In-tip nanoreactors for cancer cells proteome profiling

Mass spectrometry (MS)-based proteome profiling is essential for molecular diagnostics in modern biomedical study. To date, sample preparation including protein extraction and proteolysis is still very challenging and lack of efficiency. Recently tips-based sample preparation protocols exhibit strong potentials to achieve the goal of “a proteome in an hour”. However, in-tip proteolysis is still rarely reported and far from ideal for dealing with complex bio-samples. In this work, nanoreactors encapsulated micropipette tips were demonstrated as high performance devices for fast (∼minutes) and multiplexing proteolysis to assist the profiling of cancer cells proteome. Nanoporous silica materials with controlled pore size and surface chemistry were prepared as nanoreactors and encapsulated in micropipette tips for efficient in situ proteolysis. The as-constructed device showed desirable sensitivity (LOD of 0.204 ± 0.008 ng/μL and LOQ of 0.937 ± 0.055 ng/μL), selectivity, stability (two months under −20 °C), reusability (at least 10 times), and little memory effect in MS based bottom-up proteomic analysis. It was used for comprehensive protein mapping from cancer cell lines. The number of identified proteins was increased by 18%, 22%, 52%, and 52% dealing with HepG2, F56, MCF7, and HCCLM3 cancer cells, compared to traditional in-solution proteolysis based bottom-up proteomic strategy. With the enhanced performance, our work built a novel, efficient and miniaturized platform for facile proteomic sample preparation, which is promising for advanced biomarkers discovery in biomedical study.     

Time‐Resolved Energetics of Photoprocesses in Prokaryotic Phytochrome‐Related Photoreceptors

Time‐resolved photoacoustics (PA) is uniquely able to explore the energy landscape of photoactive proteins and concomitantly detects light‐induced volumetric changes (ΔV) accompanying the formation and decay of transient species in a time window between ca. 20 ns and 5 μs. Here, we report PA measurements on diverse photochromic bilin‐binding photoreceptors of prokaryotic origin: (1) the chromophore‐binding GAF3 domain of the red (R)/green (G) switching cyanobacteriochrome 1393 (Slr1393g3) from Synechocystis; (2) the red/far red (R/FR) Synechocystis Cph1 phytochrome; (3) full‐length and truncated constructs of Xanthomonas campestris bacteriophytochrome (XccBphP), absorbing up to the NIR spectral region. In almost all cases, photoisomerization results in a large fraction of energy dissipated as heat (up to 90%) on the sub‐ns scale, reflecting the low photoisomerization quantum yield (<0.2). This “prompt” step is accompanied by a positive ΔV₁ = 5–12.5 mL mol^?1. Formation of the first intermediate is the sole process accessible to PA, with the notable exception of Slr1393g3‐G for which ΔV₁ = +4.5 mL mol^?1 is followed by a time‐resolved, energy‐conserving contraction ΔV₂ = ?11.4 mL mol^?1, τ₂ = 180 ns at 2.4°C. This peculiarity is possibly due to a larger solvent occupancy of the chromophore cavity for Slr1393g3‐G.     

O2-2,4-二硝基苯基偶氮二醇盐类化合物的设计、合成及抗肿瘤活性

以O2-2,4-二硝基苯基偶氮二醇盐(PABA/NO)为先导化合物,选择适当的仲胺作为偶氮二醇盐中相应的胺片段,并用碳氮键取代苯环5位的碳氧酯键,设计合成了化合物2a,2b和4a~4j,以期获得活性更强且稳定性好的抗肿瘤药物.目标化合物经1H NMR,13C NMR及HRMS进行了结构确证.生物活性测试结果表明,目标化合物可不同程度地抑制结肠癌HCT-116细胞的增殖,其中化合物4h的活性最强(IC50=7.945±0.421 μmol/L),优于PABA/NO(IC50=12.134±0.675 μmol/L).NO释放实验结果表明,此类化合物的NO释放量与细胞毒性呈正相关.化合物4h在HCT-116细胞中释放NO的量最多,约是正常细胞的2倍.此外,化合物4h在大鼠血浆中的体外稳定性显著优于PABA/NO,值得进一步研究.     

基于β-环糊精接枝聚L-谷氨酸星型聚合物的可注射水凝胶的制备与表征

采用Gadelle-Defaye法制备了全-6-氨基-β-环糊精[β-CD-(NH2)7],并用"Grafting-from"接枝法得到不同分子量的星型结构β-环糊精-g-聚L-谷氨酸(β-CD-g-PLGA).对β-CD-g-PLGA进行酰肼化改性后与醛基化海藻酸钠(ALG-CHO)通过席夫碱交联反应制备β-CD-g-PLGA/ALG水凝胶.研究了前驱体浓度以及β-CD-gPLGA分子量对β-CD-g-PLGA/ALG水凝胶性能的影响,并以疏水性辛伐他汀(SIM)为模型药物,研究了水凝胶对SIM的控制释放行为.     

Fe_3O_4/RGO复合材料的制备及其电化学性能研究

以改进Hummers法合成的氧化石墨烯(GO)为前驱体,通过水热法结合烧结工艺制备了四氧化三铁/还原氧化石墨烯(Fe_3O_4/RGO)复合材料。利用X射线衍射(XRD)、拉曼光谱(Raman)、扫描电镜(SEM)、透射电镜(TEM)等手段对复合材料的理化性能进行表征;通过充放电测试、循环伏安(CV)和电化学阻抗谱(EIS)等技术,综合考察了材料的储锂性能及电化学性能增强机制。结果表明,在200和600 m A/g电流密度下,Fe_3O_4/RGO复合负极循环60次后的放电比容量分别保持在709和479 mAh/g,表现出良好的倍率性能;相较于纯Fe_3O_4负极,复合负极呈现出更优异的锂电性能,其电化学性能的改善得益于RGO能增强材料的电导性和结构稳定性。     

基于水滑石前驱体制备ZnCr_2O_4-ZnO复合光催化剂及产氢性能

以研磨水热法合成ZnCr_2O_4-ZnO异质结型光催化剂,对所得样品进行了TG-DTA、XRD、SEM、HRTEM、DRS和N2吸附-脱附表征分析;在模拟太阳光下,以草酸为牺牲剂对样品的光催化产氢活性进行评价,并分别与共沉淀法、尿素回流法和尿素水热法制备的ZnCr_2O_4-ZnO样品进行比较,探讨了异质结型ZnCr_2O_4-ZnO复合光催化剂的产氢机理。结果表明,四种方法制备的Zn-Cr前驱体都具有一定的水滑石结构,经500℃焙烧后,均为球形纳米粒子,但团聚情况各异,比表面积和孔结构参数有较大差别。其中,研磨水热法所得样品ZnCr_2O_4-ZnO粒子均匀,光电流响应强度最大,产氢效率最高,为0.956 mmol/(h·gcat),分别是共沉淀法、尿素回流法和尿素水热法制备样品产氢量的2.3、1.5和3.0倍。     

基于室温磷光量子点/硼酸基联吡啶盐纳米复合材料检测果糖

以Mn掺杂的ZnS(Mn-ZnS)室温磷光(RTP)量子点的磷光为信号,以2-溴甲基苯硼酸与4,4ˊ-联吡啶为原料合成的硼酸基联吡啶盐(BBV)为受体,带负电的量子点与带正电BBV通过静电作用形成Mn-ZnS/BBV纳米复合材料,Mn-ZnS量子点磷光猝灭,加入果糖,BBV与果糖形成阴离子硼酸酯,降低了对量子点猝灭效率,RTP恢复.考察了时间、pH值对Mn掺杂的ZnS QDs/BBV纳米复合材料磷光强度的影响,在最优条件下,此传感器检测果糖的线性范围为0.05~1.00 mmol/L,检出限为0.01 mmol/L,相关系数r为0.99.本磷光分析法简便快速、灵敏度高,有望应用于食品、医药行业中果糖含量的检测分析.     

基于新型量子点荧光微球的氯霉素免疫层析试纸条的制备和应用

以羧基化CdTe/ZnSe量子点荧光微球为标记物,通过1-乙基-(3-二甲基氨基丙基)碳二亚胺/N-羟基琥珀酰亚胺(EDC/NHS)活化法将氯霉素(CAP)单克隆抗体与量子点荧光微球偶联制备荧光探针.氯霉素全抗原(CAP-HS-BSA)及羊抗鼠二抗分别喷涂硝酸纤维素膜,形成检测线(T线)和质控线(C线),组装成新型氯霉素量子点荧光微球免疫层析试纸条,建立了快速、定量检测牛奶中CAP的方法.本研究开发的量子点荧光微球试纸条可在15 min内完成牛奶样品中CAP的定量检测,线性范围为0.1~100.0μg/L,检出限为0.1μg/L.牛奶样品CAP的加标回收率为93.3%~97.9%,相对标准偏差在4.9%~6.9%之间.     

基于Mn掺杂ZnS量子点的室温磷光传感应用的研究进展

与一般有机染料分子相比,半导体材料量子点具有优异的光学性能,在多个领域得到了广泛的应用.量子点具有窄而对称且可调的发射波长、宽激发强吸收、抗光漂白能力强以及水溶性好等诸多优势,引起了研究者广泛关注.为了增加量子点的斯托克斯位移从而很好地避免量子点的自猝灭现象,引入掺杂物是一种很有效的方式.掺杂量子点不仅保留了量子点原有的优点,而且还赋予量子点额外的优异性能.如Mn掺杂ZnS量子点生物相容性好,不含Cd和Hg等有害元素,而且Mn2+的加入使其具有优异的室温磷光特性.磷光检测能很好地避开生物背景荧光的干扰,使得Mn掺杂ZnS量子点能够广泛应用于磷光生物分析.本文综述了Mn掺杂ZnS量子点在室温磷光分析中的研究进展,着重介绍了几种具有启发意义的设计策略,包括其发光机理以及应用于离子、分子以及生物大分子等的检测.     

氟固相萃取辅助的生物分子质谱分析新方法

氟固相萃取(Fluorous solid-phase extraction,FSPE)是一种基于全氟化合物之间氟-氟相互作用的固相萃取技术,通过在目标分子上进行氟标签衍生,利用高氟化固相吸附剂实现特异性的分离纯化.这一技术在有机合成、催化,以及化学和生物分离分析等诸多领域应用广泛.近年来,由于氟固相萃取和生物质谱技术之间良好的兼容性,两者联用结合的分析方法受到了研究者的广泛关注.本文在简要介绍氟固相萃取技术原理的基础之上,重点综述了其在生物质谱分析领域中的应用,并对其发展前景进行了展望.