confocal microscope (TSCM) to 30 healthy human corneas of 3 normal volunteers and 27 patients with cataract and retinal detachment to observe normal corneal epithelial cells in vivo. All corneas were normal under slit lamp microscopic examination. The superficial and basal epithelial cells close to the basal lamina in the central cornea were recorded on videotape and analyzed by a computer-assisted digitizer. The mean cell areas of superficial cells exposed at the surface and basal cells at the horizontal section were 624 ± 109 μm² and 66 ± 5 μm², respectively. The ratio of superficial to basal mean cell area was 11.0 ± 4.5. TSCM was thus useful in evaluating the relationship between superficial and basal cells in human corneal epithelium in vivo.     

The use of freeze-substitution and lr gold in the study of rye grass (Lolium perenne) pollen

Pollen grains of Lolium perenne (rye grass) were prepared for transmission electron microscopy by rapid freezing in liquid propane, substitution in acetone, methanol or diethyl ether, and embedment in the acrylic resin London Resin gold. These were compared to pollen chemically fixed (CF) in aldehyde/osmium tetroxide and embedded in the epoxy resin Quetol 651. Ultrastructural preservation was superior in freeze-substituted (FS) pollen, particularly with the use of acetone or methanol. Optimally preserved FS pollen displayed a homogeneous aspect of the cytoplasm and nucleoplasm, and smooth, uninterrupted contour or organelles. A striking difference was also seen in the preservation of inclusions in the intine. Varied forms and sizes of intine inclusions were evident in FS pollen but these were not discernible in the CF image. The FS scheme studied here presents enormous potential for both ultrastructural and immunolabelling studies in rye grass pollen. Problems discussed include artifacts associated with each of the substitution solvents used, and a gradient of freezing damage observed within the pollen grain.     

Macroscopic and microscopic analysis of the tongue of the common opossum (Didelphis marsupialis)

We performed a macroscopic and microscopic study of the tongues of common opossums, Didelphis marsupialis, from South America. We studied two males and two females. We collected morphometric data on the tongue with precision calipers. For the light microscopy and scanning electron microscopy analyses, we fixed tissue fragments in 10% formaldehyde and 2.5% glutaraldehyde, respectively. The opossum tongues averaged 5.87 ± 0.20 cm in length, 3.27 ± 0.15 cm in width at the lingual body, and 3.82 ± 0.15 cm in width at the root. The mean thickness of the lingual body was 1.8 ± 0.1 cm, and the thickness of the root was 3.82 ± 0.15 cm. Sharp filiform papillae were scattered across the entire tongue; conical filiform papillae occurred on the lingual body and tongue tip; fungiform papillae were scattered among the filiform papillae on the lingual body and tongue tip; and there were three vallate papillae at the root of the tongue. We found two strands of papillary projections in the tongue root. Despite the low variability observed in the lingual papillae, the morphological data obtained in this study may be related to the opossum's diverse food habits and the extensive geographic distribution of the species throughout America. Microsc. Res. Tech. 2012. © 2012 Wiley Periodicals, Inc.     

An immunofluorescence method for postembedded tissue in the acrylic resin Technovit 9100 New® using fluorescein isothiocyanate secondary detection

Immunofluorescence labeling on postembedded tissue in resin is a formidable task. Although resin components and stabilizers are a source of additional strong native fluorescence that overlaps with absorption and emission spectra of commonly used green fluorophores, the unfixed tissue is also subject to native fluorescence. For tissue embedded in resin, we hypothesized that initially removing the resin and subsequently quenching the native fluorescence from the sample could result in specific immunofluorescence signals. The hypothesis was tested on fixed tissue samples embedded in Technovit 9100 New®. Deacrylated and rehydrated semithin sections from a variety of soft tissues were exposed to a quenching solution prior to immunolabeling. Cryostat sections from snap frozen tissue were also stained to assess whether all antigens investigated in fixed tissue were adequately detected. The secondary detection included antibodies conjugated with fluorescein isothiocyanate. The results were evaluated using conventional dark-field and confocal laser scanning microscopy. Both forms of microscopy confirmed the considerable lowering of the native fluorescence associated with the resin and fixed tissue samples with enhanced specific signal. The cryostat tissue sections using the same antibodies in equivalent concentrations confirmed labeling of the same cellular sites as those observed in the fixed tissue. This article describes a method for immunofluorescence labeling in Technovit 9100 New resin embedded tissue and suggests the likely chromogenic elements generating autofluorescence. Microsc. Res. Tech., 2009. © 2009 Wiley-Liss, Inc.     

Immunogold labeling of insulin growth factor-I receptors in elderly human skeletal muscle

Age-associated muscle wasting, or sarcopenia, can be delayed or reversed with interventions, including exercise and pharmaceutical agents. Mapping morphometric changes in the skeletal muscle insulin growth factor 1 receptor can provide valuable information regarding mechanisms controlling muscle protein metabolism. Immunocolloidal gold labeling is a powerful immunocytochemistry procedure for detecting antigens at the ultrastructural level, providing plausible biological markers of cell and tissue adaptations to stimuli. The intent here was to employ immunogold labeling to identify, localize, and quantify the insulin growth factor receptor-I (IGF-IR) in elderly human skeletal muscle. Needle biopsy specimens of the leg vastus lateralis muscle were fixed with 1% glutaraldehyde and 4% paraformaldehyde, dehydrated, and embedded in LR white resin. Pilot experiments were carried out to establish optimal dilutions of primary and secondary antibodies and to employ controls to establish staining specificity. The 6 nm gold particles were first evident when viewed at transmission electron microscopy (TEM) magnifications at 54,000x and clearest at 71,000x. Consistencies were noted in the staining patterns, with the majority of particles lying in proximity to the myofilaments. Gold particles were also found randomly along the outer membrane of the sarcolemma and the mitochondrial membranes. National Institutes of Health (NIH) Image 1.55 version software was used to measure receptor density (NIH, Bethesda, Md., USA). It appears that immunogold labeling of postembedded tissue samples is a sensitive method for detecting IGF-I receptors at the ultrastructural level.     

Quantitative studies on the preservation of choline and ethanolamine phosphatides during tissue preparation for electron microscopy. I. Glutaraldehyde, osmium tetroxide, Araldite methods

The loss of ¹⁴C ethanolamine- and ³H choline-labelled phospholipids from rat liver during tissue preparation for electron microscopy has been examined. Column and thin-layer chromatography combined with double-label scintillation spectrometry were used to analyse the radioactive phospholipid content of the livers of rats injected simultaneously with ¹⁴C aminoethanol and ³H choline chloride. After 4 h (in vivo) the ¹⁴C and ³H labels were mainly incorporated into phosphatidyl ethanolamine and phosphatidyl choline respectively but some ¹⁴C label had been incorporated into phosphatidyl choline. Chopped rat liver was fixed in glutaraldehyde or osmium tetroxide or both sequentially and tissues were dehydrated in ethanol and embedded in Araldite. In each procedure examined the choline label proved more labile than the ethanolamine. After glutaraldehyde fixation alone complete loss of phosphatidyl choline occurred and half of the phosphatidyl ethanolamine was also lost. Following osmium tetroxide fixation negligible loss of either phosphatide occurred. In terms of phospholipid retention, no advantage was gained by glutaraldehyde fixation prior to osmium tetroxide fixation. The results show that both ethanols and embedding monomers are potent phospholipid solvents. The data also suggests that EM autoradiography of these two phosphatides may be carried out with reasonable confidence although it must be pointed out that a high degree of retention does not necessarily imply retention in situ.     

Scanning (atomic) force microscopy imaging of earthworm haemoglobin calibrated with spherical colloidal gold particles

Scanning (atomic) force microscopy (SFM) permits high-resolution imaging of a biological specimen in physiological solutions. Untreated extracellular haemoglobin molecules of the common North American earthworm, Lumbricus terrestris, were imaged in NH₄Ac solution using calibrated SFM. Individual molecules and their top and side views were clearly identified and were comparable with the images of the same molecule obtained by scanning transmission electron microscopy (STEM). A central depression, the presumed mouth of the hole, was detected. We analysed 75 individual molecules for their lateral dimensions. Compression varied for different molecules, presumably because of the variation of the interaction between the SFM tip and the protein molecule. Two effective heights which correspond to the heights of the points of the haemoglobin molecules first and last touched by the tip, h₁ and h₂, respectively, were measured for each protein and ranged between 1.58 and 16.2 nm for h₁ and 1.23 and 13.6 nm for h₂. The apparent diameter was measured and ranged from 44.9 to 86.6 nm (63.2±10.5 nm, n =75), which is about twice the diameter of the molecule reported by STEM for the top view orientation. The higher the measured effective heights, the worse was the tip convolution effect. In order to determine the tip parameters (semivertical angle, curvature of radius and the cut-off height) and to calibrate images of earthworm haemoglobin molecules, spherical gold particles were scanned as standards. The tip sectional radii at distances of h₁ and h₂ above the tip apex were subtracted from the apparent diameter of the protein. The calibrated lateral dimension was 29.1 ±3.85 nm, which is close to the reported scanning transmission electron microscopy data 30.0 ±0.8 nm. The results presented here demonstrate that the calibration approach of imaging gold particles is practical and relatively accurate. Calibrated SFM imaging can be applied to the study of other biomacromolecules.     

Ultrastructural and immunohistochemical study of early repair of alveolar sockets after the extraction of molars from alendronate‐treated rats

The aim of the present research was to analyze ultrastructural and immunohistochemical aspects of the alveolar repair after the extraction of molars of alendronate (ALN)‐treated rats. Wistar rats received 2.5mg/kg body wt/day of ALN during 14 days previously and 7, 14 and 21 days after the extraction of the second mandibular molar. Specimens were fixed in 2% glutaraldehyde + 2.5% formaldehyde under microwave irradiation, decalcified in 4.13% EDTA and paraffin embedded for TRAP histochemistry and immunohistochemistry for OPN, BSP and endoglin, or embedded in Spurr epoxy resin for TEM analysis. Additional specimens had their soft tissues removed and were processed for scanning electron microscopy. The ALN group presented latent TRAP‐positive osteoclasts and nonresorbed alveolar crests with bacterial infection. Mild bone necrosis signs were observed at all time points studied. Ultrastructurally, empty osteocyte lacunae were observed and bone trabeculae surface presented hyalinized aspect. A significant delay in alveolar repair occurred, as well as decreased angiogenesis. ALN treatment provoked mild signs of bone necrosis, despite the high dose employed. The present findings add new information about the ultrastructural aspect of the early repair of rats under ALN treatment and highlight for giving attention when oral surgeries are performed in patients using this drug. Microsc. Res. Tech. 76:633–640, 2013. © 2013 Wiley Periodicals, Inc.