Ultrastructural study of upper surface layer in rat articular cartilage by "in vivo cryotechnique" combined with various treatments.

The ultrastructures of the upper surface layer of rat articular cartilage were studied with our "in vivo cryotechnique" followed by freeze-substitution method for scanning electron microscopy (SEM) or transmission electron microscopy (TEM). Rat hip or knee articular cartilage was quickly frozen by the in vivo cryotechnique with liquid isopentane-propane cryogen (-193 degrees C), and surface areas of some frozen specimens were freeze-fractured with a scalpel in liquid nitrogen. They were freeze-substituted and freeze-dried, ion-sputtered, and then observed in SEM. Other frozen specimens were routinely freeze-substituted and embedded in epoxy resin for TEM. Many globular structures were detected in the thick upper surface layer that had not been revealed by the conventional fixation methods. Their sizes were reduced by Triton X-100 treatment, and their localization was also detected in synovial fluid, as revealed by SEM. Such globular lipid-like structures in the upper surface layer of hip or knee articular cartilage might contribute to joint lubrication.

Scanning electron microscopic study of the renal glomerulus by an in vivo cryotechnique combined with freeze-substitution.

The 3-dimensional ultrastructure of mouse renal glomeruli under normal haemodynamic conditions was studied by scanning electron microscopy using an in vivo cryotechnique followed by freeze-substitution, and compared with glomeruli prepared by conventional fixation methods. Mouse kidneys were frozen with a cryoknife apparatus and a liquid isopentane-propane mixture (-193 degrees C). Surface areas of the frozen tissues were freeze-fractured with a scalpel in liquid nitrogen. The specimens were routinely freeze-substituted, freeze-dried, ion-sputtered, and then observed in a scanning electron microscope at an accelerating voltage of 5 kV. Renal glomeruli showed good ultrastructural preservation of the surface tissues. Podocytes with interdigitating foot processes covering capillary loops exhibited smooth surface contours and their cell surfaces were arranged more tightly than those seen by the conventional fixation method. Filtration slits between foot processes were found to be narrow. The internal structure of the glomerular tuft was seen in the freeze-fracture faces. The capillary lumen with variously shaped erythrocytes was kept open in frozen glomeruli under normal blood circulation conditions. The ultrastructure of renal glomeruli, as revealed by the in vivo cryotechnique with freeze-substitution, appears to be closer to that of the living state.

The ultrastructure of anionic sites in rat articular cartilage as revealed by different preparation methods and polyethyleneimine staining.

The ultrastructure of anionic sites in the middle layer of rat articular cartilages was studied by two methods, the quick-freezing and deep-etching method, and the quick-freezing and freeze-substitution method. The anionic sites were visualized with a cationic tracer, polyethyleneimine. They were also compared with those revealed in tissues subjected to conventional fixation, such as pre-embedding or post-embedding. With the deep-etching method, three-dimensional meshwork structures were observed more clearly in the extracellular matrix compared with those seen in conventional ultrathin sections. In combination with polyethyleneimine staining, in which no chemical contrast was needed for visualization of anionic sites, numerous stained particles were detected around filaments in the extracellular matrix, indicating that they were anionic sites consisting mainly of proteoglycans. With the pre-embedding method and polyethyleneimine staining, the shapes of aggregated stained particles varied with different preparation procedures, including chemical fixation and contrasting. The fine meshworks were also observed with the post-embedding method and polyethyleneimine staining. It is suggested that such images of anionic sites, as revealed by the deep-etching method and the post-embedding polyethyleneimine-staining method with low-temperature dehydration, are probably closer to native states than those revealed by the conventional pre-embedding polyethyleneimine-staining method.

Ultrastructural study of anionic sites in glomerular basement membranes at different perfusion pressures by quick-freezing and deep-etching method.

The ultrastructures of anionic sites in rat glomerular basement membranes (GBM) were studied at different perfusion pressures of 100, 150, 200 or 250 cm H2O by a quick-freezing and deep-etching (QF-DE) method, in addition to conventional fixation methods, using polyethyleneimine (PEI) as a cationic tracer. By the QF-DE method, three-dimensional ultrastructures at each pressure were observed more clearly than those seen on conventional ultrathin sections. When the perfusion pressures were changed from low levels to higher ones, the total thickness of GBM with anionic sites became gradually thinner. Many PEI particles were observed around filaments, not only in the laminae lucidae, but also in the lamina densa. These findings indicated the existence of anionic sites in both laminae lucidae and lamina densa of GBM. The numbers of PEI particles in the lamina rara externa were counted on conventional ultrathin sections for morphometric analyses. The numbers per unit length of GBM were significantly decreased at higher perfusion pressures (200 and 250 cm H2O) than those seen at both normal (150 cm H2O) and lower (100 cm H2O) pressures. It is concluded that the ultrastructures of anionic sites in the GBM may be changed in vivo, depending on the hemodynamics in the glomerular capillary.

A histochemical study of anionic sites in the intermediate layer of rat femoral cartilage using polyethyleneimine at different pH levels.

Anionic sites in the intermediate layer of young rat hyaline cartilages were examined using a cationic dye, polyethyleneimine (PEI), at different pH levels. Femoral heads were resected and fixed in 2.5% glutaraldehyde and treated with 0.5% PEI at pH 7.4, pH 2.5 or pH 1.0. Some cartilage samples were first digested with chondroitinase ABC or hyaluronidase. The PEI deposits at pH 7.4 appeared to be irregular shapes. Their sizes seemed to be larger than those at pH 2.5 or pH 1.0. The PEI deposits were also found on the surface of collagen fibrils at both pH 7.4 and pH 2.5 even after the chondroitinase ABC digestion, but were not found at pH 1.0. Moreover, they disappeared after hyaluronidase digestion. Accordingly, it is suggested that PEI-positive structures varied depending on pH levels. In addition, hyaluronan may be localized near collagen fibrils, but most sulphated proteoglycans may not.

Ultrastructural study of glomerular capillary loops at different perfusion pressures as revealed by quick-freezing, freeze-substitution and conventional fixation methods.

Wistar rat kidneys were perfused with some fixatives at different pressures of 100, 150, 200 or 250 cm H2O via the aorta and were studied by the quick-freezing and freeze-substitution (QF-FS) or deep-etching (QF-DE) methods, in addition to the conventional immersion or perfusion fixation method. Different parts of glomerular capillary walls were selected for morphometric analyses. It was demonstrated that the widths of glomerular slit diaphragms and the spaces between foot processes were more widely dilated at higher perfusion pressures (200 and 250 cm H2O) than those seen at both normal perfusion pressure (150 cm H2O) and lower perfusion pressure (100 cm H2O). On the other hand, the glomerular basement membranes were thinner at higher perfusion pressures. By the QF-FS and QF-DE methods, the foot processes showed different shapes from those revealed by the conventional preparation methods, even at the same perfusion pressure. It is concluded that the widths of glomerular slit diaphragms and glomerular basement membranes and the spaces between foot processes may be significantly changed in vivo, depending on the hemodynamics in the glomerular capillary.

Proteoglycans in articular cartilage revealed with a quick freezing and deep etching method.

OBJECTIVES: To clarify the three dimensional ultrastructure of proteoglycans, and their relationship with other matrix components in articular cartilage. METHODS: Specimens from rat femoral heads were examined using three techniques: (1) Histochemical staining with cationic polyethyleneimine (PEI), using a pre-embedding or a postembedding method. Some tissues were pretreated with chondroitinase ABC or hyaluronidase. (2) Quick freezing and deep etching (QF-DE). Some specimens were fixed with paraformaldehyde and washed in buffer solution before quick freezing; others were frozen directly. (3) Ultrathin sections were studied after conventional preparation. RESULTS: Proteoglycans were observed as aggregated clumps with PEI staining by the pre-embedding method, but as fine filaments by the postembedding method. They were lost with enzyme digestion; this was also demonstrated by the QF-DE method. The ultrastructure was well preserved by the QF-DE method when fixation and washing procedures were included, but not without these procedures. A fine mesh-like structure was connected to the cell membrane in the pericellular matrix. Filamentous structures suggestive of aggrecans were observed among collagen fibrils. They had side chains, approximately 50 nm in length, which branched from the central filaments at intervals of 10-20 nm, and were occasionally linked to other structures. Many thin filaments were also attached to the collagen fibrils. CONCLUSIONS: The QF-DE method incorporating paraformaldehyde fixation and buffer washing procedures revealed three dimensional, extended structures suggestive of proteoglycans.