Two cases of liver cirrhosis caused by viral hepatitis : Observations on vascular stereograms of needle liver biopsy tissue

Two cases (Case I, 24-year old male, and Case II, 41-year old male) of liver cirrhosis after viral hepatitis have been described with a special emphasis on the distortion of the hepatic lobular architecture induced by hepatic hemodYnamic changes. Careful and precise clinical and laboratory examinations as well as peritoneoscopic examination with liver biopsy, particularly with vascular stereograms of liver biopsy tissue, have been successively carried outfrom stage of normal lobular architecture to early stage of cirrhosis. As the result, it has been found that in the course of these examinations clinical and laboratory features of the patients have remained almost unchanged in spite of gradual aggravation of morphological pictures. It is especially noteworthy that on vascular stereograms of liver biopsy tissue the parenchymal cells under the scarred portal tracts have suffered atrophic changes. Thus, three individual portal tracts of Case I have been gathered in a single connective tissue located on the distributing area of a scarred portal tract, whereas a central vein of Case II has moved from center to side of the scarred portal tract. In the late stage, these two cases ultimately turned to liver cirrhosis.</p

Long-Term CPU Load Prediction System for Scheduling of Distributed Processes and Its Implementation

The IEEE 22nd International Conference on Advanced Information Networking and Applications (AINA2008

Stacking order reduction in multilayer graphene by inserting nanospacers

Toward macroscopic applications of graphene, it is desirable to preserve the superior properties of single-layer graphene in bulk scale. However, the AB-stacking structure is thermodynamically favored for multilayer graphene and causes strong interlayer interactions, resulting in property degradation. A promising approach to prevent the strong interlayer interaction is the staking order reduction of graphene, where the graphene layers are rotated in-plane to form a randomly stacking structure. In this study, we propose a strategy to effectively decrease the stacking order of multilayer graphene by incorporating nanospacers, cellulose nanofibers, or nano-diamonds (NDs) in the formation process of porous graphene sponges. We conducted an ultrahigh temperature treatment at 1500 °C with ethanol vapor for the reduction and structural repair of graphene oxide sponges with different concentrations of the nanospacers. Raman spectroscopy indicated an obvious increase in the random-stacking fraction of graphene by adding the nanospacers. The x-ray diffraction (XRD) analysis revealed that a small amount of the nanospacers induced a remarkable decrease in ordered graphene crystalline size in the stacking direction. It was also confirmed that a layer-number increase during the thermal treatment was suppressed by the nanospacers. The increase in the random-stacking fraction is attributed to the efficient formation of randomly rotated graphene through the ethanol-mediated structural restoration of relatively thin layers induced by the nanospacers. This stacking-order-reduced graphene with bulk scale is expected to be used in macroscopic applications, such as electrode materials and wearable devices.Zizhao Xu, Taiki Inoue, Yuta Nishina, and Yoshihiro Kobayashi, "Stacking order reduction in multilayer graphene by inserting nanospacers", Journal of Applied Physics 132, 174305 (2022) https://doi.org/10.1063/5.010382

A procedure to determine the optimum imaging parameters for atomic/molecular resolution frequency modulation atomic force microscopy

We propose a general procedure to determine the optimum imaging parameters (spring constant and oscillation amplitude) to obtain the optimum resolution in frequency modulation atomic force microscopy. We calculated the effective signal-to-noise ratio for various spring constants and oscillation amplitudes, based on the measurement of frequency shift and energy dissipation versus tip-sample distance curves, to find the optimum. We applied this procedure for imaging a lead phthalocyanine (PbPc) thin film on a MoS2(0001) substrate, and found that the optimum parameters were about 5 N/m and 20 nm, respectively. An improved signal-to-noise ratio was attained in a preliminary experiment using parameters which were close to the calculated optimum