奎宁的全合成

介绍治疗疟疾的特效药奎宁150年的全合成史和长达90年的与奎宁合成相关疑案的最终解答。     

基于埃洛石的载药凝胶小球的制备及性能研究

采用离子凝胶法制备了一种新的壳聚糖-g-聚丙烯酸/埃洛石/海藻酸钠(CTS-g-PAA/HT/SA)凝胶小球。研究了HT含量对载药凝胶小球的溶胀性、包封效率和释放性能等的影响;同时也讨论了凝胶小球的pH敏感性和双氯芬酸钠(DS)的释放行为。结果表明:HT含量对载药凝胶小球的溶胀率、包封效率和累积释放率有明显的影响,在HT含量为30%时,溶胀率、包封效率和12h累积释放率分别达到32.84%、91.07%和100%;另外,载药凝胶小球具有较好的pH敏感性;在pH=2.1的释放介质中DS几乎不释放,而在pH=6.8的释放介质中缓慢释放;DS释药机理为溶胀控释。     

无筛板型固相萃取柱的制备及其在食品中苯甲酸的测定研究

结合固相萃取(SPE)盘与含支撑物的SPE柱技术,制备了一种新型的无筛板型固相萃取柱.以C18填料为例,以话梅样品为介质对其中的苯甲酸进行分析,并用传统固相萃取小柱平行比较;将SPE与HPLC-UV结合,考察了填料对简单介质中苯甲酸的最大吸附量及洗脱曲线,研究了新型SPE柱在实际应用中的分离纯化效果.结果表明,新型SPE柱对样品的吸附效果更好,规格为200 mg/3 mL的SPE柱对苯甲酸的吸附量达到0.951 mg,超过了传统柱的吸附量0.908 mg;其洗脱曲线与传统柱几乎重合;苯甲酸在1～100 mg/L浓度范围内线性关系良好, r=0.9999,用此SPE柱纯化后的样品加标回收率和相对误差分别在88.4%～102.3%和1.4%～2.9%之间.     

化学/电化学腐蚀法快速制备超疏水金属铝

提出一种金属铝超疏水表面的快速制作方法. 先以化学腐蚀在铝表面形成微米级粗糙结构, 再通过电化学腐蚀构筑纳米结构, 在20 min内完成了超疏水表面所需粗糙结构的制备. 这种化学腐蚀/电化学腐蚀两步法比单独化学或电化学腐蚀方法在时间上缩短了1~2个数量级, 且不受铝材晶形限制, 同时电化学腐蚀所用电流密度也降低了1个数量级, 降低了对电源设备的要求, 可望大规模应用于工业生产和其它金属的超疏水表面制备.     

甲硫醇和氢原子反应的从头算直接动力学

利用双水平直接动力学方法对反应CH3SH+H的微观机理和动力学性质进行了理论研究.对于此反应的三个反应通道,即—SH和—CH3基团上的两个氢提取通道及一个取代通道,在MP2/6-311+G(d,p)水平上优化得到了各稳定点的结构及振动频率,并在G3(MP2)水平上进行了单点能量计算以获得更精确的能量信息;在此基础上运用结合小曲率隧道效应校正的变分过渡态理论(CVT/SCT)计算了各反应通道在220-1000 K温度区间的速率常数.计算结果表明提取—SH基团上H的反应通道R1在整个反应温度区间都是主要通道,而随着温度的升高,低温下的次要反应通道——取代通道R3变得越来越重要,并且在高温下将成为一个竞争的反应通道;提取—CH3基团上H的反应通道(R2)由于具有较高的反应能垒,因而,其对总反应速率常数的贡献可以忽略.计算得到的总反应速率常数与已有的实验值符合得很好,进而我们预测了该反应在220-1000 K温度范围内速率常数的表达式为:k=5.00×10-18T2.39exp(-119.81/T),为将来的实验研究提供参考.     

纳米钯催化剂对甲醇的电催化氧化

采用水热法,以甲醛作还原剂还原Pd2+-EDTA络合物,制得钛基纳米钯颗粒电极(nanoPd/Ti).扫描电子显微镜(SEM)显示,纳米钯颗粒直径约为60 nm,形成三维立体网状结构.在碱性溶液中,循环伏安及交流阻抗测试分别表明:nanoPd/Ti电极对甲醇氧化有极高的阳极电流、较低的起始氧化电位和较强的抗CO毒化能力.在nanoPd/Ti电极上甲醇电氧化反应的阻抗值较低,增加甲醇浓度,电极阻抗更低.电极对甲醇氧化具有极好的电催化活性.     

钛纳米管负载锰催化剂的低温选择性催化还原脱硝性能

采用水热法合成了钛纳米管（TiNT）,以400℃焙烧后得到的TiO₂纳米管为载体,采用浸渍法制备了MnO_x/TiNT催化剂,用于低温NH₃选择性催化还原脱NO反应（SCR）。BET、TEM、XRD及TG测试表明,经过400℃焙烧之后的钛纳米管主要成分为锐钛矿型TiO₂,所制备的催化剂活性组分分散性较好。在模拟烟气条件下,考察了锰负载量、空速、O₂含量、氨氮比及进口NO浓度对MnO_x/TiNT的SCR催化性能的影响。在150℃、\[NH₃\]/\[NO\]比为1.2、O₂浓度为3%、NO浓度为0.06%、空速GHSV为23613.8h^-1、Mn的负载量为5%~15%的条件下,NO的转化率达到95%以上。反应气氛中单独通入水会造成催化剂的活性下降;切断H₂O,催化剂的活性可以恢复至初始水平。温度越高,催化剂抗水性能越好,而且水存在情况下的抗硫性能优于其单独抗硫性能。再次切断H₂O和SO₂,催化剂的活性逐渐上升,但不能恢复到初始水平。     

潜指纹显现方法研究进展

综合介绍了常用的几种潜指纹显现方法及原理,其中主要综述了指纹的物理化学显现法和化学显现法的进展,包括多金属沉淀法、茚三酮法和荧光材料显现法等。     

The use of ethylene glycol solution as the running buffer for highly efficient microchip-based electrophoresis in unmodified cyclic olefin copolymer microchips

An ethylene glycol solution was used as the electrophoretic running buffer in unmodified cyclic olefin copolymer (COC) microchips to minimize the interactions between the analytes and the hydrophobic walls of the plastic microchannels, enhance the resolution of the analytes and eliminate the uncontrollable dispersion caused by uneven liquid levels and non-uniform surfaces of the separation channels. Five amino acids that were labeled with fluorescein isothiocyanate (FITC) were used as model analytes to examine the separation efficiency. The effects of ethylene glycol concentration, pH and sodium tetraborate concentration were systematically investigated. The five FITC-labeled amino acids were effectively resolved using a COC microchip with an effective length of 2.5 cm under optimum conditions, which included using a running buffer of 20 mmol/L sodium tetraborate in ethylene glycol:water (80:20, v/v), pH 6.7. A theoretical plate number of 4.8 × 10(5)/m was obtained for aspartic acid. The system exhibited good repeatability, and the relative standard deviations (n=5) of the peak areas and migration times were no more than 3.4% and 0.7%, respectively. Furthermore, the system was successfully applied to elucidate these five amino acids in human saliva.     

Surface modification of PDMS by surface-initiated atom transfer radical polymerization of water-soluble dendronized PEG methacrylate

The current paper reports the synthesis of a highly hydrophilic, antifouling dendronized poly(3,4,5-tris(2-(2-(2-hydroxylethoxy)ethoxy)ethoxy)benzyl methacrylate) (PolyPEG) brush using surface initiated atom transfer radical polymerization (SI-ATRP) on PDMS substrates. The PDMS substrates were first oxidized in H₂SO₄/H₂O₂ solution to transform the Si-CH₃ groups on their surfaces into Si-OH groups. Subsequently, a surface initiator for ATRP was immobilized onto the PDMS surface, and PolyPEG was finally grafted onto the PDMS surface via copper-mediated ATRP. Various characterization techniques, including contact angle measurements, attenuated total reflection infrared spectroscopy, and X-ray photoelectron spectroscopy, were used to ascertain the successful grafting of the PolyPEG brush onto the PDMS surface. Furthermore, the wettability and stability of the PDMS-PolyPEG surface were examined by contact angle measurements. Anti-adhesion properties were investigated via protein adsorption, as well as bacterial and cell adhesion studies. The results suggest that the PDMS-PolyPEG surface exhibited durable wettability and stability, as well as significantly anti-adhesion properties, compared with native PDMS surfaces. Additionally, our results present possible uses for the PDMS-PolyPEG surface as adhesion barriers and anti-fouling or functional surfaces in biomedical applications.