喹唑啉稠合螺杂环化合物的合成及晶体结构

许多螺杂环化合物及喹唑啉化合物具有抗癌、消炎、抗真菌、抗细菌、抗结核、抗肿瘤以及除草等生物活性,将噻唑酮和喹唑啉稠合环结构与螺杂环结构合为一体,合成新的喹唑啉稠合螺杂环化合物,以期得到具有更高生物活性的化合物,是当前化学家研究的课题之一,1,3-偶极环加成反应是合成五元杂环的常用方法,采用环外双键结构的化合物为亲偶极体,     

用FTIR研究环氧化天然橡胶的热老化

从合成结构新颖的杂环化合物角度出发，寻找具有较好生物活性的新物质，是研究新农药的一个重要方向［１］．最近研究表明很有可能从异噻唑杂环中找到生物活性独特的新型化合物［２］．据报道，腙类化合物具有很好的生物活性［３］．我们设计合成了含异噻唑杂环的腙类新型...     

2-氨基取代噻唑基膦酸酯的合成

许多噻唑类化合物具有生物活性,有些已作为杀菌剂、除草剂在农业上得到应用。近年来还进行了α-氨基酸的类似物α-氨基膦酸的合成及其生物活性的研究。迄今为止,还未见有4-噻唑基膦酸酯类化合物的合成和生物活性方面的文献报道。本文报道一系列2-氨基-5-取代-4-噻唑基膦酸酯(1)和2-氨基-4-取代-5-噻唑基膦酸酯(2)的合成。这类化合物显示了一定的杀菌活性。 1由取代乙酰氯与亚磷酸三酯经Arbuzov反应得到的取代乙酰基膦酸三酯(3)与缩二硫脲的溴氢酸盐(4)、一定量的弱碱(如硫脲、乙酸钾)在乙醇中反应制得。溶剂和碱的强弱     

噻唑环衍生物的合成

噻唑环及其衍生物广泛存在于具有生物活性的分子中[1]可用于抗生素和消炎药的制备[2]。本文合成的几种噻唑基衍生物—类以HIV蛋白酶为靶点的新型抗艾滋病药物利托那韦的重要中间体[3-5],对其合成工艺的研究具有较实际的意义。噻唑环衍生物可通过α-卤代羰基化合物与硫代酰胺缩合而成[6],α-巯基酮与腈缩合反应得到,也可采用醛与半胱氨酸缩合,再与二氧化锰作用得噻唑类化合物[7]。本文采用α-氯代羰基类化合物与硫代酰胺缩合而得三种噻唑类化合物,产率较为理想。1合成路线设计合成路线设计可表示如下图1图1目标化合物的合成路线F ig.1 The …     

新型含2-取代-1,3-噻唑烷的查尔酮类化合物的合成及其生物活性

为了寻找生物活性良好的查尔酮类化合物,利用2-(2-氰基亚胺基-1,3-噻唑烷-3-基)-1-苯基乙酮或3-((2-氰基亚胺基-1,3-噻唑烷-3-基)-1-苯基-1-丙酮与取代苯甲醛发生缩合,合成了14个新型含2-取代-1,3-噻唑烷的查尔酮类化合物.其结构均经1H NMR和元素分析表征.初步的生物活性测试结果表明,在试验浓度下,部分目标化合物表现出一定的杀菌活性.     

合成2,5-二芳基噻唑衍生物的新方法

噻唑环作为一类重要的五元芳香杂环,其衍生物具有多种生物活性,被广泛应用在医药方面.以价廉易得的不同取代苯甲酸为原料,经酰化反应、硫代反应、环合反应和Heck反应合成了2,5-二芳基噻唑衍生物.重点在于优化Heck反应的条件,进行可能反应机理的探讨.该方法具有反应条件温和、操作简单及底物的普适性良好等优点,为2,5-二芳基取代噻唑类化合物的合成提供了新的方向.     

新型含2-取代-1,3-噻唑烷和噻唑环的亚胺类化合物的合成及生物活性

通过4-[(2-氰基亚胺基-1,3-噻唑烷-3-基)甲基]-2-氨基噻唑与取代苯甲醛的缩合反应, 合成了14个新型含2-取代- 1,3-噻唑烷和噻唑环的亚胺类化合物5. 所有化合物的结构均经1H NMR和元素分析确证, 并通过X射线单晶衍射分析测定了化合物5a的晶体结构. 初步生物活性试验结果表明, 部分目标化合物具有一定的杀菌活性和植物生长调节活性.     

含4-噻唑啉酮环的新烟碱类化合物的合成及生物活性

根据生物等排原理和新烟碱类化合物与乙酰胆碱酯酶的作用机理, 以4-噻唑啉酮(4)为中间体设计合成了2-取代-3-(2-氯-5-吡啶亚甲基)-4-氰基亚胺基-1,3-噻唑烷(8a~8c)和5-芳基次甲基-2-芳基-3-(2-氯-5-吡啶亚甲基)-4-噻唑啉酮(5a~5e)两类化合物. 中间体(4)由醛、胺和巯基乙酸缩合得到. 所有化合物的结构均经元素分析和1H NMR确证. 初步生物活性试验结果表明, 部分化合物具有一定的杀菌活性和促进黄瓜子叶生根活性, 化合物8b显示出很好的抗HIV-1蛋白酶活性.     

HIV-1逆转录酶抑制剂的三维定量构效关系

采用比较分子力场分析法(CoMFA)和比较分子相似性指数分析法(CoMSIA)对一系列非核苷类HIV-1逆转录酶抑制剂(苯磺酰基亚胺噻唑类化合物)进行了三维定量构效关系的研究,获得了高可靠性的CoMFA和CoMSIA模型,其交叉验证相关系数q2值分别为0.748和0.607.通过对CoMFA和CoMSIA模型三维等势图的分析,确定了该类化合物抗HIV-1活性的结构要求.研究结果表明,对苯磺酰基亚胺噻唑类化合物而言,在苯环的C-5位引入体积大和电负性强的基团能增加其抑制活性;苯环的C-2位的氢键给体基团对活性有利;噻唑环的R2取代基疏水性增大会降低生物活性.研究结果表明,可以指导新HIV-1逆转录酶抑制剂的设计和合成.     

含有异噁唑的S-三唑[3,4-b]-1,3,4-噻二嗪、咪唑[2,1-b]-1,3,4-噻二唑和咪唑[2,1-b]-1,3,4-噁二唑衍生物的合成

异噁唑衍生物作为一类重要的生物活性物质,其合成一直受到人们的关注,其中德国HMR公司开发研制的新型抗内风湿性关节炎药来氟米特(Leftunomide)已于1998年在美国率先上市,该药还具有很好的免疫调节作用．7H-均三唑[3,4-b]-1,3,4-噻二嗪、咪唑并[2,1-b]噻唑和咪唑并[2,1-b]-1,3,4-噻二唑衍生物均表现出广谱的生物活性．     

纳米碳点的制备与应用研究进展

纳米碳点是碳纳米材料家族的新成员,近年来在国内外受到广泛关注。与传统的荧光染料和半导体量子点发光材料相比,碳点不仅具有优异的光学性能及尺寸效应,且具有制备成本低廉、生物相容性好、易于官能化、能带结构可调等优势。本文在理清有关碳点概念的基础之上,介绍了碳点结构特征和制备策略,着重综述了纳米碳点在生物成像与诊疗、传感器件、催化、光电器件和能量存储领域的最新研究进展,探讨了碳点研究目前存在的问题及未来的发展方向。     

生物热化学和热动力学研究进展

生命相关过程伴随着极其复杂的化学和物理过程,包含着物质变化和能量转换,其中部分能量不可避免地会以热的形式表现出来。用微量热技术和热动力学方法,研究复杂生命体系和相关反应的热动力学过程,可宏观地、本质地反映生命相关过程的内在规律。本文综述了生物量热学方法和技术在生命科学中的应用,介绍了生物量热技术在生态系统、生物组织和器官、细胞水平、亚细胞水平和分子层面等不同生物层次和结构水平上的研究现状和进展。     

食品及环境样品中双酚类物质的前处理及检测方法研究进展

双酚类物质作为一种环境内分泌干扰物,广泛存在于食品包装材料及环境介质中,对生态环境造成污染,也对人体健康产生一定危害。双酚残留是目前重要的食品安全问题,检测食品和环境样品中的双酚类物质的含量对人体健康具有重要的意义。由于残留目标物浓度通常较低,且实际样品存在基质干扰,因此需经一定的样品前处理,并结合仪器分析方法,提高检测效率,增强分析灵敏度与可靠性。常用的前处理分析方法主要有液液萃取、微波辅助萃取、固相萃取、固相微萃取、基质分散固相萃取、QuEChERS等,常用仪器分析方法包括液相色谱法、气相色谱法、毛细管电泳法、酶联免疫吸附测定法、生物传感器法等。该文综述了食品及环境样品中双酚类物质的样品前处理及仪器分析方法,为双酚类化合物的残留监测提供了参考依据。     

二维材料“遇见”生物大分子:机遇与挑战

二维材料的超薄原子层结构使其具有独特的力学性能、导热导电性以及巨大的比表面积,在能源存储、催化、传感和生物医学等领域引起了国内外学者的广泛关注。将二维材料与具有生物活性的生物大分子相结合可以为开发具有优异电学、力学和生物学功能的特种功能材料提供新的方法和途径。近年来,科研工作者针对这一方向展开了广泛的研究,取得了一系列重要的成果,使二维材料与生物大分子的结合与应用成为了新的研究热点。本文综述了近年来二维材料和生物大分子之间的相互作用及应用的研究进展,重点介绍了二维材料与生物大分子在分子水平上的相互作用机理,还总结了基于二维材料与生物大分子之间的相互作用在工程、疾病治疗和抗菌中的应用,并对其未来的研究趋势提出了展望。     

The Different Facets of Triclocarban: A Review

In the late 1930s and early 1940s, it was discovered that the substitution on aromatic rings of hydrogen atoms with chlorine yielded a novel chemistry of antimicrobials. However, within a few years, many of these compounds and formulations showed adverse effects, including human toxicity, ecotoxicity, and unwanted environmental persistence and bioaccumulation, quickly leading to regulatory bans and phase-outs. Among these, the triclocarban, a polychlorinated aromatic antimicrobial agent, was employed as a major ingredient of toys, clothing, food packaging materials, food industry floors, medical supplies, and especially of personal care products, such as soaps, toothpaste, and shampoo. Triclocarban has been widely used for over 50 years, but only recently some concerns were raised about its endocrine disruptive properties. In September 2016, the U.S. Food and Drug Administration banned its use in over-the-counter hand and body washes because of its toxicity. The withdrawal of triclocarban has prompted the efforts to search for new antimicrobial compounds and several analogues of triclocarban have also been studied. In this review, an examination of different facets of triclocarban and its analogues will be analyzed.     

Electrochemical Biosensors in Food Safety: Challenges and Perspectives

Safety and quality are key issues for the food industry. Consequently, there is growing demand to preserve the food chain and products against substances toxic, harmful to human health, such as contaminants, allergens, toxins, or pathogens. For this reason, it is mandatory to develop highly sensitive, reliable, rapid, and cost-effective sensing systems/devices, such as electrochemical sensors/biosensors. Generally, conventional techniques are limited by long analyses, expensive and complex procedures, and skilled personnel. Therefore, developing performant electrochemical biosensors can significantly support the screening of food chains and products. Here, we report some of the recent developments in this area and analyze the contributions produced by electrochemical biosensors in food screening and their challenges.     

Nondestructive characterization of nanoscale layered samples

Multilayered samples consisting of Al, Co and Ni nanolayers were produced by MBE and characterized nondestructively by means of SRXRF, μ-XRF, WDXRF, RBS, XRR, and destructively with SIMS. The main aims were to identify the elements, to determine their purity and their sequence, and also to examine the roughness, density, homogeneity and thickness of each layer. Most of these important properties could be determined by XRF methods, e.g., on commercial devices. For the thickness, it was found that all of the results obtained via XRR, RBS, SIMS and various XRF methods (SRXRF, μ-XRF, WDXRF) agreed with each other within the limits of uncertainty, and a constant deviation from the presets used in the MBE production method was observed. Some serious preliminary discrepancies in the results from the XRF methods were examined, but all deviations could be explained by introducing various corrections into the evaluation methods and/or redetermining some fundamental parameters.     

Chitosan-based membranes preparation and applications: Challenges and opportunities

Chitosan is an abundant natural biopolymer which finds a variety of applications due to its functionalization extending to pharmacology, controlled drug delivery, healing materials, biomedical engineering, food industry, agriculture, catalysis, biosorbents, wastewater treatment, etc. Chitosan can be transformed to distinct derivatives and composites and be modified and grafted for specific use. Many products like flakes, fine powders, beads, membranes, sponges, fibers, and gels can be formed from chitosan. Degradable membranes made of chitosan in conjunction with other materials have increased their scope and include adsorptive membranes for heavy metal and dyes, biomedical applications of chitosan electrospun nanofibers, metal complexation, polymer and modified chitosan-based nanocomposites, cellulose and chitosan composites in wastewater treatment, fuel cells and catalysis. The review has focused on a number of issues related to the said areas. Application of these composite membranes with real industrial effluents should be done with reference to the commercial adsorbents and then their application for removal of aromatics, oils, surfactants, etc. will become practical. The review covers existing gaps and gives future scope for research and innovation.     

Green synthesis of biogenic metal nanoparticles by terrestrial and aquatic phototrophic and heterotrophic eukaryotes and biocompatible agents

The size, shape and controlled dispersity of nanoparticles play a vital role in determining the physical, chemical, optical and electronic properties attributing its applications in environmental, biotechnological and biomedical fields. Various physical and chemical processes have been exploited in the synthesis of several inorganic metal nanoparticles by wet and dry approaches viz., ultraviolet irradiation, aerosol technologies, lithography, laser ablation, ultrasonic fields, and photochemical reduction techniques. However, these methodologies remain expensive and involve the use of hazardous chemicals. Therefore, there is a growing concern for the development of alternative environment friendly and sustainable methods. Increasing awareness towards green chemistry and biological processes has led to a necessity to develop simple, cost-effective and eco-friendly procedures. Phototrophic eukaryotes such as plants, algae, and diatoms and heterotrophic human cell lines and some biocompatible agents have been reported to synthesize greener nanoparticles like cobalt, copper, silver, gold, bimetallic alloys, silica, palladium, platinum, iridium, magnetite and quantum dots. Owing to the diversity and sustainability, the use of phototrophic and heterotrophic eukaryotes and biocompatible agents for the synthesis of nanomaterials is yet to be fully explored. This review describes the recent advancements in the green synthesis and applications of metal nanoparticles by plants, aquatic autotrophs, human cell lines, biocompatible agents and biomolecules.     

Plant-Based Seafood Analogs

There is a growing global need to shift from animal- towards plant-based diets. The main motivations are environmental/sustainability-, human health- and animal welfare concerns. The aim is to replace traditional animal-based food with various alternatives, predominantly plant-based analogs. The elevated consumption of fish and seafood, leads to negative impacts on the ecosystem, due to dwindling biodiversity, environmental damage and fish diseases related to large-scale marine farming, and increased intake of toxic substances, particularly heavy metals, which accumulate in fish due to water pollution. While these facts lead to increased awareness and rising dietary shifts towards vegetarian and vegan lifestyles, still the majority of seafood consumers seek traditional products. This encourages the development of plant-based analogs for fish and seafood, mimicking the texture and sensorial properties of fish-meat, seafood, or processed fish products. Mimicking the internal structure and texture of fish or seafood requires simulating their nanometric fibrous-gel structure. Common techniques of structuring plant-based proteins into such textures include hydrospinning, electrospinning, extrusion, and 3D printing. The conditions required in each technique, the physicochemical and functional properties of the proteins, along with the use of other non-protein functional ingredients are reviewed. Trends and possible future developments are discussed.