Hung Cuong Pham scite author profile

Argyrophilic grain disease constitutes one cause of late-onset dementia. Its classification among dementia disorders is still unclear because most of the reported argyrophilic grain disease cases are associated with neurofibrillary lesions (e.g. neurofibrillary tangles) which are also typical of Alzheimer's disease. In the present study we determine whether argyrophilic grain disease is associated with the senile plaques of Alzheimer's disease. The distribution and density of senile plaques was systematically investigated in 11 demented argyrophilic grain disease cases using Abeta immunohistochemistry and stereological techniques, and the results were compared with 11 Alzheimer's disease cases. All subjects with argyrophilic grain disease exhibited neurofibrillary changes corresponding to Braak stages I-III. Three of the 11 argyrophilic grain disease cases (27%) were completely devoid of Abeta deposits. In argyrophilic grain disease cases with senile plaques, the average total plaque-load was significantly lower (1%) than in Alzheimer's disease (3.1%) (P<0. 005). The regional distribution of the senile plaques and the proportion of diffuse vs. primitive or mature plaques in argyrophilic grain disease resembled values of senile plaques reported in non-demented elderly subjects, and was significantly different from Alzheimer's disease. Similarly the immunocytochemical profile of the Abeta deposition in argyrophilic grain disease resembled that of non-demented elderly subjects rather than that of subjects with Alzheimer's disease. As all argyrophilic grain disease cases under investigation were demented, including those devoid of senile plaques, the present study further supports the thesis that dementia in argyrophilic grain disease correlates more with the density and distribution of argyrophilic grains than with associated lesions of the Alzheimer-type.

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Modification of Surface Oxide Layer of Fe‐Cr‐Al Alloy with Coating Materials for SOFC Applications

Pham

Taniguchi

Inoue

et al. 2017

Fuel Cells

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We investigated the treatment of Fe‐Cr‐Al alloy for application in solid oxide fuel cells (SOFCs). The electrical resistance of the Al2O3‐based surface oxide layer on the alloy decreased and was stable when La0.6Sr0.4Co0.2Fe0.8O3 (LSCF), La0.8Sr0.2MnO3 (LSM), LaNi0.6Fe0.4O3 (LNF), or Pr0.8Sr0.2MnO3 (PrSM) were first coated on the alloy and heat treated at 700 °C in air. The activation energy, calculated from the resistance, also suggested that the surface oxide became more conductive with treatment. The surface oxide layer after treatment had a microstructure of columns growing outward in the same direction, containing small amounts of elements such as Sr, Ni, Fe, La, Mn, and Pr. The microstructure consists of polycrystalline γ‐Al2O3 and small amounts of Al compounds with these elements. In the case of the LNF coating, the formation of NiAl2O4 was observed. The enhanced electrical conductivity may have resulted from the arrangement of the columnar structure, along with the electronic conduction path generated by the reaction of γ‐Al2O3 with these elements.

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Hung Cuong Pham

Spray deposition of Nafion membranes: Electrode-supported fuel cells

NO and SO2 removal in non-thermal plasma reactor packed with glass beads-TiO2 thin film coated by PCVD process

Decrease in electrical resistance of surface oxide of iron–chromium–aluminium alloy by La0.6Sr0.4Co0.2Fe0.8O3 coating and heat treatment for the application of metal-supported solid oxide fuel cells

Low amyloid (Aβ) plaque load and relative predominance of diffuse plaques distinguish argyrophilic grain disease from Alzheimer’s disease

Modification of Surface Oxide Layer of Fe‐Cr‐Al Alloy with Coating Materials for SOFC Applications

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