Microstructural strain near osteocyte lacuna in cortical bone in vitro

Mechanical factors affect bone remodeling such that increased mechanical demand results in net bone formation, whereas decreased demand results in net bone resorption. Two proposed mechanical signals are stress-generated fluid flow forces acting on cells and bone matrix deformation itself. A prominent current theory is that bone cells are more responsive to fluid flow than to mechanical strain. Recent experiments support this conclusion: bone cells increase their production of osteopontin (OPN) mRNA, prostaglandin (PGE(2)), and nitric oxide (NO) in response to fluid flow in contrast to cells stimulated by mechanical strain levels similar to those measured in vivo. However, when cells are subjected to substrate strains levels many times greater than those measured in vivo, increased biological activity again results. We assert that it is neither fluid flow nor matrix deformation per se, but rather the resulting cell deformation that causes cell biological response. Machined specimens of undamaged bovine cortical bone were subjected to increasing levels of macroscopic strain while observed under an optical microscope at 220X. Continuum level strain was measured using a standard foil strain gauge attached to the back of the specimen and ranged from 500 to 6,000 microstrain. Images of the specimen surface at each strain level were captured. To determine the level of osteocyte deformation that results from fluid flow in vitro, MLO-Y4 cells were cultured on collagen coated 190 cm2 plastic sheets and subjected to steady fluid flow at 16 dynes/cm(2). Images representing the initial undisturbed cell configuration and the configuration of the cells after ten minutes of fluid flow were acquired from a videotape of the flow experiment. The captured unloaded vs. loaded image pairs were analyzed to determine the local deformation and strain fields using a digital stereoimaging system. When subjected to a nominal continuum strain level approximately equal to that measured in humans in vivo during rigorous activity (2,000 microstrain), the local, osteocyte level strains can be as high as 12,000 to 15,000 microstrain (1.2% to 1.5%). Average osteocyte strains due to fluid flow in vitro increase from 7,972 microstrains after 16 seconds of flow to 22,856 microstrains after 64 seconds of flow. In contrast, maximum strains measured in vivo are approximately 1,800 microstrain in humans and up to 3,000 microstrain in other species. These data may help to explain why bone cells are more sensitive to fluid flow than substrate strain; fluid forces result in cell deformations much higher than those considered to be "physiological".     

Tissue strain amplification at the osteocyte lacuna: a microstructural finite element analysis

A parametric finite element model of an osteocyte lacuna was developed to predict the microstructural response of the lacuna to imposed macroscopic strains. The model is composed of an osteocyte lacuna, a region of perilacunar tissue, canaliculi, and the surrounding bone tissue. A total of 45 different simulations were modeled with varying canalicular diameters, perilacunar tissue material moduli, and perilacunar tissue thicknesses. Maximum strain increased with a decrease in perilacunar tissue modulus and decreased with an increase in perilacunar tissue modulus, regardless of the thickness of the perilacunar region. An increase in the predicted maximum strain was observed with an increase in canalicular diameter from 0.362 to 0.421 microm. In response to the macroscopic application of strain, canalicular diameters increased 0.8% to over 1.0% depending on the perilacunar tissue modulus. Strain magnification factors of over 3 were predicted. However, varying the size of the perilacunar tissue region had no effect on the predicted perilacunar tissue strain. These results indicate that the application of average macroscopic strains similar to strain levels measured in vivo can result in significantly greater perilacunar tissue strains and canaliculi deformations. A decrease in the perilacunar tissue modulus amplifies the perilacunar tissue strain and canaliculi deformation while an increase in the local perilacunar tissue modulus attenuates this effect.     

Electron-microscopic analysis of adrenergic nerve endings in the cat caudal mesenteric ganglion

The ultrastructure of nerve endings of the cat caudal mesenteric ganglion was studied after fixation of the material with 4% lithium permanganate solution by Richardson's method in the modification of Hökfelt et al. [12]. This fixation method was shown to permit the demonstration of numerous adrenergic as well as cholinergic nerve endings. Four types of adrenergic organelles were distinguished in neurons of the ganglion: small and large granular vesicles 30–50 and 70–90 nm in diameter, respectively, a tubular reticulum with electron-dense contents, and small granular vesicles 15–20 nm in diameter. The localization of the adrenergic endings and their relations with other processes and cells of the caudal mesenteric ganglion were studied in detail. The problem of the origin and physiological role of adrenergic nerve endings in this ganglion is discussed.Institute of Physiology, Academy of Sciences of the Belorussian SSR, Minsk. Translated from Neirofiziologiya, Vol. 12, No. 1, pp. 86–92, January–February, 1980.     

Electron-microscopic studies on primate neurons: microtubule-pigment associations.

The relationship between microtubules and the lipoprotein pigment found in senile Cynomolgus brain and senile human brain biopsy material was investigated. Numerous microtubules were present in all parts of the cytoplasm and within the pigment areas, running parallel or obliquely to the pigment bodies and being associated with its lateral aspects. Microtubules also occurred in the periphery of neurons or appearing to enter the perineuronal oligodendrocytes. These observations indicate a possible role of microtubules in the transport of pigment bodies. The oligodendrocyte from human brain biopsy material has definitely taken the role of a phagocyte in ingesting pigment bodies. Its numerous microtubules may offer a fasting moving system for disposing off pigment residures to the capillary endothelium.     

Proteoglycans of hyaline cartilage: Electron-microscopic studies on isolated molecules.

Proteoglycan monomers from guinea-pig costal cartilage, bovine nasal and bovine tracheal cartilage were observed in the electron microscope after being spread in a monomolecular layer with cytochrome c. The proteoglycan molecule appeared as an extended central core filament to which side-chain filaments were attached at various intervals. The molecules from the three sources displayed great ultrastructural similarities. On average, the core filament was about 290 nm long, there were about 25 side-chain filaments per core filament, the side-chain filaments were about 45 nm long, and the distance between the attachment points of the side-chain filaments to the core filament was about 11 nm. With regard to the overall size of the molecules, no evidence of distinct subpopulations was obtained. Good correlation was found between ultrastructural data for the proteoglycan molecules and chemical data obtained by enzyme digestions and gel chromatography. Together these data strongly support the interpretation of the electron-microscopic pictures as indicating a central filament corresponding to the protein core and side-chain filaments corresponding to the chondroitin sulphate chain clusters of the proteoglycan monomers.     

Electron-microscopic and electrophoretic studies of bovine femoral-head cartilage proteoglycan fractions.

Proteoglycans (A1D1) extracted from bovine femoral-head cartilage were examined by electron microscopy using benzyldimethylammonium chloride as a spreading agent. The preparation contained a mixture of particles, some with a 'beaded' structure and a contiguous filamentous 'tail' at one end and others which appeared as round 'blobs', some of which also had filamentous tails. Previous electron-microscopic studies of proteoglycan monomers have indicated that their length distributions were apparently unimodal, a finding that contrasted with agarose/polyacrylamide-gel-electrophoresis results, which generally indicated two bands. In the present study proteoglycans isolated from the slowly migrating electrophoretic band were shown to be predominantly the larger molecules of beaded appearance, whereas the rapidly migrating proteoglycans were predominantly molecules with the 'blob-like' appearance. Gel-filtration, isopycnic-density-gradient-centrifugation and rate-zonal-centrifugation techniques were evaluated as means of proteoglycan fractionation by electron microscopy and agarose-gel electrophoresis. Rate-zonal centrifugation in mixed-salt gradients of caesium chloride/4 M-guanidinium chloride yielded the most effective fractionation.     

Electron-microscopic and chemical studies of oligomers in horse ferritin

Horse ferritin was fractionated both by starch-gel electrophoresis and by gel filtration on Sephadex G-200. Monomer fractions contained up to 98% of monomer and oligomer fractions up to 76% of oligomers as determined by quantitative electron microscopy. Percentages obtained from electron micrographs correlated well with analytical starch-gel electrophoretograms and ultracentrifuge patterns. Amino acid analyses of monomer- and oligomer-enriched fractions showed no significant differences. Ferritin oligomers did not apparently dissociate on dilution for electron microscopy or on storage. Apoferritin dimers were stable in 0·01m-phosphate buffer at dilutions down to 0·19mg./ml. as shown by ultracentrifugation. Chemical studies indicated that the intermolecular bonds in oligomers are resistant to a variety of reagents and conditions, including those that would be expected to attack disulphide, peptide and ester linkages respectively. Partial disaggregation was achieved at high pH values and in 67% (v/v) acetic acid. Centre-to-centre intermolecular distances in dimers were found to be about 100å. Three main types of trimer configuration were found and a variety of tetramers and pentamers. These configurations are described and discussed.     

Electron-microscopic studies on developing intramural ganglia of the small intestine in human and rabbit fetuses.

Electron-microscopic studies were made on the appearance of synapses in the intramural ganglion (Auerbach) and findings were correlated with the onset and development of intestinal peristalsis in 6- to 30-week-old human and rabbit fetuses from the 12th day after conception until birth. At stage I, in which the small intestine shows no indication of a muscle layer or spontaneous peristalsis, primitive synapses containing several clear vesicles and a few cored vesicles are seen on neuroblasts and their processes (dendrites). At stage II, in which the circular muscle is developed and bidirectional peristalsis occurs, synaptic profiles can be classified into 3 types. Type 1 is the most numerous but seldom shows membrane specificity on the synaptic portion. Types 2 and 3 have small flattened vesicles and small round vesicles, respectively. They are further characterized by thickening of snyaptic membranes and aggregation of small clear vesicles associated with the presynaptic membrane. At stage III, the longitudinal muscle layer develops in the small intestine. At this stage, nerve terminals containing mainly cored vesicles have been observed and classified into types 4 and 5, according to their morphology. At stage IV, antiperistalsis no longer occurs and type 6 nerve terminals in the intramural ganglia can be recognized by their densely packed, large-cored vesicles. The possible physiological significance of the nerve terminals has been discussed.     

Autotomy of sensory nerve endings in the area of microvessels]

The phenomenon of autotomy of peripheral receptor terminals, in the area of the intestinal microvessel bed has been analysed. This phenomenon is accompanied with a real separation of the terminal patches or large fragments of receptors with their successive degeneration. The effect of the terminals autotomy is succeeded in reproducing and analysing in dynamics in tissue culture. The computer analysis of the image demonstrates that autotomy is observed not only in developing structures during early period of ontogenesis, but in well developed, as regards all morphological criteria, tissue receptors of mature animals. The investigations have been performed by means of silver nitrate impregnation after Bielschowsky--Gros, as well as using vital microscopy. An idea has been formed that autotomy is a part of the cyclic process of autotomy--regeneration of the terminals. This process is connected with retractile cytopoiesis, apocrine secretion. A high concentration of proteolytic enzymes in the amputated degrading fragment of the receptor can serve as a trophic factor, activating the local metabolic process in the area of microvessels.     

Electron-microscopic and cytophotometric studies on the abdominal pre- and paravertebral ganglia of the cat.

Electron-microscopic and cytophotometric studies of the cat abdominal pre- and paravertrebral ganglia have revealed that in the prevertebral ganglion there are neurons of two distinct types. The paravertebral ganglion was found to consist of a structurally homogenous neuronal population.     

Electron-microscopic studies on the maturation of secretory cells in the mouse Harderian gland

The porphyrins in the Harderian glands of mice are first detectable at 7-8 days of age in both sexes. Thereafter, the levels show a marked rise during the closed-eye period, reaching a peak around the time of eyelid disjunction and then decrease gradually until day 25. At onset of puberty, the level rises again and exhibits a sexual dimorphism. The development of the Harderian gland was examined by light and electron microscopy in the mouse. Although two types of secretory cells, designated as type A and type B, comprise the glandular epithelium in fully developed glands, the time of neonatal appearance is different between the two. Type A cells first appear on the 5th day of age, while type B cells appear around the 7th day corresponding to the time at which porphyrins are first detected. Results of the investigations suggest that the porphyrins in the Harderian gland of mice may be synthesized mainly by type B cells.     

Electron-microscopic studies on the presence of gap junctions between corneal fibroblasts in rabbits

Summary Corneal fibroblasts, major cellular components of the corneal stroma, are loosely arrayed between collagen lamellae. They play an important role in the metabolic and physiological homeostasis mechanisms by which the cornea is kept transparent. This paper deals with the demonstration of the gap junctions between the corneal fibroblasts of rabbits by transmission electron microscopy of thin sections and of freeze-fracture specimens. Under the transmission electron microscope, the corneal fibroblasts are seen between the lamellae of collagen fibers of the corneal stroma. Their long cytoplasmic processes are in contact with those of neighboring fibroblasts. Typical gap junctions are found between these cytoplasmic processes. In the freeze-fracture images, intramembrane particles with a diameter of 10.3 nm form polygonal aggregates on P faces. These findings suggest that corneal fibroblasts, coupled with each other, might function synchronously through gap junctions responsible for metabolic activities essential for the maintenance of corneal transparency.A part of this study was published in Kinki Daigaku Igaku Zasshi in Japanese as the thesis for Atsuko Ueda, M.D. This study was supported in part by a grant from the Ministry of Education, Science and Culture of Japan, from Osaka Eye Bank, Osaka, Japan, and from an intramural research fund of Kinki University     

Further studies of the transport of protein to nerve endings

Mice were injected intracerebrally with [l-¹⁴C]leucine, and the specific activities of subcellular fractions of brain and effractions of isolated nerve endings were determined. There was a progressive increase in the specific activity of protein associated with isolated nerve endings after incorporation of [l-¹⁴C]leucine into whole brain protein had terminated. Although, the incorporation of [¹⁴C]leucine into soluble protein of whole brain did not differ significantly in mice which were 3 months or 1-year old, the subsequent increase in specific activity of soluble protein isolated from nerve endings was significantly greater in the younger animals; 6-month-old mice were intermediate. Therefore, changes in some aspect of the transport of protein to nerve endings is altered even after sexual maturity. Anaesthetization with pentobarbitone during incorporation of [¹⁴C]leucine into protein, and inhibition of protein synthesis with acetoxycycloheximide after incorporation of [¹⁴C]leucine was complete, did not interfere with the subsequent appearance of radioactive protein at the nerve ending. Evidence is presented for the transport, from a proximal site of synthesis, of protein associated with particulate components of the nerve ending, including synaptic vesicles.     

Electron-microscopic studies on the physiological cell loss in the gastric mucosa of the golden hamster

Summary Fine-structural aspects of physiological cell loss in the gastric mucosa of the golden hamster were observed. As the surface mucous cell ascends along the gastric pit, the cell becomes taller and funnel-like in shape. The interfoveolar cell located at the superficial portion of the gastric pit has many lysosomes and a few lipid droplets in the cytoplasm. The nucleus moves toward the upper region of the cytoplasm, while the Golgi apparatus moves downward toward the infranuclear region. After the rupture of the apical plasma membrane takes place, the lateral and basal plasma membranes of this cell remain in spite of loss of the cell contents. Between the basal plasma membrane of the interfoveolar cell and the capillary endothelium is a thick connective tissue layer characterized by densely packed collagen fibrils. The remaining basal and lateral plasma membranes of the ruptured cell and the thick underlying collagenous layer might play a role in protecting the tissue from potential damage induced by the physiological cell loss.This study was supported in part by a grant from the Research Fund of the Ministry of Education, Science and Culture, Japan.