在产品的质量上,时代衣柜企业要严把产品质量关,真正为消费者考虑;在产品的创新上,衣柜企业需要不断创新,与时俱进,满足消费者的不同需求。
不同SNA合成通常始于水溶液中带有巯基末端的DNA与金纳米颗粒(AuNP)之间的相互作用。这一工作使SNA合成变得轻而易举,得抖并使未来能够探索具有超高DNA密度SNA的物理、化学和生物学效应。
常规的SNA合成过程非常耗时,天下且需要格外小心以避免NP聚集。文献链接:时代FlashSynthesisofSphericalNucleicAcidswithRecordDNADensity,J.Am.Chem.Soc., 2021,DOI:10.1021/jacs.1c00568本文由材料人学术组tt供稿,材料牛整理编辑。不同这一进展对促进DNA纳米技术的快速发展和SNA的广泛应用十分及时。
得抖该成果以FlashSynthesisofSphericalNucleicAcidswithRecordDNADensity为题发表在J.Am.Chem.Soc.上20天的小狗也可以经过适当的训练来学会走路,天下但是需要耐心和持续的训练,以及经常观察它们的行为和反应。
20天的小狗会走路吗20天的小狗能够走路,时代但是它们需要一定的时间来适应走路。
它们可以学习如何以安全的方式在家里、不同公园和其他地方行走,以及如何应对不同的地形和状况。得抖(F) 再组装3D晶体的AFM图像。
天下(G) 左手双螺旋超结构的示意图。并且改变外部条件,时代调控组装过程的作用力,实现了蛋白质晶体结构应对环境刺激的动态响应。
此外,不同通过在RhuA模块表面上设计另一种组氨酸的排布,进一步构建了RhuA蛋白质双螺旋3D超结构。文献链接:得抖NoncovalentSelf-AssemblyofProteinCrystalswithTunableStructures(NanoLett., 2021,得抖DOI:10.1021/acs.nanolett.0c04587)【团队在该领域工作汇总】MingmingDu,KunZhou,RunzeYu,YufengZhai,GangChen,QiangbinWang*.NoncovalentSelf-AssemblyofProteinCrystalswithTunableStructures. NanoLett.,2021,DOI:10.1021/acs.nanolett.0c04587.KunZhou+,YihaoZhou+,HongchaoYang,HuileJin,YonggangKe*,QiangbinWang*.InterfaciallyBridgingCovalentNetworkYieldsHyperstableandUltralongVirus-basedFibersforEngineeringFunctionalMaterials.Chem.Int.Ed.,2020,59,18249-18255.JinyiDong+,MengWang+,YihaoZhou,ChaoZhou*, QiangbinWang*.DNA-BasedAdaptivePlasmonicLogicGates. Chem.Int.Ed., 2020,59,15038-15042.KunZhou,YihaoZhou,VictorPan,QiangbinWang*,YonggangKe*.ProgrammingDynamicAssemblyofViralProteinswithDNAOrigami. Am.Chem.Soc.,2020,142,5929-5932.MingmingDu,KunZhou*,XiaoWang,JiantingZhang,YejunZhang,JinchenDong,LonglongWu,ZhiQiao,GangChen*,QiangbinWang*.PreciseFabricationofDeNovoNanoparticleLatticesonDynamic2DProteinCrystallineLattices.NanoLett.,2020,20,1154-1160.JiantingZhang,KunZhou,YejunZhang,MingmingDu,QiangbinWang*.PreciseSelf-AssemblyofNanoparticlesintoOrderedNanoarchitecturesDirectedbyTobaccoMosaicVirusCoatProtein. Mater., 2019,31, 1901485.KunZhou,YonggangKe,QiangbinWang*.SelectiveinSituAssemblyofViralProteinontoDNAOrigami.Am.Chem.Soc., 2018,140,8074-8077.ChenqiShen,XiangLan,ChengganZhu,WeiZhang,LeyuWang*, QiangbinWang*.SpiralPatterningofAuNanoparticlesonAuNanorodSurfacetoFormChiralAuNR@AuNPHelicalSuperstructuresTemplatedbyDNAOrigami. Adv.Mater., 2017, 29,1606533.ChenqiShen,XiangLan,XuxingLu,TravisA.Meyer,WeihaiNi,YonggangKe*, QiangbinWang*.Site-SpecificSurfaceFunctionalizationofGoldNanorodsUsingDNAOrigamiClamps.Am.Chem.Soc.,2016,138,1764-1767.XiangLan,XuxingLu,ChenqiShen,YonggangKe,WeihaiNi, QiangbinWang*.AuNanorodHelicalSuperstructureswithDesignedChirality. J.Am.Chem.Soc., 2015,137,457-462.【相关优质文献推荐】MingmingDu,KunZhou*,XiaoWang,JiantingZhang,YejunZhang,JinchenDong,LonglongWu,ZhiQiao,GangChen*,QiangbinWang*.PreciseFabricationofDeNovoNanoparticleLatticesonDynamic2DProteinCrystallineLattices.NanoLett.,2020,20,1154-1160.JiantingZhang,KunZhou,YejunZhang,MingmingDu,QiangbinWang*.PreciseSelf-AssemblyofNanoparticlesintoOrderedNanoarchitecturesDirectedbyTobaccoMosaicVirusCoatProtein. Mater., 2019,31, 1901485.KunZhou,YonggangKe,QiangbinWang*.SelectiveinSituAssemblyofViralProteinontoDNAOrigami.Am.Chem.Soc., 2018,140,8074-8077.ChenqiShen,XiangLan,ChengganZhu,WeiZhang,LeyuWang*, QiangbinWang*.SpiralPatterningofAuNanoparticlesonAuNanorodSurfacetoFormChiralAuNR@AuNPHelicalSuperstructuresTemplatedbyDNAOrigami. Adv.Mater., 2017, 29,1606533.ChenqiShen,XiangLan,XuxingLu,TravisA.Meyer,WeihaiNi,YonggangKe*, QiangbinWang*.Site-SpecificSurfaceFunctionalizationofGoldNanorodsUsingDNAOrigamiClamps.Am.Chem.Soc.,2016,138,1764-1767.XiangLan,XuxingLu,ChenqiShen,YonggangKe,WeihaiNi, QiangbinWang*.AuNanorodHelicalSuperstructureswithDesignedChirality. J.Am.Chem.Soc., 2015,137,457-462.本文由木文韬翻译,材料牛整理编辑。