Twenty six healthy males, 60-70 years old, having the same vitamin C nutritional status detected by saturation test were selected for this study. They were divided into 4 groups and supplemented orally with various amounts of vitamin C for 15 days. The intake of each group was 59, 94, 149 and 223 ing/day per capita respectively. After comparing the vitamin C contents of 4-hour saturation test urine and early morning 1 hour fasting urine at the end of the experiment, it seems that the optimal daily requirement for the elderly is about 95 mg, and the saturated daily requirement is a little higher than 223 mg.

The age-related changes of serum lipid peroxide (LPO), RBC supero-xide dismutase activity (SOD) and glutathione peroxidase activity (GSH-Px), Cu, Zn and Se of blood were observed in 217 normal male persons aged 6~82. It was found that LPO increased significantly with age and SOD, GSH-Px decreased significantly in the elderly (60-70yrs). Blood Zn, Cu and Zn/Cu were highest in the childhood and lowest in the elderly. No significant change of Se with age was observed.The stepwise regression analysis showed that the factors influencing aging mainly were LPO and GSH-Px. It seems that LPO can be used as an indicator of aging.LPO was positively but GSH-Px, SOD, Zn and Cu negatively correlated with aging.

OBJECTIVETo analyze the correlation between the genotype and phenotype of 18q deletion syndrome with chromosome microarray analysis (CMA).

METHODSEight cases with 18q deletion syndrome were selected, including two affected fetuses and six children patients. DNA was extracted and hybridized with Affymetrix CytoScan TM 750K arrays following the manufacturer's standard protocol. The data was analyzed with a special software package.

RESULTSCMA analysis identified pathogenic copy number variations (CNVs) on 18q in all cases, which ranged from 6.612 Mb to 22.973 Mb. NFATC1, GALR1, MBP, SALL3 and TSHZ1 are likely to be causative genes for congenital heart disease, psychological, growth retardation, and cleft palate.

CONCLUSIONCMA can precisely locate the breakpoints of 18q and facilitate definition of the genotype-phenotype correlations, which is useful for prognosis.

Child, Preschool ; Chromosome Deletion ; Chromosome Disorders ; genetics ; Chromosomes, Human, Pair 18 ; genetics ; DNA Copy Number Variations ; Female ; Humans ; Infant ; Male ; Microarray Analysis

ObjectiveUltra-high performance liquid chromatography-quadrupole-electrostatic field orbitrap high resolution mass spectrometry（UHPLC-Q-Orbitrap HRMS） was used to identify the metabolites of limonin in rats， and to explore the gender differences in the distribution of prototype components and metabolites in rats after single dose intragastric administration of limonin， as well as to speculate the metabolic pathways. MethodThe separation was performed on a Thermo Scientific Accucore™ C₁₈ column（3 mm×100 mm， 2.6 μm） with 0.1% formic acid aqueous solution（A）-0.1% formic acid acetonitrile solution（B） as mobile phase in a gradient elution mode（0-1 min， 5%B； 1-6 min， 5%-20%B； 6-18 min， 20%-50%B； 18-23 min， 50%-80%B； 23-25 min， 80%-95%B； 25-30 min， 95%B） at a flow rate of 0.3 mL·min^-1 and a column temperature of 30 ℃. MS data of biological samples were collected under the positive ion mode of electrospray ionization（ESI） and in the scanning range of m/z 100-1 500. Plasma， tissues（heart， liver， spleen， lung， kidney， stomach and small intestine）， urine and fecal samples were collected and prepared after intragastric administration， and the prototype component and metabolites of limonin were identified. ResultThe prototype component of limonin were detected in the feces， stomach， small intestine of female and male rats， and in the heart， liver， spleen， lung and kidney tissues of female rats. A total of 23 metabolites related to limonin were detected in rats， of which 2， 1， 5， 4， 23 metabolites were detected in liver， stomach， small intestine， urine and feces， respectively， and the main metabolic pathways were hydrolysis， reduction， hydroxylation and methylation， etc. The distribution of some metabolites differed between male and female rats. ConclusionThe prototype component of limonin are mainly distributed in the stomach and small intestine in rats， and the distribution of prototype component and some metabolites are different by gender. Limonin is mainly excreted through feces with phase Ⅰ metabolites as the main ones. The results of this study can provide a reference for further elucidation of the effect of gender differences on the metabolism of limonin in vivo and its mechanism of action.