No abstract available.
Cartilage, Articular* ; Knee* ; Osmium Tetroxide* ; Synovial Membrane*

The effects of tear gas, o -chlorobenzylidene malononitrile (CS) on the cytoplasmic organelles were studied in the ciliated cell of rat tracheal epithelium. Albino rats (Sprague -Dawley strain), weighing about 150gm, were used as experimental animals. The experimental animals were exposed to 2.0 g/m 3 of CS gas for 20 minutes per day for the succesive 3 days. The experimental animals were sacrified at 1, 3, 6, 12 hours and 1, 3 and 5 days after final exposure to CS gas. Specimens obtained from the trachea were pre -fixed in 2% glutaraldehyde -2.5% paraformaldehyde and post -fixed in the 1% osmium tetroxide for electron microscopic study. The results obtained were as follows: 1. In 1 hour CS gas exposed group, rough endoplasmic reticulum with dilated cisternae, and mitochondria with disrupted double membrane in the ciliated cells are found. 2. In 3 hours and 6 hours CS gas exposed groups, dilated, segmented and sacculated cisterane of rough endoplasmic reticulum, mitochondria with dissolved cristae and disrupted double membrane, and Golgi complex with atrophied cisternae are observed in the ciliated cell. 3. In 12 hours CS gas exposed group, some mitochondria with swollen cristae is found in the ciliated cell. 4. In 1 day CS gas exposed group, mitochondria with dissolved cristae, Golgi complex with hypertrophied cisternae, and autophagic vacuole are found. 5. In 3 day and 5 day CS gas exposed groups, numerous mitochondria, well -developed rough endoplasmic reticulum, and supranuclear Golgi complex are found in ciliated cell. The results of the present study suggest that the o -chlorobenzylidene malononitrile (CS) gas is cytotoxic to the ciliated cells in tracheal epithelium inducing some degenerative changes, which are recovered with the lapse of time.
Animals ; Cytoplasm* ; Endoplasmic Reticulum, Rough ; Epithelium* ; Glutaral ; Golgi Apparatus ; Membranes ; Mitochondria ; Organelles* ; Osmium Tetroxide ; Rats* ; Tear Gases ; Trachea ; Vacuoles

BACKGROUND: Prolonged exposure of topical and systemic corticosteroid to skin can result in well-recognized cutaneous abnormalities including cutaneous atrophy, easy bruisibility, increased skin fragility, and increased risk of infection. Skin barrier impairment is also reported as a steroid-induced side effect. A major function of the skin is the formation of a permeability barrier between the external milieu and the organism. Recent studies have shown that chronic corticosteroid negatively impacts epidermal barrier function. As well as this topical corticosteroid not only has antiproliferative actions but also inhibits the differentiation of the epidermis, resulting in structural defects in the epidermis. OBJECT: We wanted to determine whether high dose systemic steroid injection would display adverse effects, specifically on; epidermal functions, permeability barrier homeostasis and stratum corneum integrity and cohesion. The basis for such changes was also to be determined. MATERIAL AND METHODS: Systemic steroid was administered by injecting each hairless mouse, 8-10 week of age, intraperitoneally with 0.3 mg triamcinolone acetonide, two times per week for five weeks. For the controlled hairless mice, 0.9% normal saline was administered by the same method of injection. Every week, transepidermal water loss (TEWL) was checked and skin biopsies were taken. Skin specimens were prepared for electron microscopy using both 0.25% ruthenium tetroxide and 4% osmium tetroxide postfixation. For light microscopy staining hematoxylin-eosin and ion capture cytochemistry was used. RESULTS: The results were as follows; 1. From about 1 week onwards, high dose systemic steroid usage produced visible cutaneous changes and significantly increased the TEWL in the group of 0.3 mg triamcinolone acetate injected hairless mice compared with the control. 2. Light microscopic observations of the steroid-injected hairless mice showed gradual thinning of the epidermis from about 2 weeks onwards, compared with the control. Loss of stratum corneum was also observed in the steroid injected hairless mice. 3. The ruthenium tetroxide staining of high dose systemic steroid treated specimens revealed that the lipid bilayer was impaired and fragmented from about 3 weeks. Intercellular spaces were widened and the lipid bilayer either disappeared or showed damage when compared with the control. 4. From about 3weeks onwards. electron microscopic studies revealed, not only a marked decrease in the number of lamellar bodies, but also an abnormal transformation of lamellar bodies in the steroid injected hairless mice compared with the control. 5. Throughout the five weeks, the calcium gradient gradually disappeared in the 0.3mg triamcinolone injected hairless mice compared with the control. Consequently, high dose systemic steroid use results in barrier dysfunction and morphological abnormalities.
Animals ; Atrophy ; Biopsy ; Calcium ; Epidermis ; Extracellular Space ; Histocytochemistry ; Homeostasis ; Lipid Bilayers ; Mice ; Mice, Hairless* ; Microscopy ; Microscopy, Electron ; Osmium Tetroxide ; Permeability ; Ruthenium ; Skin* ; Triamcinolone ; Triamcinolone Acetonide

Although the autogenous vein graft is the most reliable in the fields of microvascular reconstruction, the microvascular allograft and microvascular prosthesis have been developed to be substitute for autogenous vein because it has many problems. In many experimental study have been reported highly variable patency rate and its thrombogenetic property of microvascular allograft. Especially, antigenicity of the homogenous vessels and immune reaction-induced thrombosis are main cause of homogenous microvascular anastomosis failure. For that reason, several investigators have attempted to reduce the antigenicity and improve the patency rate of microvascular allograft. The purpose of this study was to observe the healing process in applying frozen arterial allograft in the rats. In order to perform this study, 27 Sprague-Dawley rats, weighing 300gm or more selected. 12 carotid arterial anastomoses were performed in the rats by using microvascular end-to-end anastomosis as control group and 15 frozen(-196degreesC) arterial allografts were implanted into the carotid artery in the rats by using microvascular anastomosis as experimental group. The experimental rats were sacrificed on the 1st, 3rd, 7th, 14th, 28th, 56th day after operations. For scanning electron microscopic study, fixation was performed by perfusion of 2.5% glutaraldehyed-2% paraformaldehyed in 0.1M phosphate buffer at pH7.3. The specimens were post-fixated in 1% osmium tetraoxide for 2 hours, washed with cacodylate buffer, dehydrated in a series of ascending ethanol baths, critical point dried, coated with gold in a vacuum evaporator, and observed with a scanning electron microscope(JEOL, JSM-840-A, 20kV). For histologic examination taken specimens were embedded in paraffin, sectioned 6-8micrometer in thickness. The specimens were stained with hematoxylin-eosin stain method, examined under light microscope. The results were as follows; 1. The patency rate of control group was 92% and experimental group was 86%. 2. Endothelial cells regeneration at the anastomosis site of both group was partially appeared on the 1st week after experiment. 3. On the 2nd week after experiment, anastomosis site was completely covered with regenerated endothelial cell in both group, and the endothelial cell proliferated toward the graft at experimental group. 4. On the 4th, 8th week after experiment, the grafted artery was partially covered with endothelial cell at experimental group.
Allografts* ; Animals ; Arteries ; Baths ; Cacodylic Acid ; Carotid Arteries ; Endothelial Cells ; Ethanol ; Humans ; Osmium ; Paraffin ; Perfusion ; Prostheses and Implants ; Rats* ; Rats, Sprague-Dawley ; Regeneration ; Research Personnel ; Thrombosis ; Transplants ; Vacuum ; Veins

BACKGROUND: The stratom corneum lipids, responsible for the epidermal water bar rier, consist mainly of ceramides, cholesterol and free fatty acids. However, little has been studied about the effects of non-polar, polar and mixed organic solvents on the changes of the stratum corneum lipids bilayer. OBJECTIVE: We designed this study in order to investigate the effect of non-polar, polar and mixed organic solvents on the lipids bilayer in hairless mice. METHODS: Twenty four hairless mice were evenly divided into 4 groups; a control group, chloroform treated group, methanol treated group and mixed solvent(chloroform/methanol(2:1) ) treated gr oup. The changes in transepidermal water loss, as measured with an evaporimeter, were recorded after topical application of either chloroform, methanol or mixed solvents at 0, 3, 6, 12, 24 and 48 hours respectiveh. For electron microscopy, the skin samples taken from the mice of ea.:h group were t.rented with osmium tetroxide and ruthenium tetroxide after the treatment with each solvent. RESULTS: The results were as follows ; 1. From 0 to 24 hours after treatment with each solvent transepidermal water loss was significantly increased in the chloroform and the mixed solvent[chloroform/methanol(2:1)] treated groups, compared to the methanol treated group and control group(P<0.001). 2. 48 hours after treatment with each solvent, the differences in the values of transepidermal water loss in all groups were insignificant. 3. On electronmicroscopic examination, separation of intercellular lipid bilayers and a decrease in the numher of lamellar bodies were more severe in the chloroform treated and mixed solvent (chloroform/methanol(2:1)] treated groups than in the methanol treated group. Application of non-polar organic solvents, especially mixed solvents[chloroform/methanol(2:1)] resulted in an increase in transepidermal water loss and greater structural changes than with polar organic solvents. CONCLUSION: Our results suggest that non-polar lipids may play a more important role in the protection of water vaporization of the stratum corneum lipids barrier than polar lipids.
Animals ; Ceramides ; Chloroform ; Cholesterol ; Fatty Acids, Nonesterified ; Lipid Bilayers ; Methanol ; Mice ; Mice, Hairless* ; Microscopy, Electron ; Osmium Tetroxide ; Ruthenium ; Skin* ; Solvents* ; Steam

BACKGROUND: Water exposure is considered an important causative factor of irritant contact dermatitis. It is also known that water exposure can disrupt the stratum corneum (SC). However, there are only a few morphologic studies on the effect of water contact on the skin. OBJECTIVE: The aim of our study was to investigate the effects of prolonged water exposure on the permeability barrier and the ultrastructure of the SC intercellular lipids. METHODS: After prolonged water exposure of hairless mouse skin in vivo for 24, 36, 48, and 72 hrs respectively, the permeability barrier function was assessed by transepidermal water loss (TEWL) measurement, and the ultrastructure of SC by electron microscopy using osmium tetraoxide and ruthenium tetraoxide postfixation and calcium ion capture cytochemistry. Additionally, the lipid composition was evaluated using confocal microscopy with nile red stain and the integrity of the SC assessed using a lanthanum tracer. RESULTS: After prolonged water exposure, water caused a significant increase in TEWL with disappearance of the calcium gradient, but this did not significantly influence the recovery rate of TEWL. The intercellular lipids were disrupted, and multiple lacunae containing abnormal delaminated materials within the intercellular spaces were observed. Lanthanum tracer penetrated into the intercellular space of the SC. There was a progressive decrease in nile red staining with neutral lipid content. With increasing exposure to water, these results were more evident. CONCLUSION: Our results provide a better understanding of the disruptive effect of prolonged water exposure on barrier lipids, the penetration-enhancing effect of water and the increased susceptibility to irritants, with regard to duration of water exposure.
Animals ; Calcium ; Dermatitis, Contact ; Extracellular Space ; Histocytochemistry ; Irritants ; Lanthanum ; Mice ; Mice, Hairless ; Microscopy, Confocal ; Microscopy, Electron ; Osmium ; Permeability* ; Ruthenium ; Skin ; Water*

This experiment was performed to evaluate the morphological responses of 5-fluorouracil or mitomycin C on the spleen of the mice. 5-fluorouracil (60 mg/kg) or mitomycin C (400 microgram/kg) were injected subcutaneously every other day, and the animals were sacrificed at 1 week and 2 weeks following the first injection. Pieces of the tissue were taken from the spleen, fixed in 10% neutral formalin for light microscopy. The paraffin sections stained with hematoxylin-eosin, Masson-trichrome, Bielschowsky's silver impregnation or aldehydefuchsin. For electron microscopy, the tissues were prefixed with 2.5% glutaraldehyde-1.5% paraformaldehyde followed by post-fixed with 1% osmium tetroxide. The ultrathin sections stained with uranyl acetate and lead citrate. The observed results were as follows: 1. On histological study, in the mitomycin C treated group, macrophages which contain pyknotic nuclei were observed more frequently than in those of 5-fluorouracil treated group. 2. In the 5-fluorouracil treated group, positive reactions to Masson-trichrome and Bielschowsky's silver impregnation were observed in the splenic capsule and traculae at the 1 week, and weak postive stains were observed at the 2 weeks. 3. In the mitomycin C and the 5-fluorouracil group, positive staining reaction to aldehyde-fuchsin were observed in splenic capsule, trabeculae and around artery at the 1 week and 2 weeks. 4. On the ultrastructural study, distended cisternae of granular endoplasmic reticula were observed frequently at 1 week. 5. In the mitomycin C treated group, myelin figures in the lymphocytes and reticular cells were observed more frequently than in those of 5-fluorouracil treated group. From the above results, it was concluded that lymphocytes and reticular cells of the spleen were slightly damaged by 5-fluorouracil or mitomycin C, and mitomycin C seems more harmful on the spleen than 5-fluorouracil does.
Animals ; Arteries ; Citric Acid ; Coloring Agents ; Fluorouracil* ; Formaldehyde ; Lymphocytes ; Macrophages ; Mice ; Microscopy ; Microscopy, Electron ; Mitomycin* ; Myelin Sheath ; Osmium Tetroxide ; Paraffin ; Silver ; Spleen*

OBJECTIVETo introduce a practical, economical, and time-saving method to stain (with osmic acid) the myelin sheath in normal and regenerated peripheral nerves.

METHODSA total of 12 Sprague Dawley rats, weighing 250-320 g (mean equal to 276 g+/-38 g), were divided into two groups: a normal nerve group (n equal to 6) and a regenerated nerve group (n equal to 6). In the normal nerve group, the ventral and dorsal roots of L(4) to L(6) and their sciatic nerves were harvested for histological analysis. While in the regenerated nerve group, the right sciatic nerves were severed and then repaired with an epineurial microsuture method. The repaired nerves were harvested 12 weeks postoperatively. All the specimens were fixed in 4% paraformaldehyde and transferred to 2% osmic acid for 3-5 days. Then the specimens were kept in 75% alcohol before being embedded in paraffin. The tissues were cut into sections of 3 micromolar in thickness with a conventional microtome.

RESULTSUnder a light microscope, myelin sheaths were clearly visible at all magnifications in both groups. They were stained in clear dark colour with a light yellow or colorless background, which provided high contrast images to allow reliable morphometric measurements. Morphological assessment was made in both normal and regenerated sciatic nerves. The ratios of the myelin area to the fibre area were 60.28%+/-7.66% in the normal nerve group and 51.67%+/-6.85% in the regenerated nerve group, respectively (P less than 0.01).

CONCLUSIONSOsmic acid staining is easy to perform and a very clear image for morphometrical assessment is easy to obtain. Therefore, it is a reliable technique for quantitative evaluation of nerve morphology.

Animals ; Myelin Sheath ; pathology ; Nerve Regeneration ; Osmium Tetroxide ; Peripheral Nerves ; anatomy & histology ; pathology ; Rats ; Rats, Sprague-Dawley ; Sciatic Nerve ; pathology ; Staining and Labeling ; methods ; Suture Techniques

BACKGROUND: Stratum corneum lipids are arranged as intercellular membrane bilayers presumed to mediate the epidermal permeability barrier. Acute disruption in barrier function will initiate epidermal lipid synthesis, which can be prevented by occlusive membrane. Whereas, occlusion of the skin is known to cause an increased transepidermal water loss(TEWL) and enhanced percutaneous absorption of a variety of compounds. OBJECTIVE: Previous reports with electron microscopy showed varying sizes of lacunae and disorganized intercorneocyte lipids after tape stripping and occlusion with a water impermeable membrane on the murine skin. Hence we studied the effects on stratum corneum lipids and changes in barrier function after occlusion with a water-impermeable membrane. METHODS: Male hairless mice were occluded with one finger of a Latex glove for 24, 48 and 60 hours. After occlusion, TEWL was measured and biopsy specimens were taken from skin. For electron microscopic examination the samples were treated with osmium tetroxide, ruthenitum tetroxide, and tracer (lanthanum) and infrared spectroscopy were also applied. RESULTS: Occlusion with a water-impermeable membrane on the skin induced higher TEWL Values and greater penetration of the tracer than normal. Alterations of the lipid bilayer membrane and lacunae forwation in the stratum corneum interstices were also induced after 24 hours of occlusion. However, the orderness of the lipid alkyl chain in the stratum corneum was not changed until 60 hours of occlusion. CONCLUSION: These studies indicate that the increased epidermal permeability after occlusion may be due to the abnormal lipid membrane structures and volume expansion of existing lacunar domains in the stratum corneum interstices.
Animals ; Biopsy ; Fingers ; Humans ; Lanthanum ; Latex ; Lipid Bilayers ; Male ; Membranes ; Mice ; Mice, Hairless* ; Microscopy, Electron ; Osmium Tetroxide ; Permeability ; Skin ; Skin Absorption ; Spectrum Analysis ; Water

BACKGROUND: The stratum corneum(SC) has a permeability barrier function which regulates percutaneous absorption by the inhibition of transepidermal water loss(TEWL). Acute mechanical or chemical disruption of the SC induces the impairment of the permeability barrier and so increases the TEWL. The calciumtion has been recognized as an important ion in the recovery of the skin barrier. Recently the main delivery pathway of iontophoretic drugs have been suggested by SC interstices. However the morphologic changes in the SC interstices and calcium after iontophoresis have not been reported. OBJECTIVE: The aim of our study is to confirm that iontophoresis may induce changes in the SC interstices and delay the recovery of the barrier after disruption. MATERIALS AND METHODS: After tape stripping the hairless mouse flank skin, the iontophoresis power supply (6V, 0.6mA) was connected to the patch atiached for 2.5 hours to the stripped site. We checked the THWL 0, 2.5, 6, 12, 18, 24 hours after the tape stripping and obtained specimens and performed osmium tetroxide, ruthenium tetroxide postfixation and calcium ion-capture cytochemical stains for electron microscopic study. RESULTS: The recovery rate of the TEWL in iontophoresis was lower than in the control. This was especially so in the anouse which had received anode iontophoresis for 6 hours. It showed statistically lower TEWL than in the control(p<0.05). Anode iontophoresis induced low calcium in stratum granulosum (SG), but cathode iontophoresis induced high calcium in SC. After iontophoresis there were changes in the SC interstices structures. CONCLUSION: Iontophoresis can induce changes in the SC interstices and calcium distribution and so may help the topical drug delivery system.
Animals ; Calcium ; Coloring Agents ; Drug Delivery Systems ; Electric Power Supplies ; Electrodes ; Iontophoresis* ; Mice ; Mice, Hairless ; Osmium Tetroxide ; Permeability ; Ruthenium ; Skin ; Skin Absorption