基于电镜和免疫组化的线粒体数目标志物评估肝癌的初步研究

目的:研究线粒体数目与肝癌生长的相关性。方法:利用电子显微镜技术定量肝癌组织中线粒体数目,利用免疫组织化学技术评估肝癌组织中的线粒体标志物COX Ⅳ及HSP60表达水平,分析电镜肝癌线粒体定量结果与COX Ⅳ及HSP60表达量之间的相关性,并比较肝癌中线粒体数目、COX Ⅳ及HSP60表达量与肝癌直径之间的关系。结果:与癌旁相比,肝癌组织中线粒体数目(P0.001)、COX Ⅳ及HSP60的表达量显著降低(P=0.0417,P=0.0290)。COX Ⅳ及HSP60表达水平与线粒体数目无显著相关(r~2=0.009,P=0.5468;r~2=0.056,P=0.1396)。线粒体数目与肿瘤直径显著负相关(r~2=0.1086,P=0.0434),COX Ⅳ及HSP60表达量与肿瘤直径无显著相关(r~2=0.0251,P=0.3287;r~2=0.0461,P=0.1830)。结论:线粒体数目是潜在的肝癌生长标志物。但常用的线粒体定量分子HSP60与COX Ⅳ并不能准确定量肝癌线粒体。     

基于体视显微镜观察两种鼠氟斑牙的形态变化

目的:通过对染氟大鼠和小鼠氟斑牙的观察,进一步确定氟斑牙作为慢性氟中毒的诊断指标的重要性。方法:通过不同浓度和不同时间的氟染毒,利用数码体视显微镜观察Wistar大鼠和C57BL/6J小鼠氟斑牙的形态变化。将Wistar大鼠随机分为4组,每组8只,共计32只,分笼饲养,C57BL/6J小鼠4组,每组12只,共计48只,分8笼饲养。对照组:蒸馏水组,实验组三组:氟化钠分别为50 mg/L组,100 mg/L组和150 mg/L组。在染氟至6个月时,应用在体视显微镜观察大鼠和小鼠牙齿的动态改变。结果:染氟组Wistar大鼠和C57BL/6J小鼠牙齿均出现规则的斑纹、白垩状、延迟断裂、缺损等症状。随着染氟时间的延长,C57BL/6J小鼠氟斑牙的损伤程度大于Wistar大鼠。在慢性氟中毒大鼠和小鼠的牙齿变化中发现,大鼠和小鼠的牙齿变化程度与种属有着密切的关系。结论:通过利用体视显微镜对Wistar大鼠和C57BL/6J小鼠染氟6个月进行氟斑牙的观察分析,为慢性氟中毒鼠模型提供氟斑牙的形态学的详实依据。并且,可根据研究需要适宜选择氟斑牙的动物模型。     

Intense Chiral Optical Phenomena in Racemic Polymers by Cocrystallization With Chiral Guest Molecules: A Brief Overview

This review is devoted to the chiral optical behavior of films of racemic polymers whose chirality is induced by cocrystallization with nonracemic (also temporary) guest molecules. We provide examples of macromolecular amplification of chirality, produced by molecular and supramolecular mechanisms, on industrially relevant polymers like poly(2,6‐dimethyl‐1,4‐phenylene)oxide (PPO) and syndiotactic polystyrene (s‐PS). Chirality 28:29–38, 2016. © 2015 Wiley Periodicals, Inc.     

Helical Polybissilsesquioxane Bundles Prepared Using a Self‐Templating Approach

Polybissilsesquioxanes with single‐handed helical morphologies attracted much attention during the last decade, which could be applied as asymmetric catalysts and chiral stationary phases. Herein, a pair of chiral biphenylene‐bridged bissilsesquioxanes were synthesized. They self‐assembled into helical bundles in ethanol, behavior that was confirmed in field emission scanning electron microscopy images. Circular dichroism analysis indicated that the biphenylene groups twisted in a single‐handed fashion. Single‐handed helical polybissilsesquioxane bundles were prepared via polycondensation of the bissilsesquioxanes, using a self‐templating approach. Because of the shrinkage that occurred during polycondensation, the helical pitches of the bundles were shorter than those of their corresponding organic self‐assemblies. The wide‐angle X‐ray diffraction pattern indicated that there were no π–π interactions among the diphenylene groups. The circular dichroism spectra indicated that the chirality was successfully transferred from the bissilsesquioxane self‐assemblies to the polybissilsesquioxane. The polybissilsesquioxanes displayed a capacity for the adsorption of nitrobenzene and had potential application for enantioseparation. Chirality 28:44–48, 2016. © 2015 Wiley Periodicals, Inc.     

Heme Orientation of Cavity Mutant Hemoglobins (His F8 → Gly) in Either α or β Subunits: Circular Dichroism, 1H NMR,and Resonance Raman Studies

Native human adult hemoglobin (Hb A) has mostly normal orientation of heme, whereas recombinant Hb A (rHb A) expressed in E. coli contains both normal and reversed orientations of heme. Hb A with the normal heme exhibits positive circular dichroism (CD) bands at both the Soret and 260‐nm regions, while rHb A with the reversed heme shows a negative Soret and decreased 260‐nm CD bands. In order to examine involvement of the proximal histidine (His F8) of either α or β subunits in determining the heme orientation, we prepared two cavity mutant Hbs, rHb(αH87G) and rHb(βH92G), with substitution of glycine for His F8 in the presence of imidazole. CD spectra of both cavity mutant Hbs did not show a negative Soret band, but instead exhibited positive bands with strong intensity at the both Soret and 260‐nm regions, suggesting that the reversed heme scarcely exists in the cavity mutant Hbs. We confirmed by ¹H NMR and resonance Raman (RR) spectroscopies that the cavity mutant Hbs have mainly the normal heme orientation in both the mutated and native subunits. These results indicate that the heme Fe‐His F8 linkage in both α and β subunits influences the heme orientation, and that the heme orientation of one type of subunit is related to the heme orientation of the complementary subunits to be the same. The present study showed that CD and RR spectroscopies also provided powerful tools for the examination of the heme rotational disorder of Hb A, in addition to the usual ¹H NMR technique. Chirality 28:585–592, 2016. © 2016 Wiley Periodicals, Inc.     

Optical Activity Governed by Local Chiral Structures in Two‐Dimensional Curved Metallic Nanostructures

Chiral nanostructures show macroscopic optical activity. Local optical activity and its handedness are not uniform in the nanostructure, and are spatially distributed depending on the shape of the nanostructure. In this study we fabricated curved chain nanostructures made of gold by connecting linearly two or more arc structures in a two‐dimensional plane. Spatial features of local optical activity in the chain structures were evaluated with near‐field circular dichroism (CD) imaging, and analyzed with the aid of classical electromagnetic simulation. The electromagnetic simulation predicted that local optical activity appears at inflection points where arc structures are connected. The handedness of the local optical activity was dependent on the handedness of the local chirality at the inflection point. Chiral chain structures have odd inflection points and the local optical activity distributed symmetrically with respect to structural centers. In contrast, achiral chain structures have even inflection points and showed antisymmetric distribution. In the near‐field CD images of fabricated chain nanostructures, the symmetric and antisymmetric distributions of local CD were observed for chiral and achiral chain structures, respectively, consistent with the simulated results. The handedness of the local optical activity was found to be determined by the handedness of the inflection point, for the fabricated chain structures having two or more inflection points. The local optical activity was thus governed primarily by the local chirality of the inflection points for the gold chain structures. The total effect of all the inflection points in the chain structure is considered to be a predominant factor that determines the macroscopic optical activity. Chirality 28:540–544, 2016. © 2016 Wiley Periodicals, Inc.     

倒置双光子显微镜的使用与维护

双光子激发荧光显微是一种非线性光学显微技术,它结合了激光扫描共聚焦显微镜和双光子激发技术,具有高时空分辨率、高信噪比和固有的三维层析分辨能力等优点。介绍了双光子显微镜的软硬件组成和技术参数,样品制备方法,双光子图像采集的常用操作规程,日常维护和仪器管理等方面。旨在为双光子仪器的使用者与管理者提供参考,使之更好地服务于教学与科研。     

Inverse Optical Cavity Design for Ultrabroadband Light Absorption Beyond the Conventional Limit in Low‐Bandgap Nonfullerene Acceptor–Based Solar Cells

In the subwavelength regime, several nanophotonic configurations have been proposed to overcome the conventional light trapping or light absorption enhancement limit in solar cells also known as the Yablonovitch limit. It has been recently suggested that establishing such limit should rely on computational inverse electromagnetic design instead of the traditional approach combining intuition and a priori known physical effect. In the present work, by applying an inverse full wave vector electromagnetic computational approach, a 1D nanostructured optical cavity with a new resonance configuration is designed that provides an ultrabroadband (≈450 nm) light absorption enhancement when applied to a 107 nm thick active layer organic solar cell based on a low‐bandgap (1.32 eV) nonfullerene acceptor. It is demonstrated computationally and experimentally that the absorption enhancement provided by such a cavity surpasses the conventional limit resulting from an ergodic optical geometry by a 7% average over a 450 nm band and by more than 20% in the NIR. In such a cavity configuration the solar cells exhibit a maximum power conversion efficiency above 14%, corresponding to the highest ever measured for devices based on the specific nonfullerene acceptor used.     

Perspectives of surface plasmon resonance sensors for optimized biogas methanation

Biogas production is becoming significantly viable as an energy source for replacing fossil‐based fuels. The further development of the biogas production process could lead to significant improvements in its potential. Wastewater treatment currently accounts for 3% of the electrical energy load in developed countries, while it could be developed to provide a source of nitrogen and phosphorus, in addition to energy. The improvement of anaerobic digestion (AD) detection technologies is the cornerstone to reach higher methane productivities and develop fully automatized processes to decrease operational costs. New sensors are requested to automatically obtain a better interpretation of the complex and dynamical internal reactor environment. This will require detailed systematic detection in order to realize a near‐optimal production process. In this review, optical fiber‐based sensors will be discussed to assess their potential for use in AD. There is currently a disparity between the complexity of AD, and online detection. By improving the durability, sensitivity, and cost of dissolved H₂ (as well as H₂S, acetic acid, ammonia, and methane) sensor technology, further understanding of the AD process may allow the prevention of process failure. The emergence of surface plasmon resonance (SPR) sensing with optical fibers coupled with the H₂‐sensitive metal palladium, allows detection of dissolved hydrogen in liquid. By implementing these SPR sensors into AD, improvements to the biogas production process, even at small scales, may be achieved by guiding the process in the optimum direction, avoiding the collapse of the biological process. This review intends to assess the feasibility of online, cost‐effective, rapid, and efficient detection of dissolved H₂, as well as briefly assessing H₂S, acetic acid, ammonia, and methane in AD by SPR.     

High‐Voltage Photogeneration Exclusively via Aggregation‐Induced Triplet States in a Heavy‐Atom‐Free Nonplanar Organic Semiconductor

The electron–hole recombination kinetics of organic photovoltaics (OPVs) are known to be sensitive to the relative energies of triplet and charge‐transfer (CT) states. Yet, the role of exciton spin in systems having CT states above 1.7 eV—like those in near‐ultraviolet‐harvesting OPVs—has largely not been investigated. Here, aggregation‐induced room‐temperature intersystem crossing (ISC) to facilitate exciton harvesting in OPVs having CT states as high as 2.3 eV and open‐circuit voltages exceeding 1.6 V is reported. Triplet excimers from energy‐band splitting result in ultrafast CT and charge separation with nonradiative energy losses of <250 meV, suggesting that a 0.1 eV driving force is sufficient for charge separation, with entropic gain via CT state delocalization being the main driver for exciton dissociation and generation of free charges. This finding can inform engineering of next‐generation active materials and films for near‐ultraviolet OPVs with open‐circuit voltages exceeding 2 V. Contrary to general belief, this work reveals that exclusive and efficient ISC need not require heavy‐atom‐containing active materials. Molecular aggregation through thin‐film processing provides an alternative route to accessing 100% triplet states on photoexcitation.