介孔材料在电化学生物传感器中的应用进展

回顾了近年来有序介孔材料在电化学生物传感器中的应用及发展状况,简述了规则介孔材料的合成方法及特点、生物分子在介孔材料上的固定方法及其优缺点,通过总结近年几种介孔材料电化学生物传感器的研究进展,提出介孔材料在电化学生物传感器领域的应用前景(引用文献49篇)。     

功能化有序介孔二氧化硅材料在分析样品前处理中的应用

功能化有序介孔二氧化硅材料具有均一可调的介孔孔径、规则的孔道、稳定的骨架结构、易于修饰的内表面和较高的比表面积、高的吸附容量等特性,可用于生物、医药、环境样品等复杂基体中痕量分析物的高选择性分离与富集,因此在样品前处理中的应用特别引人瞩目。文中简要介绍了功能化有序介孔二氧化硅材料的制备方法,综述了功能化有序介孔二氧化硅材料在分离富集金属离子、有机污染物以及生物大分子样品前处理中的应用进展。     

有序介孔硅胶及其复合材料作固定相在液相色谱中的应用

系统地介绍了有序介孔硅胶及其复合材料的研究进展。重点评述了颗粒状无机介孔硅胶材料、颗粒状有机-无机复合介孔硅胶材料、手性介孔硅胶材料和整块介孔硅胶材料在用作液相色谱固定相方面的最新进展。对硅基有序介孔材料制备方面存在的问题进行了分析,并就该领域今后的发展趋势做了展望。     

酶在有序介孔材料上的固定化

本文回顾了近年来有序介孔材料用于酶的固定化的研究进展;对比了不同固定化方法对介孔材料固定化酶活性的影响以及各种固定化方法的优缺点;分析了影响酶在有序介孔材料上的固定化因素,并分别对这些影响因素进行了讨论;对酶在有序介孔材料上固定化的发展和潜在的应用进行了讨论,指出介孔材料固定化酶的潜在应用.     

功能化介孔材料在环境领域的应用研究进展

介孔材料是一种具有较大比表面积和高度有序孔道结构的材料,而功能化介孔材料是将介孔材料改性而使其具有不同的功能。这种材料由于具有极好的吸附和催化性能而被广泛应用于环境领域中。本文总结了功能化介孔材料的制备方法,包括引入官能团、掺杂金属和酸改性;探讨分析了几种制备方法下的功能化介孔材料的特点和应用前景;重点介绍了功能化介孔材料在吸附重金属、有机污染物、染料、CO2以及催化领域的研究进展;最后展望了未来功能化介孔材料的应用前景和发展趋势,以期为功能化介孔材料的发展提供参考和指明方向。     

磁性有序介孔炭的合成及新应用

有序介孔炭作为一类崭新的功能材料,因具有高比表面积、孔径分布集中、孔径结构可调、大孔容、高度热稳定性和机械稳定性等优异特性而备受瞩目,广泛应用于水体净化、催化及光、电、磁等领域。其极佳的生物相容性使其在药物负载领域有巨大的潜在应用价值。根据磁性有序介孔炭材料的最新研究动态和应用研究热点,本文综述了磁性有序介孔炭合成作用机理、药物负载效率和介孔结构(如比表面、孔容、孔径分布)制约因素。讨论分析了各种合成方法的优劣和孔结构参数制约载药量的研究瓶颈。并着重对磁性有序介孔炭在医药领域的新应用进行了阐述和评价。旨在为探讨磁性有序介孔炭在优化合成工艺技术参数、提高药物负载量和靶向释药应用趋势方面提供理论导向。     

有序介孔材料: 历史、 现状与发展趋势

有序介孔材料是指孔径在2~50 nm之间的多孔材料, 是一类具有均匀孔径、 高有序度纳米孔道和高比表面积的新材料. 在过去30年里, 有序介孔材料的研究取得了长足的进步, 在可控合成、 结构设计和调控及功能化等方面形成了系统的理论. 同时, 其应用领域也不断被拓展, 包括能源存储与转化、 催化、 生物医药和传感等方面. 本文首先回顾了有序介孔材料的发展历史, 简要介绍发展过程中“里程碑式”的研究工作; 然后根据构效关系总结了其在不同领域应用的最新进展; 最后讨论了有序介孔材料领域进一步发展所面临的挑战与机遇, 并对未来前景进行了展望.     

软模板合成有序介孔碳材料

有序介孔碳材料由于其较大的表面积、均一的孔径、良好的热稳定性和化学稳定性,广泛应用于吸附、分离、催化以及能量储存等众多领域。与传统的以硅基介孔材料为硬模板的反向复制方法相比,通过嵌段共聚物和聚合物前驱体之间的有机-有机自组装的软模板法简便易行,已成为合成有序介孔碳材料有效方法。本论文综述了介孔碳材料的软模板合成机制、合成方法、功能化及其应用,对合成技术、结构控制、孔径调控以及形貌控制等方面进行了讨论,并探讨了其在吸附、催化、电极材料等领域的应用。     

介孔材料孔道内进行的非自由基聚合反应研究进展

介孔材料在催化、吸附、分离等领域有潜在的应用价值.近来,研究人员将介孔材料的有序孔道作为聚合微反应器,在其内部进行了许多类型的聚合反应,如自由基聚合反应和非自由基聚合反应.本文综述了近二十年来在介孔材料孔道内各类单体进行的非自由基聚合反应,包括氧化聚合反应、配位聚合反应、缩合聚合反应、开环聚合反应和阳离子聚合反应,阐述...     

磁性介孔材料的研究进展

磁性介孔材料兼具介孔材料和磁性材料的双重优势,如高比表面积、孔径均一、高吸附性和可磁分离性,具有广泛的应用前景和重大的研究意义,受到化学和材料工作者的极大关注。本文综述了磁性介孔材料的制备方法及其改性研究,同时介绍了磁性介孔材料在污水处理、催化反应、药物控释和生物分子的分离提纯等领域的一些应用进展。     

甲壳素基新材料研究进展

甲壳素/壳聚糖良好的生物相容性、生物可降解性及独特的生理活性使其成为非常有应用价值的天然高分子材料,当前已成为新材料领域的研究热点.甲壳素/壳聚糖具有良好的可加工性能,可固定贵金属、半导体纳米材料等活性催化物质,同时其本身也具有催化作用,是一类绿色环境友好的高分子催化材料.良好的生物相容性和生物可降解性使甲壳素/壳聚糖...     

Thermally Responsive Materials for Bioimaging

The last decade has witnessed multiple thermally responsive materials emerge as a significant class of stimuli‐responsive materials. These materials are elaborately designed and exert interesting properties. Herein, an overview of thermally responsive materials with respect to design strategies, fabrication procedures, and their applications is presented. Recently reported thermally responsive materials are highlighted. Then, applications of thermally responsive materials in bioimaging are summarized.     

Thermally degradable thermosetting materials

Thermosetting materials have been widely used in a variety of applications but they generally display poor tractability after curing, which limits their use in applications where degradable or re-workable polymers are advantageous. Moreover, recyclability and biodegradability of thermosetting polymer also limit their use in applications where recycling and biodegradation are important. A variety of thermally degradable linkages within thermosetting materials have been studied both in academia and industry to develop re-workable adhesives. This review reports the recent development in thermosetting materials containing thermally breakable linkages that exhibit re-workability as well as potential for recyclability and biodegradability.     

Robust Aqua Material: A Pressure‐Resistant Self‐Assembled Membrane for Water Purification

“Aqua materials” that contain water as their major component and are as robust as conventional plastics are highly desirable. Yet, the ability of such systems to withstand harsh conditions, for example, high pressures typical of industrial applications has not been demonstrated. We show that a hydrogel‐like membrane self‐assembled from an aromatic amphiphile and colloidal Nafion is capable of purifying water from organic molecules, including pharmaceuticals, and heavy metals in a very wide range of concentrations. Remarkably, the membrane can sustain high pressures, retaining its function. The robustness and functionality of the water‐based self‐assembled array advances the idea that aqua materials can be very strong and suitable for demanding industrial applications.     

Liquid-Phase Synthesis of Iron Oxide Nanostructured Materials and Their Applications

Owing to their high natural abundance, low cost, easy availability, and excellent magnetic properties, considerable interest has been devoted to the synthesis and applications of iron oxide nanostructured materials. Liquid-phase synthesis methods are economical and environmentally friendly with low energy consumption and volatile emissions, and as such have received much attention for the preparation of iron oxide nanostructured materials. Herein, the liquid-phase synthesis methods of iron oxide nanostructured materials including the co-precipitation method, microemulsion method, conventional hydrothermal and solvothermal methods, microwave-assisted heating method, sonolysis method, and other methods are summarized and reviewed. Many iron oxide nanostructured materials, self-assembled nanostructures, and nanocomposites have been successfully prepared, which are of great significance to enhance their structure-dependent properties and applications. The specific roles of liquid-phase chemical reaction parameters in regulating the chemical composition, structure, crystallinity, morphology, particle size, and dispersive behavior of the as-prepared iron oxide nanostructured materials are emphasized. The biomedical, environmental, and electrochemical energy storage applications of iron oxide nanostructured materials are discussed. Finally, challenges and perspectives are proposed for future investigations on the liquid-phase synthesis and applications of iron oxide nanostructured materials.     

生物可降解及生物材料的电场纺丝及应用

电场纺丝是制备生物可降解及生物材料纳米纤维非织造布的简单工艺,由于纳米纤维具有较大的比表面积,具有多孔结构,使其在生物医学领域,如：组织工程、药物缓释及医用纱布等领域有潜在的应用前景。本文综述了生物降解材料及生物材料的电场纺丝及其应用。     

共轭聚合物发光和光伏材料研究进展

聚合物光电功能材料与器件因其广阔的应用前景,1990年以年来吸引了世界各国学术界的广泛关注和兴趣.聚合物光电子器件主要包括聚合物电致发光二极管、聚合物场效应晶体管和聚合物太阳能电池等,其使用的关键材料是共轭聚合物光电子材料,包括共轭聚合物发光材料、场效应晶体管材料和光伏材料等.本文主要对共轭聚合物电致发光材料和光伏材料的研究进展进行综述,介绍了这些聚合物材料的种类、结构和性质以及在聚合物电致发光器件和聚合物太阳能电池中的应用.并讨论了当前共轭聚合物光电子材料中的关键科学问题和今后的发展方向.     

Two-dimensional mesoporous materials：From fragile coatings to flexible membranes

This paper reviews the progress of two-dimensional mesoporous materials including their synthesis strategy,mesostructure,composition,surface property,flexibility,and potential applications.During the past two decades,research on two-dimensional mesoporous materials has experienced an evolution from fragile coatings to flexible membranes.Aiming at practical applications,it is significant to support mesoporous materials with proper matrices for example porous membranes especially flexible ones to form mesoporous composite membranes with designed pore size and chemistry.     

“Aggregation-induced emission” of transition metal compounds: Design,mechanistic insights,and applications

In the last decades, compounds with ‘Aggregation-Induced Emission’ (AIE), which are weakly or non-emissive at all in solution but exhibit a strong luminescence in aggregated states, have emerged as an extraordinary breakthrough in the field of luminescent materials, allowing to circumvent ‘Aggregation Caused Quenching’ (ACQ), which in many cases prevents the development of efficient solid-state materials for optoelectronic applications.Since the discovery of AIE, many AIE-active materials have been developed, most of them composed of organic molecules, and thus fluorescent in nature. Although a wide range of applications such as bioimaging, sensing, multi-stimuli responsive materials, and optoelectronic devices have been proposed for this new class of materials, triplet harvesting phosphorescent materials have much longer lifetimes as compared to their singlet harvesting analogues, and for this particular reason, the development of AIE-active phosphorescent materials seems to be a promising strategy from the applications point of view. In this respect, the synthesis of new AIE-active systems including heavy metals that would facilitate the population of low-lying excited triplet states via spin-orbit coupling (SOC), for which the strength increases as the fourth power of atomic number, i.e. Z⁴, is highly desirable. This review covers the design and synthetic strategies used to obtain the AIEgens reported in the literature that contain either d-block metals such as Cu(I), Zn(II), Re(I), Ru(II), Pd(II), Ir(III), Pt(II), Au(I), and Os(IV), describing the mechanisms proposed to explain their AIE. New emerging high-tech applications such as OLEDs, chemical sensors or bioimaging probes proposed for these materials are also discussed in a separate section.     

Carbon Dots in Porous Materials: Host–Guest Synergy for Enhanced Performance

Carbon dots (CDs) are emerging as a new class of carbon nanomaterials, which have inspired growing interest for their widespread applications in anti-counterfeiting, sensing, bioimaging, optoelectronic and energy-related fields. In terms of the concept of host–guest assembly, immobilizing CDs into porous materials (PMs) has proven to be an effective strategy to avoid the aggregation of bare CDs in solid state, in particular, the host—guest synergy with both merits of CDs and PMs affords composites promising properties in afterglow and tunable emissions, as well as optimizes their performance in optics, catalysis, and energy storage. This Minireview summarizes the recent progress in the research of CDs@PMs, and highlights synthetic strategies of constructing composites and roles of porous matrices in boosting the applications of CDs in diverse areas. The prospect of future exploration and challenges are proposed for designing advanced CDs-based functional nanocomposite materials.