OBJECTIVES: Gastric resection may predispose gallstone formation. However, the mechanism has not been clearly understood. To evaluate the relationship between gastric resection and gallstone formation, we compared gallbladder(GB) motility in gastrectomized patients and control subjects. METHODS: We compared the GB volume and ejection fraction of the 46 gastrectomized patients with 37 healthy controls using real time ultrasonography. RESULTS: GB volume increased significantly in the gastrectomized group in fasting (30.2 13.9 ml). The GB volume after a fatty meal was greater in the gastrectomized group (12.6 6.4 ml) than in the control group (4.3 3.3 ml) (p +ADw- 0.01). A significant reduction of ejection fraction was found in gastrectomized patients (56.9 13.0+ACU-) in comparison with the control group (75.5 16.1+ACU-) (p +ADw- 0.01). The GB ejection fraction had a poor correlation to the postoperative period (r +AD0- 0.232). CONCLUSION: A gastrectomy appears to be a risk factor of GB dysmotility, which may play a major role in gallstone formation in gastrectomized patients.
Adult ; Aged ; Cholelithiasis/ultrasonography ; Cholelithiasis/etiology+ACo- ; Comparative Study ; Eating ; Endosonography ; Fasting ; Female ; Gallbladder/ultrasonography ; Gallbladder/physiopathology+ACo- ; Gallbladder Emptying ; Gastrectomy/adverse effects+ACo- ; Gastrointestinal Motility ; Human ; Male ; Middle Age ; Probability ; Prospective Studies ; Reference Values ; Risk Assessment ; Stomach Neoplasms/surgery+ACo-

The purpose of the present study was to evaluate the expression of cardiac marker protein in rabbit cardiac tissue that was exposed to ischemic preconditioning (IPC), or ischemiareperfusion injury (IR) using two-dimensional gel electrophoresis (2DE) and matrix-assisted laser desorption ionization mass spectrometry (MALDI-MS). We compared 2DE gels of control (uninjured) cardiac tissue with those of IPC and IR cardiac tissue. Expression of one protein was detected in IR heart tissue, however the protein was not detected in the samples of control and IPC tissue. To further characterize the detected protein molecule, the protein in the 2D gel was isolated and subjected to trypsin digestion, followed by MALDI-MS. The protein was identified as myoglobin, which was confirmed also by Western blot analysis. These results are consistent with previous studies of cardiac markers in ischemic hearts, indicating myoglobin as a suitable marker of myocardial injury. In addition, the present use of multiple techniques indicates that proteomic analysis is an appropriate means to identify cardiac markers in studies of IPC and IR.
Blotting, Western ; Digestion ; Electrophoresis, Gel, Two-Dimensional* ; Gels ; Heart ; Ischemia* ; Ischemic Preconditioning ; Mass Spectrometry* ; Myoglobin ; Reperfusion Injury* ; Reperfusion* ; Spectrometry, Mass, Matrix-Assisted Laser Desorption-Ionization ; Trypsin

Mitochondrial ATP-sensitive potassium (mitoKATP) channels play a role in early and late ischemic preconditioning. Nevertheless, the subunit composition of mitoKATP channels remains unclear. In this study, we investigated the subunit composition of mitoKATP channels in mitochondria isolated from rat cardiac myocytes. Mitochondria were visualized using the red fluorescence probe, Mitrotracker Red, while mitoKATP channels were visualized using the green fluorescence probe, glibenclamide-BODIPY. The immunofluorescence confocal microscopy revealed the presence of Kir6.1, Kir6.2 and SUR2 present in the cardiac mitochondria. Western blot analysis was carried to further investigate the nature of mitoKATP channels. For SUR proteins, a 140-kDa immunoreactive band that corresponded to SUR2, but no SUR1 was detected. For Kir6.2, three bands (~4, ~6, and ~0 kDa) were detected, and a specific ~6-kDa immunoreactive band corresponding to Kir6.1 was also observed. These observations suggest that the subunits of mitoKATP channels in rat myocytes include Kir6.1, Kir6.2, and a SUR2-related sulfonylurea-binding protein.
Animals ; Blotting, Western ; Fluorescence ; Fluorescent Antibody Technique ; Ischemic Preconditioning ; KATP Channels* ; Microscopy, Confocal ; Mitochondria ; Muscle Cells ; Myocytes, Cardiac* ; Potassium ; Rats*