For renewable energy sources such as solar, wind, and hydroelectric to be effectively used in the grid of the future, flexible and scalable energy-storage solutions are necessary to mitigate output fluctuations. Redox-flow batteries (RFBs) were first built in the 1940s and are considered a promising large-scale energy-storage technology. A limited number of redox-active materials--mainly metal salts, corrosive halogens, and low-molar-mass organic compounds--have been investigated as active materials, and only a few membrane materials, such as Nafion, have been considered for RFBs. However, for systems that are intended for both domestic and large-scale use, safety and cost must be taken into account as well as energy density and capacity, particularly regarding long-term access to metal resources, which places limits on the lithium-ion-based and vanadium-based RFB development. Here we describe an affordable, safe, and scalable battery system, which uses organic polymers as the charge-storage material in combination with inexpensive dialysis membranes, which separate the anode and the cathode by the retention of the non-metallic, active (macro-molecular) species, and an aqueous sodium chloride solution as the electrolyte. This water- and polymer-based RFB has an energy density of 10 watt hours per litre, current densities of up to 100 milliamperes per square centimetre, and stable long-term cycling capability. The polymer-based RFB we present uses an environmentally benign sodium chloride solution and cheap, commercially available filter membranes instead of highly corrosive acid electrolytes and expensive membrane materials.
Electricity users expect energy on demand. This poses a problem for renewables, such as solar, wind or hydroelectric, as the supply is naturally intermittent. Building scalable and inexpensive energy storage is the answer, and here we describe a new rechargeable battery system that uses salt solutions of organic polymers and a cheap filter membrane.
The presence of sugar receptors on human myeloid leukemia cells was comparatively assessed by a highly sensitive binding assay, employing a panel of 14 types of neoglycoenzymes (chemically glycosylated Escherichia coli beta-galactosidase). The selected carbohydrate ligands mainly encompass common components of natural glycoconjugates as mono- or disaccharides. The monocytoid cells of the THP-1 line, the very young myeloblasts and the myeloblasts of the lines KG-1a and KG-1, the promyelocytes of the HL-60 line, and the early myeloblasts/erythroblasts of the K-562 line displayed a nonuniform pattern of specific binding with quantitative differences at a fixed, nonsaturating concentration of the probes. Scatchard analysis in four cases corroborated the indication of cell-type-related differences between the various cell lines. To test whether the detectable cellular sugar-binding sites can mediate adhesion to glycoligands, a rather simple model matrix of nitrocellulose-immobilized neoglycoproteins was first used. In comparison to the carbohydrate-free carrier protein significant cell adhesion was observed primarily with neoglycoproteins that exposed galactose, N-acetylgalactosamine, N-acetylglucosamine, mannose, and fucose moieties among the 11 tested types of carbohydrate residue. Subsequently, human bone marrow stromal cell layers were tested as a model matrix with increased levels of physiological relevance and complexity. Mixtures of carbohydrate and neoglycoprotein were employed as inhibitors of an interaction via lectins between the stromal and the tumor cells. The carbohydrate-dependent alterations of this parameter revealed cell-type-associated properties. Tumor cell binding was significantly decreased for not more than two lines with the effective sugars, namely N-acetylgalactosamine, mannose, fucose, and sialic acid.
Cell-surface sugar receptors may participate in interactions of lymphoid cells that influence their adhesive properties and proliferation. Their expression on cells of the pre-B line BLIN-I, the B-lymphoblastoid line Croco II, the myeloma line RPMI 8226 and the T-lymphoblastoid line CCRF-CEM was monitored with a panel of 14 types of chemically glycosylated E. coli beta-galactosidase at a non-saturating ligand concentration. Quantitative differences were determined for the capacity of the different cell types to bind constituents of the carbohydrate part of glycoconjugates. They were corroborated by analyses of binding for lactose-, beta-N-acetylgalactosamine-, beta-N-acetylglucosamine- and fucose-exposing neoglycoenzymes up to saturation levels. Values of dissociation constants of the tetrameric enzyme were in the range of 3-300 nM. Several types of sugar receptor led to carbohydrate-inhibitable adhesion of cells to 6 types of nitrocellulose-immobilized neoglycoprotein, their effectiveness being most obvious for the myeloma cells. Analyses of the carbohydrate-ligand-mediated adhesion of the other cell types revealed a comparatively decreased response. Only a few carbohydrates among the 7 types tested were effective in reducing cell adhesion to a far more complex ligand-bearing matrix than immobilized neoglycoproteins, namely bone-marrow stromal cell layers: sialic acid and N-acetylgalactosamine for B-lymphoblastoid cells and rhamnose for pre-B cells. These cellular interactions may encompass sugar receptors on the stromal cells and other types of molecular recognition in addition to the detected activities on the lymphoid cells.
Setzt man das Tetrazin (I) mit dem Dihydrothiepin‐S,S‐dioxid (II) um, so entsteht ein Gemisch der Verbindungen (III) und (IV), die durch (4+2)‐Cycloaddition an (II) bzw. an das aus (II) durch SOQ‐Eliminierung entstehende Hexatrien gebildet 27 werden.
Wie wir kurzlich zeigen konnten, besitzen die Heterotropilidene Oxepin2) und N-Ethoxycarbonyl-azepin3) gegenuber dem in 3,6-Dimethoxycarbonyl-tetrazin (1) fixierten s-cis-Azinsystem eine ausgepragte Dienophil-Reaktivitat. Im Thiepin-1,l-dioxid (2)4) sind dagegen die n-Bindungen nicht ausreichend aktiviert fur eine ,,inverse" [4+2]-Cycloaddition. Beim Erhitzen von 1 mit 2 in siedendem Chlorbenzol erfolgt vielmehr Fragmentierung von 2 in Schwefeldioxid und Benzol, eine Reaktion mit 1 findet nicht statt').
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