For adult rats fed on the following six kinds of diets for about 80 days, intermediate metabolic substrates in serum, liver and skeletal muscle were determined. The components of feeding diet are as follows:
1. STANDARD DIEF : 18% protein, 100 oil & 65% dextrin.
2. HIGH PROTEIN-HIGH FAT DIET: 29% protein, 25% oil & 39% dextrin.
3. LOW PROTEIN-LOW FAT DIET: 9% protein, 2% oil & 82% dextrin.
4. STANDARD DIET modified with choline chloride & vitamin B, C & E.
5. HIGH PROTEIN-HIGH FAT DIET modified with choline chloride & vitamin B, C & E.
6. LOW PROTEIN-LOW FAT DIET modified with choline chloride & vitamin B, C & E. (reference : 1, 2, 3 ; due to National Institute of Nutrition)
As the results increase of body weight was the least 3rd diet group, and by addition of choline chloride (above 4th, 5th & 6th diet groups) it were generally inhibited. Especially the latter phenomenon was remarkably observed in 6th diet group. Although intermediate metabolic substrates in skeletal muscle were no difference from their control levels, triglyceride and cholesterol of liver reduced also in 4th, 5th & 6th diet group, and FFA level of it increased on contrary. The triglycerides of interscapular brown fat and white fat of epididymis reduced in 4th, 5th & 6th diet groups. Furthermore, increase of triglyceride, FFA and cholesterol in serum observed in above 4th, 5th & 6th diet group, which will suggest that they might be removed from brown or white fat and choline chloride might play an important role of lipid-releasing effect from those tissues.

Background/Aims: Magnifying endoscopic classification systems, such as the Japan narrow-band imaging (NBI) Expert Team (JNET) classification, have been widely used for predicting the histologic diagnosis and invasion depth of colorectal epithelial tumors. However, disagreement exists among observers regarding magnifying endoscopic diagnosis, because these classification systems are subjective. We herein investigated the utility of endoscopic microvascular density (eMVD) calculated from magnifying NBI endoscopic images in colorectal tumors. Methods: We reviewed magnifying NBI endoscopic images from 169 colorectal epithelial tumors (97 adenomas, 72 carcinomas/high-grade dysplasias) resected endoscopically or surgically. The eMVD on magnifying NBI endoscopic images was evaluated using image-editing software, and relationships between eMVD and clinical, endoscopic, and pathological findings were retrospectively analyzed. Results: The eMVD in carcinomas (0.152 ± 0.079) was significantly higher than that in adenomas (0.119 ± 0.059, P< 0.05). The best cutoff value for distinguishing carcinoma from adenoma was 0.133. Sensitivity, specificity, and accuracy were 56.9%, 67.0%, and 62.7%, respectively. In addition, JNET type 2B tumors showed significantly higher eMVD (0.162 ± 0.079) compared to type 2A tumors (0.111 ± 0.050, P< 0.05). Conclusions The eMVD as determined by magnifying NBI endoscopy is considered to be a possible objective indicator for differentiating colorectal carcinomas from adenomas.

BACKGROUND: Glyphosate and its salt formulations are nonselective herbicides that have been extensively used worldwide, both for residential and agricultural purposes. The possible carcinogenicity and teratogenicity of glyphosate remain to be elucidated. We developed a sensitive and high-throughput analytical method for urinary glyphosate using liquid chromatography-tandem mass spectrometry with the aim of contributing to glyphosate exposure assessment in epidemiological studies. METHODS: After urine dilution (creatinine matching dilution to 0.05 g creatinine/L), glyphosate was extracted using two types of solid phase extraction columns (SCX and NH2) with automated sample preparation instruments. The eluate was dried and dissolved in the mobile phase, followed by liquid chromatography-tandem mass spectrometry analysis. The optimized method was applied to urine samples obtained from 54 Japanese adults and children. RESULTS: The results from the validation study demonstrated good recoveries (91.0-99.6%), within- and between-run precisions (< 15%), low detection limits (0.1 μg/L), and lower limit of quantification (0.3 μg/L). The detection frequency and median concentration of the urinary glyphosate in Japanese subjects were 59% and 0.25 μg/L (0.34 μg/g creatinine). CONCLUSIONS Our reliable determination method was successful in measuring urinary glyphosate concentration. Moreover, this is the first biomonitoring report of urinary glyphosate levels in the Japanese general population.
Adult ; Aged ; Chromatography, Liquid/methods* ; Female ; Glycine/urine* ; Humans ; Male ; Middle Aged ; Solid Phase Extraction/methods* ; Tandem Mass Spectrometry/methods*