目的 分析彩色多普勒超声对肝硬化患者门静脉血流改变的评价作用。 方法 选择2010年1月-2011年4月收治的50例肝硬化患者作为观察组,其中代偿期患者27例,失代偿期患者23例;同时设置健康对照组50名,比较两组的门静脉内径(Dpv)、门静脉平均血流速度(Vpv)、门静脉血流量(Qpv)。 结果 观察组患者的Dpv增宽,Vpv减慢,Qpv减少,与对照组比较,差异均有统计学意义(P<0.05);且失代偿期患者的改变更为明显,与代偿期患者间差异有统计学意义(P<0.05)。 结论 彩色多普勒超声检查门静脉血流改变可以对肝硬化患者进行初步确诊。
Objective To observe the time-intensity curve characteristics of contrast agents in intraocular tumor. Methods A total of 236 patients (238 eyes) with intraocular tumor were enrolled in this study. All the patients received regular ophthalmologic examination, two dimensional ultrasound, color doppler ultrasonography and contrast-enhanced ultrasonography. There were 166 patients (166 eyes) with choroidal melanoma, 16 patients (18 eyes) with choroidal metastatic carcinoma, 52 patients (52 eyes) with choroidal hemangioma, two patients (two eyes) with retinal hemangioma. The whole process of contrast-enhanced ultrasound were recorded, and exported as t images of Dicom format. These images were processed by Sonoliver software (Tomteck Company, Germany) to drawn the time-intensity curve of contrast agents in the intraocular tumors. Results All intraocular lesions were completely filled with contrast agent, concentric filling from the periphery to the center can be documented in some cases. The time-intensity curve of choroidal hemangioma and retinal hemangioma were basically the same. The time-intensity curve of choroidal melanoma and choroidal metastatic carcinoma were also basically the same. In the filling phase, all tumors were rapid filling type. In the regression phase, contrast agent subsided earlier than in control tissue within the melanoma or metastatic carcinoma lesions, but subsided synchronous or slightly faster than in control tissue within the choroidal hemangioma and retinal hemangioma lesions. Among 166 eyes with choroidal melanoma, 138 eyes (83.1%) were in full compliance with the above changes, 28 eyes (16.9%) were largely in line with these changes. All the eyes (100.0%) with choroidal metastatic carcinoma, choroidal hemangioma and retinal hemangioma were in full compliance with the above changes. Conclusion Time-intensity curve is quickly filling and fast regression for malignant intraocular tumors, but is quickly filling and slow regression for benign intraocular tumors.
OBJECTIVE: To study the effect of color doppler flow imaging(CDFI) technique in the design of axial pattern flap. METHODS: From April 1996 to June 1999, 10 patients with residual wound were adopted in this study. Among them, there were seven males and three females, the area of wounds ranged from 6 cm x 8 cm to 15 cm x 20 cm. Before operation, the axial pattern flaps were designed by traditional method, then CDFI technique with high frequency(5.0-7.5 MHz) was used for examining the major supply artery of the flap. At last, the modified flaps were transferred to cover the wounds. RESULTS: All the patients except one case completed the operation successfully. The cosmetic and function of the flaps were excellent. CONCLUSION: CDFI is a simple, direct and accurate method for detecting the supply artery of axial pattern flap. This technique should be popularized to avoid the blindness of flap design.
Objective To compare canine decel luarized venous valve stent combining endothel ial progenitor cells (EPC) with native venous valve in terms of venous valve closure mechanism in normal physiological conditions. Methods Thirty-six male hybrid dogs weighing 15-18 kg were used. The left femoral vein with valve from 12 dogs was harvested to prepare decelluarized valved venous stent combined with EPC. The rest 24 dogs were randomly divided into the experimental group and the control group (n=12 per group). In the experimental group, EPC obtained from the bone marrowthrough in vitro ampl ification were cultured, the cells at passage 3 (5 × 106 cells/mL) were seeded on the stent, and the general and HE staining observations were performed before and after the seeding of the cells. In the experimental group, allogenic decelluarized valved venous stent combined with EPC was transplanted to the left femoral vein region, while in the control group, the autogenous vein venous valve was implanted in situ. Color Doppler Ultrasound exam was performed 4 weeks after transplantation to compare the direction and velocity of blood flow in the distal and proximal end of the valve, and the changes of vein diameter in the valve sinus before and after the closure of venous valve when the dogs changed from supine position to reverse trendelenburg position. Results General and HE staining observations before and after cell seeding: the decelluarized valved venous stent maintained its fiber and collagen structure, and the EPC were planted on the decelluarized stent successfully through bioreactor. During the period from the reverse trendelenburg position to the starting point for the closure of the valve, the reverse flow of blood occurred in the experimental group with the velocity of (1.4 ± 0.3) cm/s; while in the control group, there was no reverse flow of blood, but the peak flow rate was decreased from (21.3 ± 2.1) cm/s to (18.2 ± 3.3) cm/s. In the control group, the active period of valve, the starting point for the closure of the valve, and the time between the beginning of closure and the complete closure was (918 ± 46), (712 ± 48), and (154 ± 29) ms, respectively; while in the experimental group, it was (989 ± 53), (785 ± 43), and (223 ± 29) ms, respectively. There was significant difference between two groups (P lt; 0.05).After the complete closure of valve, no reverse flow of blood occurred in two groups. The vein diameter in the valve sinus of the experimental and the control group after the valve closure was increased by 116.8% ± 2.0% and 118.5% ± 2.2%, respectively, when compared with the value before valve closure (P gt; 0.05). Conclusion Canine decelluarized venous valve stent combined with EPC is remarkably different from natural venous valve in terms of the valve closure mechanism in physiological condition. The former rel ies on the reverse flow of blood and the latter is related to the decreased velocity of blood flow and the increased pressure of vein in the venous sinus segment.