The structure of 39 specimens of hepatobiliary duct stones with strictures were studied histologically. The elastic and collagenous fibers were studied by quantitative analysis. The results show that the epithelium of the sttnotic bile duct are intact but with proliferation. The mitochondrions are degenerated and broken, the endoplasmic reticulum are dilated, suggesting the functional impediment of these epithelium. The mucous glands are markedly proliferated fibrosis are found near the glands which are destroyed .Some of the elastic fibers are destroyed and arranged disorderly . Hyaline degeneration was observed in collagenous fibers with remarkable increase of the volume density.
Objective To review the strategies on repairing elastic fibers in aorta. Methods Literature concerningelastic fiber as well as its repairment was consulted and summarized from three aspects: enhancement of the expressions ofits components, improvement of the condition of its assembly, and reduction of the destructive effects. Results Elastinis concerned as the main protein to be enhanced with three different methods including gene transfection, stimulationwith ectogenesis factors, and induction of phenotype transition of smooth muscle cell. Fibul in and lysyl oxidases show theabil ity to improve the assembly of the elastic fiber, while the related mechanisms are not clear. Matrix metalloproteinasesare regarded as the main destructive factors, and researches focus on reducing their expression as well as their destructiveeffects. Conclusion To assure a high-qual ity repair of elastic fibers in aorta, their components should be sufficientlyexpressed and effectively assemblyed, and the destructive effects caused by dangerous factors should also be reduced.
OBJECTIVE: To observe the architecture of elastic fiber of anastomosed artery. METHODS: The right femoral arteries of 60 Wistar rats were cut off transversely and end-to-end anastomosis were performed. On the 3rd, 7th, 14th, 21st, 30th and 90th days after operation, the anastomosed artery segments were harvested and fixed by 10% formalin. After routine processed, the architecture of elastic fiber of anastomosed artery was observed under scanning electronic microscope and was compared with that of normal artery. RESULTS: On the 3rd and 7th days after anastomosis, there was no the elastic fiber in the middle of the anastomosed area. From 14 to 90 days after anastomosis, the newborn elastic fiber connected the anastomosed area. The reconstruction of elastic fiber could be divided into quiescent stage, proliferation stage, and rebuilding stage. CONCLUSION: The reconstruction of elastic fiber occurs after arterious anastomosis and newborn elastic fiber originates from endoarterious layer. The structure of elastic fiber can return to normal 30 days after anastomosis.