小儿反复呼吸道感染与微量元素

小儿反复呼吸道感染与微量元素的关系已引起临床的广泛重视.观点较一致的是缺锌、缺铁、铜异常、铅过高对机体有显著影响.小儿呼吸道的生理解剖的特点以及免疫机制未完善,微量元素的异常影响了小儿免疫机制和机体各系统的正常功能,导致小儿反复呼吸道感染.     

Ramberg-B(a)cklund反应在功能有机分子合成中的应用

碳碳双键广泛地存在于功能有机分子中,其构筑在合成化学中具有极其重要的意义.Ramberg-B(a)cklund反应是构筑碳碳双键的重要方法之一,其关键步骤是砜在碱性条件下进行1,3-消除,得到环状砜,然后重排除去SO2形成双键.该方法具有良好的立体选择性,底物在不同的反应条件下得到不同构型的产物,因而可以应用于合成许多功能有机分子,具有很好的应用前景.结合自己的研究工作对Ramberg-B(a)cklund反应在功能有机分子合成中的应用进行了较为系统的总结,也对Ramberg-B(a)cklund反应的拓展进行了简要介绍.     

功能高分子活性材料硫酸根离子选择电极的研制

利用辐射方法制备硫酸根离子选择电极活性材料,至今未见报导,我们首次采用辐射接枝方法制备了以疏水性高分子为骨架的带有SO~-活性基团的功能高分子活性材料,研制了硫酸根离子选择电极。结果表明,该电极具有内阻低,响应快,稳定性较好的特点,且其功能曲线的线性范围为10~(-1)～10~(-4)MSO_4~-,适宜的pH范围为4～9。     

一步法直接合成有机季铵功能修饰的介孔分子筛SBA-15

以P123 嵌段共聚物为模板剂, 3-三甲基丙基氯化铵三甲氧基硅烷(TMAPS)为修饰剂, 酸性条件下一步法直接合成了有机季铵基团功能修饰的SBA-15, 并通过XRD、TEM、N2吸附-脱附、Raman 光谱等对功能化样品的结构和性质进行了表征, 对一步法合成TMAPS 修饰的SBA-15 的可能反应机理进行了探讨. 修饰后的SBA-15 仍然保持了二维六方特征介孔结构, 随着TMAPS负载量的增大, SBA-15 孔道有序度下降, 孔径、孔容和比表面积也随之下降. 有机季铵基团在SBA-15 孔道表面均匀分散, 可与HAuCl4通过快速离子交换制备Au 颗粒高度分散的Au-SBA-15.     

烟碱分子烙印聚合物的吸附特性

利用分子烙印技术，以烟碱为烙印分子，甲基丙烯酸(MAA)为功能单体，乙二醇二甲基丙烯酸酯(EDMA)为交联剂，合成了对烟碱具有特异性作用的分子烙印聚合物P(Nic)；通过平衡吸附实验，评价了其对烟碱的亲和力和选择性。与非烙印聚合物相比，P(Nic)对烟碱表现了很高的亲和力；Scatchard分析表明在P(Nic)中存在对烟碱有不同的亲和力的两类作用位点。通过与氨基吡啶类物质在P(Nic)上的吸附行为比较，表明P(Nic)对烟碱具有很好的选择性。本工作证明了用P(Nic)作为固相萃取(SPE)材料选择性地从烟草烟雾中提取烟碱的可能性。     

食物中的钼与人体健康

综述了食物中钼与人体健康之间的关系.主要包括常见食物中的钼含量,钼在人体中的代谢,钼的生物学功能以及钼对人体健康的影响等.     

聚γ-[N,N-双(β-乙硫乙基)胺基]丙基硅氧烷铑配合物的合成及其催化硅氢化性能

从二(β-氟乙基)烯丙胺出发,通过乙硫醚化、硅氢加成、气相法二氧化硅固载,再与三氯化铑作用,合成了标题配合物,它们是烯烃与三乙氧基硅烷的硅氢加成反应的有效催化剂,对其催化特性进行了研究。     

镍与生物

镍是一种稀有金属元素，也是动植物和人的必需营养微量元素。本文对镍的生物学功能及对有机体可能造成的损害进行了详细地阐述。     

职业性铅接触对行为功能的影响

对３５名铅作业工城套的行为功能测验，接触组与对照组比较，１６项行为功能测验中有１４项得分有统计学意义（Ｐ〈０．０１或Ｐ〈０．０５），半数项目行为功能测验得分有随着铅作业工人龄增长而呈该增或该减的趋势。作者认为铅对作业工人行为功能的影响是肯定的，用行为功能测验的方法来研究铅的神经毒性是可取的简便方法。     

双功能型嵌入镍纳米颗粒的碳棱柱状微米棒电极用于电化学甲醇氧化助力的节能产氢

With the rapid development of human society, clean energy forms are imperative to sustain the normal operations of various mechanical and electrical facilities under a cozy environment. Hydrogen is considered among the most promising clean energy sources for the future. Recently, electrochemical water splitting has been considered as one of the most efficient approaches to harvest hydrogen energy, which generates only non-pollutant water on combustion. However, the sluggish anodic oxygen evolution reaction significantly restricts the efficiency of water splitting and requires a relatively high cell voltage to drive the electrolysis. Therefore, seeking a thermodynamically favorable anodic reaction to replace the sluggish oxygen evolution reaction by utilizing highly active bifunctional electrocatalysts for the anodic reaction and hydrogen evolution are crucial for achieving energy-efficient hydrogen production for industrial applications. Nevertheless, it is known that the oxygen evolution reaction can be replaced with other useful and thermodynamically favorable reactions to reduce the electrolysis voltage for realizing energy-efficient hydrogen production. Therefore, in this study, we present a bifunctional nickel nanoparticle-embedded carbon (Ni@C) prism-like microrod electrocatalyst synthesized via a two-step method involving the synthesis of a precursor metal-organic framework-74 and subsequent carbonization treatment for methanol oxidation and hydrogen evolution. The interfacial structure consisting of a nickel and carbon skeleton was realized via in situ carbonization. However, the dispersed nickel nanoparticles do not easily aggregate owing to the partition by the surrounding carbon as it would sufficiently expose the active Ni sites to the electrolytes, ensuring fast charge transfer between the catalyst and electrolytes by accelerating the electrochemical kinetics. In the anodic methanol oxidation, the products were detected as carbon dioxide and formate with faradaic efficiencies of 36.2% and 62.5%, respectively, at an applied potential of 1.55 V. Meanwhile, the Ni@C microrod catalyst demonstrated high activity and durability (2.7% current decay after 12 h of continuous operation) toward methanol oxidation, which demonstrates that methanol oxidation precedes oxidation under voltage forces. Notably, the bifunctional catalyst not only exhibits excellent performance toward methanol oxidation but also yields a low overpotential of 155 mV to drive 10 mA∙cm⁻² toward hydrogen evolution in 1.0 mol∙L⁻¹ KOH aqueous solution with 0.5 mol∙L⁻¹ methanol at room temperature, which guarantees the hydrogen production efficiency. More importantly, the constructed two-electrode electrolyzer produced a current density of 10 mA∙cm⁻² at a low cell voltage of 1.6 V, which decreased by 240 mV after replacing the oxygen evolution reaction with methanol oxidation.