Caudal anesthesia for total hip replacement in geriatric patients has been evaluated clinically. The caudal epidural puncture was performed by a 22 G short needle through sacral hiatus with a lateral decubitus position. 1.5% lidocaine 20 mL and 0.5% bupivacaine 15 mL mixed with 1:200,000 epinephrine and 2 mg morphine was used as an anesthetics. The results were follows ; 1) The onset of caudal anesthesia was 7.9+/-4.5 min (2-20 min) and the duration was 4.8+/-3.0 hrs (1-12 hrs). 2) Anesthetic sensory level was not related with the patient's weight or height. 3) The failure rate including systemic toxicity was 13%. 4) The most common complication was hypotension and its incidence was 26.6%. 5) Time to first analgesics was 8.3+/-3.6 hrs. These results indicate that caudal anesthesia in lateral decubitus position is a recommendable anesthetic technique for total hip replacement in geriatric patients. However, the further studies for the determinations of the optimum dose of local anesthetics are needed.
Analgesics ; Anesthesia, Caudal* ; Anesthetics ; Anesthetics, Local ; Arthroplasty, Replacement, Hip* ; Bupivacaine ; Epinephrine ; Geriatrics ; Humans ; Hypotension ; Incidence ; Lidocaine ; Morphine ; Needles ; Punctures

No abstract available.
Lung Neoplasms* ; Lung* ; Neoplasm Metastasis* ; Toes*

PURPOSE: To describe the HRCT and pathologic findings of squalene-induced lipoid pneumonia in rabbits. MATERIALS AND METHODS: Three ml of squalene was instilled into the trachea between the second and the third tracheal ring in 16 rabbits. Serial HRCT scans were obtained on day 4 (n=8), at 1 week (n=7), 2 weeks (n=1), 4 weeks(n=1), 6 weeks (n=2) and 20 weeks (n=1) after squalene instillation. With sacrifice of the rabbits pathology was reviewed at 1 week (n=3), 4 weeks (n=3), and 6 weeks (n=4) after CT scans. RESULTS: Lipoid pneumonia was induced in 8 rabbits; lesions were distributed mainly in the dependent posterior lung. On serial HRCT scans, airspace consolidation, as seen on an air-bronchogrm, and nodular opacities were early findings; these gradually diminshed and with time were replaced by nodular & linear opacities. Histologically, pulmonary fibrosis appeared one week after squalene instillation and progressed over time. Alveolar septal thickening and cuboidal change of the alveolar lining epithelium were more prominent at week 6. CONCLUSION: The early change of squalene-induced lipoidpneumonia in rabbits is the proliferation of intraalveolar macrophage, which is responsible for air-space consolidation with air-bronchograms on HRCT. Nodular and linear opacities on HRCT are due to the appearance of pulmonary fibrosis one week after squalene instillation, and its subsequent progression.
Animals ; Epithelium ; Lung ; Macrophages ; Pathology ; Pneumonia* ; Pulmonary Fibrosis ; Rabbits* ; Squalene ; Tomography, X-Ray Computed ; Trachea

Krukenberg tumor is comparatively rate in metastatic ovarian tumor and is almost metastasized from gastrointestinal tract. We have experienced one case of tumor of unidentified primary focus and two coases of metastatic Krukenberg tmor from stomach and report this cases with a brief review of literatures.
Gastrointestinal Tract ; Krukenberg Tumor* ; Stomach

To determine the effects of hydrcxyethyl starch upon liver, kidney, serm electrolytes and particularly upon blood coagulation, 500 ml of 6% HES in saline solution was administered intravenously to 15 patients during elective minor surgery. In all cases weighted blood loss was less than 600 ml without replacement. The following laboratory tests were performed immediately before infusion and again 1 hour, 24 hours, 48 hours, and 1 week after the infusion: RBC, WBC, hemoglobin, hematocrit, ESR, platelet, bleeding time, coagulation time, prothrombin time, total protein, albumin, total bilirubin, direct bilirubin, SGOT, SGPT, alkaline phosphatase, BUN, sodium, potassium, and chloride. The results are as follows: 1) No anaphylactic shock or bleeding tendency characteristic of colloids was encountered. 2) No functional disturbance of liver or kidney directly attributable to HES was identified. 3) All laboratory parameters except WBC and ESR decreased after infusion. The decrease was, however, within the normal range and believed secondary to dilational effect of infusion. WBC increased somewhat, but returned to the preinfusion level in a week. 4) Exceptionally erythrocyte sedimentation rate increased notably during the 24 hour period following infusion. As with dextran, this was interpreted not due to direct effect of HES, but due to increased adsorption of fibrinogen, alpha-beta-gamma-glcbulin to red cell surface with changes in electric charge between red cells. 5) Clinical applicability, metabolic aspect, degree of subtitution of hydroxyethyl group and safety with multiple infusion of HES must be carefully determined.
Adsorption ; Alanine Transaminase ; Alkaline Phosphatase ; Anaphylaxis ; Aspartate Aminotransferases ; Bilirubin ; Bleeding Time ; Blood Coagulation ; Blood Platelets ; Blood Sedimentation ; Colloids ; Dextrans ; Electrolytes ; Fibrinogen ; Hematocrit ; Hemorrhage ; Humans ; Kidney ; Liver ; Potassium ; Prothrombin Time ; Reference Values ; Selective Estrogen Receptor Modulators ; Sodium ; Sodium Chloride ; Starch* ; Surgical Procedures, Minor

No abstract available.
Lasers, Solid-State* ; Papilloma*

PURPOSE: To evaluate the effect of respiration on the sizes of intrathoracic vasculature, and the trachea,and the main bronchus. MATERIALS AND METHODS: Seventeen volunteers (10males aged 20-39 years and 7 females aged20-39 years) underwent spiral CT, between the apex and lowest base of the lung, collimation was 10mm, pitch was 1,and images were obtained at breath hold forced end-inspiration and breath hold forced end-expiration. Crosssecional areas or diameters were measured in each respiration state at the aorta (ascending, descending, lowerthoracic) and great branches, the IVC (thoracic, abdominal), the SVC, pulmonary artery (right main, leftdescending) and the tracheobronchus (trachea, left upper bronchus). Changes in the size of vessels and airwaysbetween the respiration states were evaluated and compared between inspiration and expiration. RESULT: Duringbreath-hold forced end-inspiration CT, the ascending, descending, and lower thoracic aorta and itsbranches(brachiocephalic, left common carotid, left subclavian) as well as the thoracic IVC and SVC and the rightmain and left descending pulmonary arteries decreased in size: during breath-hold forced end-expiration CT, thesize of all these vessels increased. For the trachea, left upper lobe bronchus and abdominal IVC, the situationwas reversed. Statistically significant changes(p<0.05) were noted in the ascending aorta and descending aorta,the lower thoracic aorta, the thoracic and abdominal IVC, the SVC, the right main and left pulmonary arteries, andthe trachea. CONCLUSION: During respiration, changes in the size of the thoracic vasculature and airways isprobably due to changes in intrathoracic pressure. In the measurement and diagnosis of stenosis or dilatation inthe intrathoracic vesculature and airways, respiration states should therefore be considered.
Aorta ; Aorta, Thoracic ; Bronchi* ; Constriction, Pathologic ; Diagnosis ; Dilatation ; Female ; Humans ; Lung ; Pulmonary Artery ; Respiration* ; Tomography, Spiral Computed ; Trachea* ; Volunteers

PURPOSE: To determine optimal window settings for measuring the inner diameter of the trachea and both mainbronchi by spiral CT. MATERIALS AND METHODS: Chest PA radiography and spiral CT scanning were performed in ten healthy adult volunteers. Three dimensional images were reconstructed (minimal threshold value : -1000HU ; maximal threshold value : from -200 to -900HU, of 50HU intervals) to measure the inner diameter of the trachea and both main bronchi. The results of 3D spiral CT were compared with those of chest radiography. RESULTS: The inner diameters of the trachea, right main bronchus, left main bronchus-I (1cm below the tracheal carina) and left mainbronchus-II (2cm below the tracheal carina) measured by chest radiograph and 3D spiral CT were not significantly different at maximal threshold values of -400 ~ -550HU, -450 ~ -550HU, -450 ~ -600HU and -500 ~ -600HU, respectively (p>0.05). The differences in the results of the two series were statistically significant at other threshold values however (p<0.05). CONCLUSION: We determined optimal window settings for measuring the inner diameter of the trachea and both main bronchi by spiral CT. The optimal maximal threshold values were somewhat different according to measured sites of the trachea and both main bronchi.
Adult ; Bronchi ; Humans ; Radiography ; Radiography, Thoracic ; Thorax ; Tomography, Spiral Computed* ; Trachea ; Volunteers

PURPOSE: To evaluate the changes and normal ranges of the artery-bronchus ratio (ABR) during respiration MATERIALS AND METHODS: We analyzed HRCT of 10 healthy adults. The HRCT findings of ten healthy adults were analysed. CT scanning was performed with 1 mm collimation at 3 mm intervals during full inspiration and full expiration, with a range during inspiration from 2 cm to 4 cm above the carina and from 4 cm above to 2 cm below the right hemidiaphragm. The range during expiration was from 1 cm to 3 cm above the carina and from 4 cm above to 2 cm below the right hemidiaphragm. ABiR (defined as the diameter of pulmonary artery divided by the inner diameter of the bronchus), ABoR (defined as the diameter of pulmonary artery divided by the outer diameter of the bronchus) and BLR (defined as the inner diameter of the bronchus divided by the outer diameter of the bronchus) were measured on the display console. RESULTS: The mean inner diameter of the bronchi was 2.04+/-0.73 mm during inspiration and 1.68+/-0.51 mm during expiration, while the mean diameter of the arteries was 3.95+/-1.03 mm during inspiration and 4.37+/-1.09 mm during expiration. The diameters of the bronchi were thus seen to increase during inspiration, and the diameters of the pulmonary arteries, to decrease. The mean thickness of the bronchial wall was 1.07+/-0.19 mm during inspiration and 1.06+/-0.24mm during expiration; thus, no change in thickness was seen during respiration (p<0.05). Mean ABiR was 2.01+/-0.60 (range 1.15-4.58) during inspiration and 2.59+/-0.74(range 1.16-4.9) during expiration, and in all cases the inner diameter of the bronchus was less than that of the accompanying pulmonary artery. Mean ABoR was 0.91+/-0.19 during inspiration and 1.09+/-0.22 during expiration. while for BLR, the corresponding fingures were 0.46+/-0.06, and 0.44+/-0.09. CONCLUSION: HRCT is a useful tool for evaluating changes in the pulmonary arteries and bronchi during respiration.
Adult ; Arteries ; Bronchi ; Humans ; Pulmonary Artery ; Reference Values ; Respiration* ; Tomography, X-Ray Computed

PURPOSE: To evaluate the usefulness of spiral CT in the measurement of lung volumes. MATERIALS AND METHODS: Fifteen healthy volunteers were studied by both spirometer and spiral CT at full inspiration and expiration inorder to correlate their results, including total lung capacity (TLC), vital capacity (VC) and residual volume(RV). 3-D images were reconstructed from spiral CT, and we measured lung volumes at a corresponding CT window range ; their volumes were compared with the pulmonary function test (paired t-test). RESULTS: The window range corresponding to TLC was from -1000HU to -150HU (p=0.279, r=0.986), and for VC from -910HU to -800HU (p=0.366,r=0.954) in full-inspiratory CT. The optimal window range for RV in full-expiratory CT was from -1000HU to -450HU (p=0.757, r=0.777), and TLC-VC in full-inspiratory CT was also calculated (p=0.843, r=0.847). CONCLUSION: Spiral CT at full inspiration can used to lung volumes such as TLC, VC and RV.
Healthy Volunteers ; Imaging, Three-Dimensional ; Lung* ; Respiratory Function Tests ; Tomography, Spiral Computed* ; Total Lung Capacity ; Vital Capacity