Chryseobacterium indologenes Peritonitis in a Peritoneal Dialysis Patient: A Case Report and Review of Literature

Peritonitis is one of the most important complications in patients with peritoneal dialysis (PD). Appropriate antibiotic treatment against PD-associated peritonitis is necessary to prevent PD catheter removal and withdrawal from PD. Chryseobacterium indologenes is a Gram-negative rod that occurs in the natural environment. C. indologenes is thought to acquire resistance to β-lactam drugs through the production of metallo-β-lactamase and to become resistant to antibiotic therapy through the formation of biofilms. Only a few cases of PD-associated peritonitis caused by C. indologenes have been reported to date, and appropriate treatment strategies have not been clarified. In the past, 5 cases of PD-associated peritonitis caused by C. indologenes have been reported and 2 patients required catheter removal because of recurrence or refractoriness. In this case, a 51-year-old man with PD-associated peritonitis caused by C. indologenes was treated with 2 susceptible antibiotics, including fluoroquinolones to prevent acquired resistance and biofilm formation. There was no recurrence, and catheter removal was not necessary in this case. Collectively, the present case highlighted that PD-associated peritonitis caused by C. indologenes should be treated with 2 susceptible antibiotics including fluoroquinolones for 3 weeks

Small-angle X-ray diffraction studies of a molluscan smooth muscle in the catch state

Small-angle X-ray diffraction patterns from the anterior byssus retractor muscle of Mytilus edulis in the resting, active, and catch states were examined closely to elucidate the structural features of catch. The specimens were isometrically contracted by stimulation with acetylcholine. The specimens that produced strong tensions in both the active and catch states showed noticeable structural change in the thick filaments. Although the tension was weaker in the catch state than in the active state, the axial spacings of the 14.5 nm meridional reflection and its higher order reflections from the thick filaments were more elongated in the catch state than in the active state. This means that the thick filaments were stretched more strongly in the catch state than in the active state

All-Optical Wide-Field Selective Imaging of Fluorescent Nanodiamonds in Cells, In Vivo and Ex Vivo

Fluorescence imaging is a critical tool to understand the spatial distribution of biomacromolecules in cells and in vivo, providing information on molecular dynamics and interactions. Numerous valuable insights into biological systems have been provided by the specific detection of various molecular species. However, molecule-selective detection is often hampered by background fluorescence, such as cell autofluorescence and fluorescence leakage from molecules stained by other dyes. Here we describe a method for all-optical selective imaging of fluorescent nanodiamonds containing nitrogen-vacancy centers (NVCs) for wide-field fluorescence bioimaging. The method is based on the fact that the fluorescence intensity of NVCs strictly depends on the configuration of ground-state electron spins, which can be controlled by changing the pulse recurrence intervals of microsecond excitation laser pulses. Therefore, by using regulated laser pulses, we can oscillate the fluorescence from NVCs in a nanodiamond, while oscillating other optical signals in the opposite phase to NVCs. As a result, we can reconstruct a selective image of a nanodiamond by using a series of oscillated fluorescence images. We demonstrate application of the method to the selective imaging of nanodiamonds in live cells, in microanimals, and on a hippocampal slice culture obtained from a rat. Our approach potentially enables us to achieve high-contrast images of nanodiamond-labeled biomolecules with a signal-to-background ratio improved by up to 100-fold over the standard fluorescence image, thereby providing a more powerful tool for the investigation of molecular dynamics in cells and in vivo

Global 7-km mesh nonhydrostatic Model Intercomparison Project for improving TYphoon forecast (TYMIP-G7)

AAS06-P06 ポスター発表 / JpGU-AGU Joint Meeting 2017 (2017年5月20日～5月25日 幕張メッセ国際会議場