OBJECTIVE: To summarize the importance of surgical management to repair vascular injury in limbs salvage, and to analyze the influence factors in the management. METHODS: From 1993 to 2000, 42 cases of 58 vascular injuries were reviewed; there were 37 males and 5 females, aging from 12 to 70 years old. Emergency operations were performed in 38 cases and selective operations in 4 cases from 1 hour to 45 days after injury. There were 22 cases of complete rupture in 32 blood vessels, 5 cases of partial rupture in 6 blood vessels, and 15 cases of vascular defect in 20 blood vessels, with 5 cm to 10 cm defect. The operation management included end-to-end anastomosis in 22 cases, side-to-end anastomosis in 1 case, vascular repair in 5 cases and vascular grafting in 14 cases. All of the cases were followed up for 6 months to 7 years. RESULTS: In those received emergency operations, it was successful in 35 cases, with amputation in the other 3 cases; after operation, there were 5 cases of post-operative angio-crisis, 1 case of hematoma and 1 case of pseudoaneurysm. In those received selective operation, all succeeded but 1 case of post-operative angio-crisis. After the follow-up, except for 3 cases of amputation, the other limbs survived; and function of the survived limbs recovered satisfactorily after operation except poor recovery in 7 cases of replantation of the limbs. CONCLUSION: To repair vascular injury immediately, to manage angio-crisis and to remove influence factors is the key to save the injured limbs and to maintain the function of them.
Objective To evaluate the influence of the location of retinal vessel trunk on neuroretinal rim width of inferior and superior sectors of optic disc, and explore its role in the diagnosis of glaucomatous optic nerve lesion. Methods The photographs of ocular fundus from 459 patients with clear location of retinal vessel trunk, including large disc in 131, medium disc in 145, horizontally oval disc in 75, and small disc in 108 were evaluated. Independent-sample t test was used to compare the difference of the superior and inferior rim widths between the higher-vessel group and the lower-vessel group, and to compare the difference of superior and inferior vessel distances between the narrow-superior-rim-width group and the narrow inferior-rim-width group. Results In most of the patients, or the ones with large and small disc, the ratio of superior rim width to summation of superior and inferior rim widths in the higher-vessel group(0.467plusmn;0.051,0.445plusmn;0.040,0.508plusmn;0.056)were less than which in the lowervessel group(0.500plusmn;0.066,0.474plusmn;0.062,0.546plusmn;0.048), and the differences were significant(P=0.000, 0.045, 0.018); the ratio of superior vessel distance to summation of superior and inferior vessel distance in the narrow-superior-rim-width group(0.510plusmn;0.051,0.508plusmn;0.055,0.512plusmn;0.036)were less than which in the narrow-inferior-rim-width group(0.528plusmn;0.045,0.533plusmn;0.048,0.534plusmn;0.045), and the differences were significant(P=0.000, 0.046, 0.022). Conclusions The position of optic disc vessel trunk influences its superior and inferior rim width. The rim closer to vessel trunk position has narrower width than which comparatively far away from the position. In patients with large, medium, horizontally oval optic disc, glaucoma optic nerve lesion would be considered if the optic disc has the shape of narrower inferior rim, broader superior rim, and vessel location in the superior half of the disc. In the ones with small disc, the optic disc with the shape of narrower superior rim, broader inferior rim, and vessel location in the inferior half of the disc may suggest glaucoma optic nerve lesion. (Chin J Ocul Fundus Dis, 2007, 23: 118-121)
Organoids are three-dimensional structures formed by self-organizing growth of cells in vitro, which own many structures and functions similar with those of corresponding in vivo organs. Although the organoid culture technologies are rapidly developed and the original cells are abundant, the organoid cultured by current technologies are rather different with the real organs, which limits their application. The major challenges of organoid cultures are the immature tissue structure and restricted growth, both of which are caused by poor functional vasculature. Therefore, how to develop the vascularization of organoids has become an urgent problem. We presently reviewed the progresses on the original cells of organoids and the current methods to develop organoids vascularization, which provide clues to solve the above-mentioned problems.