17 research outputs found
A Cluster of Respiratory Syncytial Virus Infections in a Hospital Ward for Adult Immunocompromised Patients
Four male patients admitted to the same ward in the first half of September 201Y were identified to have respiratory syncytial virus(RSV)infection. Their ages ranged from 49 to 85 years(median 72.5). One patient was infected with human immunodeficiency virus and three patients had hematological malignancies. Following immuno-chromatological testing with a nasal cavity swab, RSV infection was diagnosed. Although blood and sputum cultures were performed in three patients, no significant bacteria were detected. Two cases responded to supportive therapy. However, one patient died secondary to multiple myeloma, and another patient developed pneumonia and died with an exacerbation of leukemia. RSV infections in immunocompromised hosts are associated with a poor prognosis. Early diagnosis will facilitate isolation of infected individuals to prevent hospital outbreaks
Molecular and Crystal Structure of a Chitosan−Zinc Chloride Complex
We determined the molecular and packing structure of a chitosan–ZnCl2 complex by X-ray diffraction and linked-atom least-squares. Eight D-glucosamine residues—composed of four chitosan chains with two-fold helical symmetry, and four ZnCl2 molecules—were packed in a rectangular unit cell with dimensions a = 1.1677 nm, b = 1.7991 nm, and c = 1.0307 nm (where c is the fiber axis). We performed exhaustive structure searches by examining all of the possible chain packing modes. We also comprehensively searched the positions and spatial orientations of the ZnCl2 molecules. Chitosan chains of antiparallel polarity formed zigzag-shaped chain sheets, where N2···O6, N2···N2, and O6···O6 intermolecular hydrogen bonds connected the neighboring chains. We further refined the packing positions of the ZnCl2 molecules by theoretical calculations of the crystal models, which suggested a possible coordination scheme of Zn(II) with an O6 atom
DFT Optimization of Isolated Molecular Chain Sheet Models Constituting Native Cellulose Crystal Structures
Because
of high crystallinity and natural abundance, the crystal
structures of the native cellulose allomorphs have been theoretically
investigated to elucidate the cellulose chain packing schemes. Here,
we report systematic structure optimization of cellulose chain sheet
models isolated from the cellulose Iα and Iβ crystals
by density functional theory (DFT). For each allomorph, the three-dimensional
chain packing structure was partitioned along each of the three main
crystal planes to construct either a flat chain sheet model or two
stacked chain sheet models, each consisting of four cello-octamers.
Various combinations of the basis set and DFT functional were investigated.
The flat chain sheet models constituting the cellulose Iα (110)
and Iβ (100) planes, where the cellulose chains are mainly linked
by intermolecular hydrogen bonds, exhibit a right-handed twist. More
uniform and symmetrical sheet twists are observed when the flat chain
sheet models are optimized using a basis set with diffuse functions
(6-31+G(d,p)). The intermolecular interactions are more stable when
the chain sheet models are optimized with the two hybrid functionals
CAM-B3LYP and M06-2X. Optimization of the two stacked chain sheet
models, where van der Waals interactions predominated between adjacent
chains, gave differing results; those retaining the initial structures
and those losing the sheet appearance, corresponding to the cellulose
Iα/Iβ (010)/(11̅0) and (100)/(110) chain sheet models,
respectively. The cellulose Iβ (11̅0) chain sheet model
is more stable using the M06-2X functional than using the CAM-B3LYP
functional
DFT Optimization of Isolated Molecular Chain Sheet Models Constituting Native Cellulose Crystal Structures
Because
of high crystallinity and natural abundance, the crystal
structures of the native cellulose allomorphs have been theoretically
investigated to elucidate the cellulose chain packing schemes. Here,
we report systematic structure optimization of cellulose chain sheet
models isolated from the cellulose Iα and Iβ crystals
by density functional theory (DFT). For each allomorph, the three-dimensional
chain packing structure was partitioned along each of the three main
crystal planes to construct either a flat chain sheet model or two
stacked chain sheet models, each consisting of four cello-octamers.
Various combinations of the basis set and DFT functional were investigated.
The flat chain sheet models constituting the cellulose Iα (110)
and Iβ (100) planes, where the cellulose chains are mainly linked
by intermolecular hydrogen bonds, exhibit a right-handed twist. More
uniform and symmetrical sheet twists are observed when the flat chain
sheet models are optimized using a basis set with diffuse functions
(6-31+G(d,p)). The intermolecular interactions are more stable when
the chain sheet models are optimized with the two hybrid functionals
CAM-B3LYP and M06-2X. Optimization of the two stacked chain sheet
models, where van der Waals interactions predominated between adjacent
chains, gave differing results; those retaining the initial structures
and those losing the sheet appearance, corresponding to the cellulose
Iα/Iβ (010)/(11̅0) and (100)/(110) chain sheet models,
respectively. The cellulose Iβ (11̅0) chain sheet model
is more stable using the M06-2X functional than using the CAM-B3LYP
functional
DFT Optimization of Isolated Molecular Chain Sheet Models Constituting Native Cellulose Crystal Structures
Because
of high crystallinity and natural abundance, the crystal
structures of the native cellulose allomorphs have been theoretically
investigated to elucidate the cellulose chain packing schemes. Here,
we report systematic structure optimization of cellulose chain sheet
models isolated from the cellulose Iα and Iβ crystals
by density functional theory (DFT). For each allomorph, the three-dimensional
chain packing structure was partitioned along each of the three main
crystal planes to construct either a flat chain sheet model or two
stacked chain sheet models, each consisting of four cello-octamers.
Various combinations of the basis set and DFT functional were investigated.
The flat chain sheet models constituting the cellulose Iα (110)
and Iβ (100) planes, where the cellulose chains are mainly linked
by intermolecular hydrogen bonds, exhibit a right-handed twist. More
uniform and symmetrical sheet twists are observed when the flat chain
sheet models are optimized using a basis set with diffuse functions
(6-31+G(d,p)). The intermolecular interactions are more stable when
the chain sheet models are optimized with the two hybrid functionals
CAM-B3LYP and M06-2X. Optimization of the two stacked chain sheet
models, where van der Waals interactions predominated between adjacent
chains, gave differing results; those retaining the initial structures
and those losing the sheet appearance, corresponding to the cellulose
Iα/Iβ (010)/(11̅0) and (100)/(110) chain sheet models,
respectively. The cellulose Iβ (11̅0) chain sheet model
is more stable using the M06-2X functional than using the CAM-B3LYP
functional
Theoretical Study of the Structural Stability of Molecular Chain Sheet Models of Cellulose Crystal Allomorphs
The
structural stabilities of the molecular chain sheets constituting
the crystal structures of the cellulose allomorphs Iα, Iβ,
II, and III<sub>I</sub> were investigated by density functional theory
(DFT) optimization of the isolated chain sheet models with finite
dimensions. The DFT-optimized chain sheet models of the two native
cellulose crystals developed a right-handed twist with a similar amount
of twisting. The DFT-optimized cellulose II (010) and (020) models
twisted in opposite directions with right- and left-handed chirality,
respectively. The cellulose III<sub>I</sub> (1–10) model retained
the initial flat structure after the DFT-optimization. The structural
features of the DFT-optimized chain sheet models were reflected in
the structures of the parent crystal models observed in solvated molecular
dynamics (MD) simulations. The minor conformations of the hydroxymethyl
groups proposed in the real crystal structures were detected in the
MD crystal models and the DFT-optimized (010) model of cellulose II.
The crystal chain packing and crystal conversions are interpreted
in terms of principal chain sheet stacking
Cell-compatible isotonic freezing media enabled by thermo-responsive osmolyte-adsorption/exclusion polymer matrices
Abstract During the long-term storage of cells, it is necessary to inhibit ice crystal formation by adding cryoprotectants. Non-cell-permeable cryoprotectants have high osmotic pressure which dehydrates cells, indirectly suppressing intracellular ice crystal formation. However, the high osmotic pressure and dehydration often damage cells. Emerging polymer-type non-cell-permeable cryoprotectants form matrices surrounding cells. These matrices inhibit the influx of extracellular ice nuclei that trigger intracellular ice crystal formation. However, these polymer-type cryoprotectants also require high osmotic pressure to exert an effective cryoprotecting effect. In this study, we designed a poly(zwitterion) (polyZI) that forms firm matrices around cells based on their high affinity to cell membranes. The polyZI successfully cryopreserved freeze-vulnerable cells under isotonic conditions. These matrices also controlled osmotic pressure by adsorbing and desorbing NaCl depending on the temperature, which is a suitable feature for isotonic cryopreservation. Although cell proliferation was delayed by the cellular matrices, washing with a sucrose solution improved proliferation