简介:采用离体抑菌试验研究观察H2O2-Ag+复方消毒剂对柑橘青霉病菌(Penicilliumitalicum)和绿霉病菌(Penicilliumdigitatum)生长的直接抑制效果,并以年橘为试材,分别活体接种P.italicum和P.digitatum,研究H_2O_2-Ag~+复方消毒剂处理对青霉病和绿霉病的抑制作用,同时分析果实在贮藏过程中的品质变化。离体抑菌试验表明:培养基中添加H_2O_2-Ag~+显著抑制了P.italicum和P.digitatum的菌丝生长(P〈0.05),并表现出明显的浓度效应,浓度为1%H_2O_2-20mg/LAg~+的复方消毒剂对两种病菌的抑制率达100%;活体接种试验表明:3%H_2O_2-60mg/LAg~+浓度的复方消毒剂可显著抑制病原菌诱导的病斑扩展,降低果实发病率,而对果实的品质及果面色差值没有明显影响。本研究表明,H_2O_2-Ag~+复方消毒剂不仅对柑橘青、绿霉菌有直接的杀灭作用,还能有效控制果实的腐烂率,可作为一种新型、安全、环保的保鲜防腐剂,应用于柑橘果实采后病害的控制。
简介:以海参为原料,研究海参蛋白肽的抗氧化性以及对H2O2诱导RAW264.7巨噬细胞氧化损伤的保护效果和作用机制。以清除羟自由基(·OH)能力、Fe2+螯合能力和Fe3+还原能力为指标,评价海参蛋白肽的体外抗氧化活性。以H2O2刺激RAW264.7巨噬细胞建立氧化损伤细胞模型,采用2′,7′-二氯荧光黄双乙酸盐(DCFH-DA)荧光探针法测定细胞活性氧(ROS)水平,四甲基偶氮唑盐(MTT)法测定细胞活力,实时荧光定量PCR测定细胞血红素氧合酶-1(HO-1)mRNA表达水平。结果表明,海参蛋白肽能够清除·OH,具有Fe2+螯合能力和Fe3+还原能力,海参蛋白肽的这种体外抗氧化能力呈现浓度依赖效应。海参蛋白肽显著降低氧化损伤RAW264.7巨噬细胞ROS水平和提高氧化损伤细胞活力(P〈0.05)。而且,海参蛋白肽显著提高巨噬细胞内HO-1mRNA表达(P〈0.05),HO-1抑制剂锌原卟啉IX(ZnPPIX)部分逆转海参蛋白肽对氧化损伤巨噬细胞活力的促进作用。这些结果说明,海参蛋白肽通过上调RAW264.7巨噬细胞HO-1mRNA表达水平,发挥对巨噬细胞氧化损伤的保护作用。
简介:ThefruitsofPaulowniacatalpifoliaGongTongareusedasaChinesefolkherbalmedicineforthetreatmentofenteritis,tonsillitis,bronchitis,anddysentery,etc.OurpreviousstudyhasidentifiednewC-geranylatedflavanoneswithobviousanti-proliferativeeffectsinlungcancerA549cells.Inthepresentstudy,anewC-geranylatedflavone,paucatalinoneC(1)andfiveknownC-geranylatedflavanones(2-6)wereisolated.Inaddition,atotalof34C-geranylatedflavonoidsweredetectedbyHPLC-DAD-ESI-MS/MScouplingtechniquesfromtheCH_2Cl_2extractofP.catalpifolia.Futhermore,anti-agingeffectsofisolatedcompoundswereevaluatedinvitrowithprematuresenescent2BScellsinducedbyH_2O_2.PhytochemicalresultsindicatedthatP.catalpifoliawasanaturalresourceofabundantC-geranylatedflavonoids.Diplacone(3)andpaucatalinoneA(5)werethepotentanti-agingagentsintheprematuresenescent2BScellsinducedbyH_2O_2andtheC-geranylsubstituentmaybeanimportantfactorbecauseofitslipophiliccharacter.
简介:同步讲解SectionA1.Whattimedoyougotoschool?你什么时候上学?(1)whattime意为'什么时候,几点',常用来对具体的时间提问,可以用when替换。如:—WhattimedoesJimgotobed?吉姆什么时候睡觉?—Hegoestobedatteno’clock.他十点钟睡觉。
简介:Hydrogen,thecleanestandmostpromisingenergyvector,canbeproducedbysolarintochemicalenergyconversion,eitherbythephotocatalyticdirectsplittingofwaterintoH2andO2,or,moreefficiently,inthepresenceofsacrificialreagents,e.g.,intheso-calledphotoreformingoforganics.Efficientphotocatalyticmaterialsshouldnotonlybeabletoexploitsolarradiationtoproduceelectron–holepairs,butalsoensureenoughchargeseparationtoallowelectrontransferreactions,leadingtosolarenergydriventhermodynamicallyup-hillprocesses.RecentachievementsofourresearchgroupinthedevelopmentandtestingofinnovativeTiO2-basedphotocatalyticmaterialsarepresentedhere,togetherwithanoverviewonthemechanisticaspectsofwaterphotosplittingandphotoreformingoforganics.Photocatalyticmaterialswereeither(i)obtainedbysurfacemodificationofcommercialphotocatalysts,orproduced(ii)inpowderformbydifferenttechniques,includingtraditionalsolgelsynthesis,aimingatengineeringtheirelectronicstructure,andflamespraypyrolysisstartingfromorganicsolutionsoftheprecursors,or(iii)inintegratedform,toproducephotoelectrodeswithindevices,byradiofrequencymagnetronsputteringorbyelectrochemicalgrowthofnanotubearchitectures,orphotocatalyticmembranes,bysupersonicclusterbeamdeposition.