This study investigates the market's response to analyst report readability. We posit that readable reports decrease uncertainty of earnings expectations and by extension increase stock prices. Our results show that the equity market reacts more positively to readable reports and that this positive reaction is attributable to a reduction in uncertainty of future performance. Moreover, we find that the effect of readability on stock prices is significantly positive only for firms with greater R&D spending, higher bid‐ask spreads, a greater proportion of uninformed investors, and more experienced analysts, which suggests that readability matters only when information asymmetry in the equity market is high.
Photocatalysts produce free radicals upon receiving light energy; thus, they possess antibacterial properties. Silver (Ag) is an antibacterial material that disrupts bacterial physiology. Our previous study reported that the high antibacterial property of silver nanoparticles on the surfaces of visible light-responsive nitrogen-doped TiO2 photocatalysts [TiO2(N)] could be further enhanced by visible light illumination. However, the major limitation of this Ag-TiO2 composite material is its durability; the antibacterial property decreased markedly after repeated use. To overcome this limitation, we developed TiO2(N)/Ag/TiO2(N) sandwich films in which the silver is embedded between two TiO2(N) layers. Various characteristics, including silver and nitrogen amounts, were examined in the composite materials. Various analyses, including electron microscopy, energy dispersive spectroscopy, X-ray diffraction, and ultraviolet–visible absorption spectrum and methylene blue degradation rate analyses, were performed. The antibacterial properties of the composite materials were investigated. Here we revealed that the antibacterial durability of these thin films is substantially improved in both the dark and visible light, by which bacteria, such as Escherichia coli, Streptococcus pyogenes, Staphylococcus aureus, and Acinetobacter baumannii, could be efficiently eliminated. This study demonstrated a feasible approach to improve the visible-light responsiveness and durability of antibacterial materials that contain silver nanoparticles impregnated in TiO2(N) films.
This paper reports a new polymeric, aspheric SU-8 microlens array using a soft replica molding method and its application to cell counting. A bio-detection system comprising the SU-8 microlens array with its three-dimensional convex geometry, a micro flow cytometer chip and an optical detection module is demonstrated. A polymethyl methacrylate (PMMA) template is first fabricated and then the SU-8 microlens array is replicated using a new fabrication process. The developed array has four sizes of microlens, with diameters of 50, 100, 150 and 200 µm. Experimental results show that the surface roughness of the microlens was only 10.2 nm for the SU-8 polymer material. The microlens had good surface uniformity and excellent optical properties with calculated focal lengths ranging from tens to hundreds of micrometers, depending on their dimensions. A microlens with a high numerical aperture ranging from 0.3 to 0.75 was achieved. The microlens array can be used to increase the efficiency of the optical detection, allowing high-resolution detection and providing a high signal-to-noise ratio. The microlens array has the potential to be widely used for optical or biophotonic applications and for the integration of microfluidic devices. In order to demonstrate its capability, the developed microlens array was integrated with a micro flow cytometer for cell counting applications. Successful counting of fluorescent-labeled human lung cancer cells is demonstrated using the developed method.
We present DART, an open domain structured DAta-Record-to-Text generation dataset with over 82k instances (DARTs). Data-to-text annotations can be a costly process, especially when dealing with tables which are the major source of structured data and contain nontrivial structures. To this end, we propose a procedure of extracting semantic triples from tables that encodes their structures by exploiting the semantic dependencies among table headers and the table title. Our dataset construction framework effectively merged heterogeneous sources from open domain semantic parsing and spoken dialogue systems by utilizing techniques including tree ontology annotation, question-answer pair to declarative sentence conversion and predicate unification, all with minimum post-editing. We present systematic evaluation on DART as well as new state-of-the-art results on WebNLG 2017 to show that DART (1) poses new challenges to existing data-to-text datasets and (2) facilitates out-of-domain generalization. Our data and code can be found at https://github. com/Yale-LILY/dart.
Mast cells play an important role in allergic responses. During activation, these cells undergo degranulation, a process by which various kinds of mediators stored in the granules are released. Granule homeostasis in mast cells has mainly been studied by electron microscopy (EM), where the fine structures of subcellular organelles are partially destroyed during sample preparation. Migration and fusion of granules have not been studied in detail in three dimensions (3D) in unmodified samples. Here, we utilized soft X-ray tomography (SXT) coupled with fluorescence microscopy to study the detailed structures of organelles during mast cell activation. We observed granule fission, granule fusion to plasma membranes, and small vesicles budding from granules. We also detected lipid droplets, which became larger and more numerous as mast cells were activated. We observed dramatic morphological changes of mitochondria in activated mast cells and 3D-reconstruction revealed the highly folded cristae inner membrane, features of functionally active mitochondria. We also observed giant vesicles containing granules, mitochondria, and lipid droplets, which we designated as granule-containing vesicles (GCVs) and verified their presence by EM in samples prepared by cryo-substitution, albeit with a less clear morphology. Thus, our studies using SXT provide significant insights into mast cell activation at the organelle level.
This study reports a new microfluidic cell culture platform for real-time, in vitro microscopic observation and evaluation of cellular functions. Microheaters, a micro temperature sensor, and micropumps are integrated into the system to achieve a self-contained, perfusion-based, cell culture microenvironment. The key feature of the platform includes a unique, ultra-thin, culture chamber with a depth of 180 mum, allowing for real-time, high-resolution cellular imaging by combining bright field and fluorescent optics to visualize nanoparticle-cell/organelle interactions. The cell plating, culturing, harvesting and replenishing processes are performed automatically. The developed platform also enables drug screening and real-time, in situ investigation of the cellular and sub-cellular delivery process of nano vectors. The mitotic activity and the interaction between cells and the nano drug carriers (conjugated quantum dots-epirubicin) are successfully monitored in this device. This developed system could be a promising platform for a wide variety of applications such as high-throughput, cell-based studies and as a diagnostic cellular imaging system.
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