Objective To investigate the application of air leak test combined with methylene blue solution leak test in the detection of anastomotic leakage after total mesorectal excision (TME) in rectal cancer. Methods In total of132 patients with rectal cancer underwent Dixon according to TME in our hospital from Mar. 2010 to Mar. 2013 were enrolled. All patients were randomly divided into air leak test group (n=65) and air leak+methylene blue solution leak test group (n=67). The intestinal anastomosis of patients in air leak test group were clamped at 2 cm from the upper endof bowel, then injecting 500 mL distilled water to pelvic, and placing 24# Foley catheter through the anus. The catheter balloon was injected with water to close anus, and then injected with 50 mL gas to find the anastomotic leakage where bubbles happened, and then repaired it. Patients of air leak+methylene blue solution leak test group were treated with methylene blue solution test in addition. After sucking out of the distilled water in pelvic and gas in the rectum, 1 bottle of methylene blue solution (20 mg) and 50 mL saline were injected, observing the location where the methylene blue solutionleaking out and repaired it. Results Three cases (4.62%) of anastomotic leakage were found during operation in air leak test group, and 9 cases (13.85%) were found after operation. Of the 9 cases, 5 cases were cured with placement of adeq-uate drainage and symptomatic treatment, 3 cases were cured with anal patch, and 1 case was cured with transverse colon fistula and drainage. In total of 15 cases (22.39%) were found anastomotic leakage, 2 cases of them were found by air leak test and another 13 cases were found by methylene blue solution leak test during operation in air leak+methylene bluesolution leak test group, but no one suffered anastomotic leakage after operation. Compared with air test group, detectionrate of anastomotic leakage during operation was higher (P<0.05), and incidence rate of anastomotic leakage after opera-tion was lower in air leak+methylene blue solution leak test group (P<0.05). Conclusions Large anastomotic leakage can be found by using air leak test, and small and hidden leakage can be found by using methylene blue solution leak test, combination method of the two experiments is better. Repair can be performed effectively under direct vision.
Objective To study the effect and intrinsic mechanism of acute suppurative peritonitis associated ascitic fluid (ASPAAF) on experimental liver injury of rats. Methods Thirty-two male or female Sprague-Dawley (SD) rats were randomly divided into two groups: ASPAAF group (n=16) and control group (n=16), in which 8 ml ASPAAF or normal saline (NS) were injected into the peritoneal cavity, respectively. The rats were killed at each time intervals after peritoneal cavity injection (6 h and 12 h) respectively in two groups and specimens were made to detect the levels of serum TNF-α, endotoxin and liver function (AST, ALT and STB). The level of TNF-α in liver tissues was measured. The pathological change of liver was observed by microscope. Results The levels of TNF-α, endotoxin, ALT, AST and STB in serum and the levels of TNF-α in liver tissues at different time points were markedly higher in ASPAAF group compared with those in control group (P<0.05), and these indexes increased with increasing time in ASPAAF group (P<0.05). In ASPAAF group, hepatic tissue appeared hydrops, even spotty necrosis and the changes at 6 h and 12 h were not obvious different. No abnormal pathological change of hepatic tissue was found in control group. Conclusion ASPAAF can induce the injury of the liver in rats, which may involved in TNF-α and endotoxin.
Objective To explore the role and intrinsic mechanism of the injury of intestines induceded by pancreatitis associated ascitic fluid (PAAF) and acute suppurative peritonitis associated ascitic fluid (ASPAAF) in rats. Methods Forty-eight Sprague-Dawley (SD) rats, male or female, were randomly divided into three groups averagely. The control group: 8 ml of normal saline (NS) was injected into the peritoneal cavity; the PAAF group: 8 ml of PAAF was injected into the peritoneal cavity; and the ASPAAF group: 8 ml of ASPAAF was injected into the peritoneal cavity. After peritoneal cavity injection, the rats were put to death in batches at 6 h and 12 h, eight rats per-batch. Levels of TNF-α and endotoxin in serum were measured. The activity of ATP enzyme and level of TNF-α in the intestinal tissues were measured. The pathological changes of intestines were observed by microscope.Results The levels of TNF-α, endotoxin and the degree of injury of the intestines were markedly elevated and the activity of ATP enzyme of the intestinal tissues was decreased in the PAAF group and ASPAAF group compared with those in the control group (P<0.05). The levels of TNF-α, endotoxin and the degree of injury of the intestines were markedly elevated and the activity of ATP enzyme of the intestinal tissues was decreased in the ASPAAF group compared with those in the PAAF group (P<0.05). Conclusion PAAF and ASPAAF can induce the injury of intestines, but the injury of intestines induced by ASPAAF is more serious.
Objective To investigate the value of color Doppler ultrasonography in the examination of perforating veins of the lower extremities by comparing with X-ray antegrade venography. Methods Fifty-three patients (60 lower extremities) clinically diagnosed with varicosis of the great saphenous vein from January 2014 to March 2016 were selected for color Doppler ultrasonography and X-ray antegrade venography. The results were compared and confirmed by surgery. Results Forty-seven lower extremities were diagnosed with perforating venous valve insufficiency by color Doppler ultrasonography, while 50 lower extremities by X-ray antegrade venography. There was no significant difference between the two methods (χ2=0.800, P=0.371). A total of 78 perforating veins were detected by color Doppler ultrasonography, with 1–4 perforating veins per one lower extremity. Among them, 66 perforating veins had an internal diameter of 2–5 mm, accounting for 84.6%. Except two perforating veins with an internal diameter <2 mm, the rest showed reflux. In addition, a total of 73 perforating veins presented distance to the pelma of 10–32 mm (foot-boot), accounting for 93.6%. Fifty-two lower extremities with varicosis of the great saphenous vein underwent laser ablation of the great saphenous vein with high ligation or + devascularization of perforating veins. Compared with operation findings, color Doppler ultrasonography in diagnosis of perforating venous valve insufficiency had 37 true positives, 2 false positives, 10 true negatives and 3 false negatives, and the sensitivity was 92.5% (37/40), the specificity was 83.3% (10/12), the accuracy rate was 90.4% (47/52). Conclusions Color Doppler ultrasonography can accurately localize perforating veins, measure the internal diameter and observe the degree of reflux. It is of high sensitivity and accuracy in the diagnosis of perforating venous valve insufficiency. Moreover, it is safe, simple and economical, and suitable for preoperative and intraoperative diagnosis and localization.