Comparative metabolism of 3H-glucosamine by fibroblast populations exposed to cyclosporine.

Cyclosporine and nifedipine therapy produces gingival overgrowth in many patients. Neither the mechanism underlying this undesirable side effect nor the possibility of synergism between these drugs is known, although many renal transplant patients receive both drugs. This study compared the rates of 3H-glucosamine utilization by three groups of fibroblasts: untreated gingival fibroblasts, fibroblasts from gingival overgrowth tissue of a patient receiving both cyclosporine and nifedipine, and normal gingival fibroblasts exposed to cyclosporine-A in vitro. Significant differences in the rates of deposition of 3H-glucosamine into the extracellular matrix by each group of gingival fibroblasts were demonstrated, suggesting that increased rates of deposition of proteoglycans into the gingival extracellular matrix by fibroblasts should be further investigated as a biologic mechanism for gingival overgrowth.

A re-evaluation of the distribution of the elastic meshwork within the periodontal ligament of the mouse.

The elastic properties of the periodontal ligament have been attributed, in part, to oxytalan fibers, as no other types of elastic fibers are described there. It has been difficult to study the periodontal elastic meshwork by standard microscopic techniques because it is partially obscured by the adjacent periodontal ligament collagen fibers. Our study employed methods which either completely or partially removed mandibular molar periodontal ligament collagen fibers, exposing a previously undescribed periodontal elastic meshwork. The periodontal elastic meshwork was composed of many elastin lamellae containing both peripheral microfibrils of regular arrangement and central microfibrils of irregular arrangement, which could only be demonstrated in oxidized tissues. Peripheral, regularly arranged bundles of microfibrils resembled oxytalan fibers, which were often adherent to the border of the elastin lamella. Elastin lamellae containing irregular microfibrils resembled elaunin fibers. These fibers probably enclosed either blood vessels, nerves or collagen fiber bundles. Peripheral microfibrils attached elaunin to cementum, alveolar bone, blood vessels, and principal periodontal collagen fibers. Thus, the periodontal elastic meshwork is composed of both oxytalan and elaunin fibers. Microfibrils attach elaunin fibers to the adjacent non-elastic tissue and also form bundles which traverse the periodontal ligament space and are probably the oxytalan fibers demonstrable by light microscopic techniques. This meshwork of oxytalan and elaunin fibers probably contributes to tooth support and maintenance of periodontal homeostasis by dissipating chewing forces and maintaining patency of periodontal blood vessels.

Preparation of bone for high-voltage electron microscopic radioautography.

This paper presents a reliable technique for the preparation of radioautographic specimens for study by high-voltage electron microscopy. Tissues are fixed by ventricular perfusion of aldehydes, sectioned, collected on slides, and coated with nuclear track emulsion using a coating machine. Sections are developed after 17 weeks' exposure in either undiluted Microdol-X or diluted D-19 developer, fixed in 25% sodium thiosulfate, and stained through the emulsion with uranyl acetate in absolute methanol and aqueous lead citrate. The technique produces sections of even thickness and staining density with negligible numbers of background grains and non-specific labeling. In this report, the efficacy of this technique for the study of the periosteal surface of demineralized alveolar bone specimens is demonstrated.

Osteodentin formation in rat incisor as visualized by radioautography after 3H-proline administration.

Osteodentin formation was studied in rat incisor pulp after adriamycin administration. Male Sprague Dawley rats (100 +/- 5 gm) were injected intravenously with adriamycin (5 mg/kg body weight), and after 7 days they were again injected intravenously with 3H-proline (3 microCi/gm). These animals were killed in groups of three from 5 minutes to 4 hours after proline injection by perfusion with 3% phosphate-buffered formaldehyde followed by 2.5% phosphate-buffered glutaraldehyde. Control animals injected with only physiological saline, and 7 days later with 3H-proline (3 microCi/gm), and were killed at the same time intervals. Radioautography on sections showing osteodentin formation revealed that at 5 minutes after 3H-proline injection the labeling was located over the cells associated with the osteodentin matrix. At 1 hour after injection the labeling was located over the cells and the matrix, while at 4 hours the labeling was seen only over the matrix. It therefore appears that at least a proline-containing component of the osteodentin matrix is synthesized and secreted by the cells associated with it.

The effect of streptozotocin on the secretory activity of ameloblasts in rat incisor as revealed by radioautography after 3H-proline administration.

The effect of a diabetogenic dose of streptozotocin on the secretory activity of ameloblasts was investigated in the rat incisor by radioautography. One group of male Sprague-Dawley rats was injected intravenously with streptozotocin in citrate buffer (pH 4.5). One hour later, this group was again injected intravenously with 3H-proline (2 mCi/kg). A control group of animals was injected with 3H-proline only. All the animals were sacrificed in groups of three at 5 min, 1 h, 2 h, 4 h and 8 h after 3H-proline injection by perfusion with 3% phosphate-buffered formaldehyde followed by an additional perfusion with 2.5% phosphate-buffered glutaraldehyde. The incisors were extracted with the jaws, demineralized, and prepared for radioautographic observations and analysis. The principal effects of streptozotocin were as follows: There was an inhibition of 3H-proline incorporation into the secretory ameloblasts at 5 min after injection. This was followed by a larger uptake and a slower passage of the label out of the cells into the enamel matrix than that seen in the control sample. Finally, there was a slower secretion of labeled proteins out of Tomes' processes between 1 and 4 h after injection. Therefore, streptozotocin had a temporary inhibitory effect on the incorporation and secretion of 3H-proline by the secretory ameloblasts of the rat incisor. This effect was present for about 4 h and was completely reversed 9 h after streptozotocin injection.

The extent of the necrotic lesion in the apical end of the rat incisor pulp seen after Adriamycin administration.

The extent of the necrotic lesion produced by adriamycin in the apical end of the rat incisor was investigated. Male Sprague Dawley rats were injected intravenously with adriamycin (5 mg/kg body weight), and sacrificed by perfusion with a 2.5% buffered glutaraldehyde solution 1 d after injection. Controls injected with only physiological saline were treated in the same manner. One micron thick plastic serial sections were prepared from the apical end of the incisor, and a schematic representation of the entire lesion as seen in longitudinal section was reproduced from each fiftieth section. Cell destruction was observed for 2.2 mm within the pulp. The lesion extended further incisally in the lingual portion than in the labial portion. The bulbous portion of the odontogenic organ was not affected. This study indicates that the cytotoxicity of adriamycin appears to affect mainly proliferating immature precursor cells within the mesenchyma, and the preodontoblasts.