聚吡咯复合材料应用研究进展

聚吡咯复合材料由于制备简单方便、导电率高、无毒及热稳定性和机械延展性能好等优点而有着十分广阔的应用前景,并成为了一门学科交叉的新型研究领域。综述了聚吡咯复合材料在金属防腐、超级电容器、传感器、生物医药及其它领域在国内外的最新应用进展,对其应用中存在的主要问题进行了小结,对该复合材料的发展趋势进行了展望。     

基于碳基电极的电化学传感器检测铅离子的研究进展

重金属铅离子在空气、水、土壤和食物中普遍存在而且含量越来越高。铅离子具有较大的毒性,对人体的健康有很大的危害。近年来发展了很多检测铅离子的方法,其中以碳基为基底电极的电化学传感器由于具有简单、快速、灵敏等优点而备受青睐。从复合电极修饰材料的角度,综述了基于无机材料、有机材料和功能核酸等复合电极在检测铅离子的研究进展,重点介绍了碳基电极的发展历程、构建及铅离子的检测方法,对基于碳基电极的铅离子电化学传感器的发展前景进行了展望。     

CRISPR-Cas系统调控细菌生理功能的机制研究进展

CRISPR-Cas系统是存在于部分细菌和绝大部分古细菌中的一种获得性免疫防御系统,使细菌在外源性基因入侵时具有免疫防御能力。此外,CRISPR-Cas系统对细菌自身生物膜的形成、耐药性、毒力等生理功能都有调控作用,这对于研究人员进行相关研究有着重要意义。本文以细菌CRISPR-Cas系统及其发挥免疫防御作用的相关研究为基础展开论述,重点阐述该系统对细菌生理功能的调控作用,并对其应用前景进行了展望,以期为进一步研究细菌耐药性和致病性提供新思路。     

“共轭聚合物-产电菌”复合生物电极构建及其在微生物燃料电池中的应用

微生物燃料电池(Microbial fuel cell,MFC)作为一种生物电化学装置,在可再生能源生产和废水处理方面的巨大潜力已引起广泛关注。然而MFC面临输出功率低、欧姆内阻高以及启动时间长等问题,极大限制了其在实际工程中的应用。MFC中阳极是微生物附着的载体,对电子的产生及传递起着关键作用,开发优质的生物电极已发展成为改善MFC性能的有效途径。共轭聚合物具有成本低、电导率高、化学稳定性及生物相容性好等优点,利用共轭聚合物修饰生物电极结构,可以实现大比表面积、缩短电荷转移路径,从而实现高效生物电化学性能。同时,纳米级共轭聚合物包覆细菌,可以使细菌产生的电子有效地传递到电极。文中综述了最近报道的共轭聚合物在MFC中的应用,重点介绍了共轭聚合物修饰的MFC阳极,系统分析了共轭聚合物的优点及局限性,以及这些高效复合生物电极如何解决MFC应用中存在的低输出功率、高欧姆内阻及长启动时间等问题。     

基于表面修饰的活体细菌药物及递送策略

活体细菌在多种疾病防治领域显示出巨大的应用前景。然而，以细菌为基础的“活体材料”在生物医药应用中普遍面临生物利用度低、作用缺乏靶向性、治疗效果不佳和安全性等问题。表面工程技术为克服上述问题，发展新型活体细菌药物及其先进递送平台提供了重要的手段。该文首先介绍了活体细菌表面修饰的物理和化学手段；进一步讨论了表面修饰后的活体细菌药物所具有的不良环境耐受性、特定作用位点靶向性和定向运动等优良特性；最后总结了表面修饰改造的活体细菌在肿瘤和肠炎等不同疾病的诊断、成像和治疗中的应用。这项工作将有助于推进细菌疗法和活体细菌药物的进一步发展与应用。     

超级淋病菌来势汹汹

当超级细菌已经被越来越多的人熟知的时候，它也随之成为一场噩梦的代名词。近些年，超级细菌在全球不同国家大量涌现。使我们的临床治疗越加困难。     

PCR技术在食品微生物检测中的应用

PCR技术以其高强的特异性和灵敏度以及检测速度快、准确性好等优点,广泛地应用在食品微生物检测的各个领域,尤其对培养困难的细菌检测和抗原结构复杂的细菌鉴定方面。介绍了几种PCR方法的原理,以及其在食品微生物检测中的应用情况。     

光合细菌在水污染治理中的研究进展

光合细菌以其无毒、繁殖快、适应能力强、易人工培养等优点而在环境治理中受到重视。国内外对光合细菌的研究主要集中在水产养殖业(如净化水质,作饵料添加剂等)和生活及工业重污染水处理中的作用,关于光合细菌在景观微污染水体治理方面的作用研究较少。课题组研究发现光合细菌中的沼泽红假单胞菌对西南大学景观水中氨氮的去除率高达95%,暗示光合细菌能有效治理景观水污染。综述了光合细菌的分类、脱氮除磷原理以及目前光合细菌在治理有机废水、重金属废水和养殖污水方面的应用,并展望了光合细菌在处理景观微污染水体方面的应用前景,以期为进一步研究光合细菌在景观水治理中的作用提供参考。     

生物质制氢技术研究进展

氢能以其清洁,来源广泛及用途广等优点成为最有希望的替代能源之一,用可再生能源制氢是氢能发展的必然趋势。由于生物质制氢具有一系列独特的优点,它已成为发展氢经济颇具前景的研究领域之一。生物质制氢技术可以分为两类,一类是以生物质为原料利用热物理化学方法制取氢气,如生物质气化制氢,超临界转化制氢,高温分解制氢等热化学发制氢,以及基于生物质的甲烷、甲醇、乙醇的化学重整转化制氢等;另一类是利用生物转化途径转换制氢,包括直接生物光解,间接生物光解,光发酵,光合异养细菌水气转移反应合成氢气,暗发酵和微生物燃料电池等技术。本文综述了目前主要的生物质制氢技术及其发展概况,并分析了各技术的发展趋势。     

多频大幅脉冲传感系统监测3种食源性致病菌的生长趋势

【目的】探究智能电子舌伏安法结合特定的统计分析系统是否适用于示踪食品致病性细菌生长情况的快速监测。【方法】利用智能电子舌――多频大幅脉冲传感系统的伏安法,监测液体培养基中3种食源性致病菌的16个时段生长情况所致液体基质变化过程的综合信息;结合主成分分析法对获得的复杂综合信息数据进行统计学分析,按获得的主成分得分图分析检测样品。【结果】监测能力强的电极、频率段分别是：金黄色葡萄球菌的为钨电极的100 Hz、铂电极的1 Hz、银电极的10 Hz和钛电极的10 Hz频率段;大肠杆菌O157:H7的为金电极的100 Hz、铂电极的1 Hz、钛电极的1 Hz和钨电极的100 Hz频率段;枯草芽孢杆菌的为钯电极的1、10和100 Hz 3个频率段。【结论】本试验首次用多频大幅脉冲传感系统伏安法结合主成分分析法,能够有效的监测样品细菌的生长情况,有望成为一种具有多种优点的新型检测细菌生长情况的快速监测系统。     

Recent progress in electrodes for microbial fuel cells

The performance and cost of electrodes are the most important aspects in the design of microbial fuel cell (MFC) reactors. A wide range of electrode materials and configurations have been tested and developed in recent years to improve MFC performance and lower material cost. As well, anodic electrode surface modifications have been widely used to improve bacterial adhesion and electron transfer from bacteria to the electrode surface. In this paper, a review of recent advances in electrode material and a configuration of both the anode and cathode in MFCs are provided. The advantages and drawbacks of these electrodes, in terms of their conductivity, surface properties, biocompatibility, and cost are analyzed, and the modification methods for the anodic electrode are summarized. Finally, to achieve improvements and the commercial use of MFCs, the challenges and prospects of future electrode development are briefly discussed.     

微生物降解秸秆木质素的研究进展

我国秸秆资源丰富，每年产生逾8亿t作物秸秆。通过秸秆直接还田或肥料化还田不仅可以减少化肥的施用量，缓解农业污染压力，还能实现农作物秸秆的循环利用。木质素结构复杂，且与纤维素和半纤维素相互缠绕，因此秸秆的自然腐解过程中，木质素是主要的限速因子，为了提高降解效率，木质素降解菌的发掘和降解机制也逐渐成为研究热点。本文综述了降解木质素的真菌和细菌的研究现状，对比其真菌和细菌降解特性的优缺点并分析复合降解菌群的优势。随后对木质素降解酶系的酶学性质、在不同微生物中的表达特性进行总结，对木质素降解机制及衍生芳烃代谢路径的研究进展进行综述。最后整理木质素降解微生物在秸秆肥料化技术中的应用进展，并探讨了微生物降解秸秆木质素的应用前景和未来的研究方向。     

Pushing the Energy Output and Cyclability of Sodium Hybrid Capacitors at High Power to New Limits

Hybrid capacitors, especially sodium hybrid capacitors (NHCs), have continued to gain importance and are extensively studied based on their excellent potential to serve as advanced devices for fulfilling high energy and high power requirements at a low cost. To achieve remarkable performance in hybrid capacitors, the two electrodes employed must be superior with enhanced charge storage capability and fast kinetics. In this study, a new sodium hybrid capacitor system with a sodium super ionic conductor NaTi₂(PO₄)₃ grown on graphene nanosheets as an intercalation electrode and 2D graphene nanosheets as an adsorption electrode is reported for the first time. This new system delivers a high energy density of ≈80 W h kg^?1 and a high specific power of 8 kW kg^?1. An ultralow performance fading of ≈0.13% per 1000 cycles (90%–75 000 cycles) outperforms previously reported sodium ion capacitors. The enhanced charge transfer kinetics and reduced interfacial resistance at high current rates deliver a high specific energy without compromising the high specific power along with high durability, and thereby bridge batteries and capacitors. This new research on kinetically enhanced NHCs can be a trendsetter for the development of advanced energy storage devices requiring high energy—high power.     

Fe3O4/ 生物可降解复合材料研究

磁性氧化铁纳米粒子因具有尺寸小、低毒性和超顺磁性等特点,已经引起了生物化工、医药工业领域的广泛关注。生物可降解高分子材料是生物医用高分子研究中最活跃的领域之一,已广泛用于外科手术缝合线,植入体材料及药物释放载体等。将Fe3O4和生物可降解高分子材料进行复合,可以扩大两者的应用范围,达到理想的治疗效果,并有望开创临床治疗的新时代。本文介绍了磁性四氧化三铁粒子的化学制备方法,包括共沉淀法、溶胶-凝胶法、微乳液法,并对各种方法的优缺点进行了比较;重点阐述了磁性壳聚糖,磁性聚乳酸,磁性PEG,磁性PCL复合材料的制备,及它们在酶的固定化、磁靶向药物及基因载体等医学领域的应用,显示了Fe3O4/生物可降解复合材料在医学领域的广阔应用前景;最后对复合材料走向临床应用所面临的问题及发展前景进行了讨论。     

Hollow Carbon Spheres and Their Hybrid Nanomaterials in Electrochemical Energy Storage

Electrochemical energy storage is of extraordinary importance for fulfilling the utilization of renewable and sustainable energy sources. There is an increasing demand for energy storage devices with high energy and power densities, prolonged stability, safety, and low cost. In the past decade, numerous research efforts have been devoted to achieving these requirements, especially in the design of advanced electrode materials. Hollow carbon spheres (HCS) derived nanomaterials combining the advantages of 3D HCS and porous structures have been considered as alternative electrode materials for advanced energy storage applications, due to their unique features such as high surface‐to‐volume ratios, encapsulation capability, together with outstanding chemical and thermal stability. In this review, the authors first present a comprehensive overview of the synthetic strategies of HCS, and elucidate the design and synthesis of HCS‐derived nanomaterials including various types of HCS and their nanohybrids. Additionally, their significant roles as electrode materials for supercapacitors, lithium‐ion or sodium‐ion batteries, and sulfur hosts for lithium sulfur batteries are highlighted. Finally, current challenges in the synthesis of HCS and future directions in HCS‐derived nanomaterials for energy storage applications are proposed.     

Capacitor‐Integrated Triboelectric Nanogenerator Based on Metal–Metal Contact for Current Amplification

The electrical power of triboelectric nanogenerators (TENGs) is increased by surface modifications, and they can successfully power portable devices alone. However, modifying the material and its surface may limit the device lifetime, and most of the portable applications demonstrated in previous studies have excessive input conditions. In this study, a capacitor‐integrated TENG (CI‐TENG) that uses the fundamental mechanisms of the Leyden jar is developed. In this device, a long sheet metal (capacitor electrode)–polymer–metal composite (TENG electrode) is rolled inside the casing cylinder, and a capacitor unit is fabricated at the end of the sheet composite. This new operating mechanism of the CI‐TENG is analyzed in terms of the dielectric constant of the capacitor unit and the metal‐to‐metal contact between electrodes. By instantaneous charging and discharging of the capacitor unit inside the CI‐TENG, it can generate a peak open‐circuit voltage of 156 V and a peak closed‐circuit current of 4.3 mA under manual input. It charges a capacitor more than three times faster than a conventional TENG does. Furthermore, the internal impedance of the CI‐TENG is decreased to 200 kΩ without any external circuit.     

乳酸菌及其细菌素在海水鱼保鲜中应用的研究进展

随着人们对生鲜海水鱼产品需求的日益增加,其保鲜技术的研发成为热点。乳酸菌及其细菌素以其天然、强抗菌性及安全可靠等优势,在海水鱼保鲜方面有广阔的应用前景。综述了海水鱼中乳酸菌细菌素分类、分离纯化方法,分析了乳酸菌产生的有机酸、细菌素和H₂O₂的抑菌作用,概述了乳酸菌及其细菌素在海水鱼保鲜中的应用现状和监管问题,提出了在应用上存在的问题和今后的发展重点。进一步阐明了乳酸菌生物保鲜剂在海水鱼保鲜中的应用价值,以推动海水鱼保鲜技术的发展。     

Energy Storage Data Reporting in Perspective—Guidelines for Interpreting the Performance of Electrochemical Energy Storage Systems

Due to the tremendous importance of electrochemical energy storage, numerous new materials and electrode architectures for batteries and supercapacitors have emerged in recent years. Correctly characterizing these systems requires considerable time, effort, and experience to ensure proper metrics are reported. Many new nanomaterials show electrochemical behavior somewhere in between conventional double‐layer capacitor and battery electrode materials, making their characterization a non‐straightforward task. It is understandable that some researchers may be misinformed about how to rigorously characterize their materials and devices, which can result in inflation of their reported data. This is not uncommon considering the current state of the field nearly requires record breaking performance for publication in high‐impact journals. Incorrect characterization and data reporting misleads both the materials and device development communities, and it is the shared responsibility of the community to follow rigorous reporting methodologies to ensure published results are reliable to ensure constructive progress. This tutorial aims to clarify the main causes of inaccurate data reporting and to give examples of how researchers should proceed. The best practices for measuring and reporting metrics such as capacitance, capacity, coulombic and energy efficiencies, electrochemical impedance, and the energy and power densities of capacitive and pseudocapacitive materials are discussed.     

Porous Electrode Materials for Lithium‐Ion Batteries – How to Prepare Them and What Makes Them Special

Numerous benefits of porous electrode materials for lithium ion batteries (LIBs) have been demonstrated, including examples of higher rate capabilities, better cycle lives, and sometimes greater gravimetric capacities at a given rate compared to nonporous bulk materials. These properties promise advantages of porous electrode materials for LIBs in electric and hybrid electric vehicles, portable electronic devices, and stationary electrical energy storage. This review highlights methods of synthesizing porous electrode materials by templating and template‐free methods and discusses how the structural features of porous electrodes influence their electrochemical properties. A section on electrochemical properties of porous electrodes provides examples that illustrate the influence of pore and wall architecture and interconnectivity, surface area, particle morphology, and nanocomposite formation on the utilization of the electrode materials, specific capacities, rate capabilities, and structural stability during lithiation and delithiation processes. Recent applications of porous solids as components for three‐dimensionally interpenetrating battery architectures are also described.     

金黄色葡萄球菌组分疫苗研究进展

临床上,耐药性的金黄色葡萄球菌日益增多,极其耐药的菌株甚至获得了超级耐药细菌的称谓,难以找到有效的抗菌素控制其感染,因而研制有效的疫苗来防治金黄色葡萄球菌感染显得更加重要。对研制开发的金黄色葡萄球菌荚膜多糖疫苗、纤维粘连结合蛋白疫苗、RNAⅢ激活蛋白疫苗以及核酸疫苗等进行了综述。