Mechanism for Local-Atomic Structure Changes in Chalcogenide-based Threshold-Switching Devices.

Threshold-switching devices based on amorphous chalcogenides are considered for use as selector devices in 3D crossbar memories. However, the fundamental understanding of amorphous chalcogenide is hindered owing to the complexity of the local structures and difficulties in the trap analysis of multinary compounds. Furthermore, after threshold switching, the local structures gradually evolve to more stable energy states owing to the unstable homopolar bonds. Herein, based on trap analysis, DFT simulations, and operando XPS analysis, it is determined that the threshold switching mechanism is deeply related to the charged state of Se-Se homopolar defects. A threshold switching device is demonstrated with an excellent performance through the modification of the local structure via the addition of alloying elements and investigating the time-dependent trap evolution. The results concerning the trap dynamics of local atomic structures in threshold switching phenomena may be used to improve the design of amorphous chalcogenides.

Generation of a High-Growth Influenza Vaccine Strain in MDCK Cells for Vaccine Preparedness.

As shown during the 2009 pandemic H1N1 (A(H1N1)pdm09) outbreak, egg-based influenza vaccine production technology is insufficient to meet global demands during an influenza pandemic. Therefore, there is a need to adapt cell culture-derived vaccine technology using suspended cell lines for more rapid and larger-scale vaccine production. In this study, we attempted to generate a high-growth influenza vaccine strain in MDCK cells using an A/Puerto/8/1934 (H1N1) vaccine seed strain. Following 48 serial passages with four rounds of virus plaque purification in MDCK cells, we were able to select several MDCK-adapted plaques that could grow over 108 PFU/ml. Genetic characterization revealed that these viruses mainly had amino acid substitutions in internal genes and exhibited higher polymerase activities. By using a series of Rg viruses, we demonstrated the essential residues of each gene and identified a set of high-growth strains in MDCK cells (PB1D153N, M1A137T, and NS1N176S). In addition, we confirmed that in the context of the high-growth A/PR/8/34 backbone, A/California/7/2009 (H1N1), A/Perth/16/2009 (H3N2), and A/environment/Korea/deltaW150/2006 (H5N1) also showed significantly enhanced growth properties (more than 107 PFU/ml) in both attached- and suspended-MDCK cells compared with each representative virus and the original PR8 vaccine strain. Taken together, this study demonstrates the feasibility of a cell culture-derived approach to produce seed viruses for influenza vaccines that are cheap and can be grown promptly and vigorously as a substitute for egg-based vaccines. Thus, our results suggest that MDCK cell-based vaccine production is a feasible option for producing large-scale vaccines in case of pandemic outbreaks.

Characterization of the carbohydrate binding and ADP-ribosyltransferase activities of chemically detoxified pertussis toxins.

Pertussis toxin (PTx) is an essential component of the acellular pertussis (aP) vaccine. However, because PTx in its native form is considered too toxic for human vaccine use, it must be inactivated into a stable, nontoxic form by treatment with chemical detoxifying agents or by genetic modification. Therefore, testing for the residual PTx in the aP vaccine is a major quality control step for vaccine manufacturers and regulatory authorities. The histamine sensitization test is currently the standard safety test method for all aP vaccines, regardless of the vaccine formula or the detoxification process, except for those with genetically modified PTx. However, test result variability and ethical concerns regarding animal use necessitate an alternative method. In vitro assays based on the biochemical properties of PTx have been considered as potential alternatives to the histamine sensitization test. In this study, the suitability of assays based on the ADP-ribosyltransferase and carbohydrate binding activities of PTx was assessed for PTx after treatment with formaldehyde, glutaraldehyde or both denaturants in sequence. The results indicated a distinctive pattern of the biochemical activities depending on the detoxification methods and storage conditions. These results suggest that although a more careful study is needed, these in vitro biochemical assays can be considered potential alternatives to the histamine sensitization test, as they might provide more specific safety information of aP vaccines.