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Better diet and glucose uptake in the brain lead to longer life in fruit flies


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IMAGE: Glucose uptake in brain neurons decreases with age (left), Increasing glucose uptake in brain neurons counteracts aging (middle), Increasing glucose uptake in brain neurons plus dietary restriction further extends lifespan.
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Credit: Tokyo Metropolitan University
Tokyo, Japan - Researchers from Tokyo Metropolitan University have discovered that fruit flies with genetic modifications to enhance glucose uptake have significantly longer lifespans. Looking at the brain cells of aging flies, they found that better glucose uptake compensates for age-related deterioration in motor functions, and led to longer life. The effect was more pronounced when coupled with dietary restrictions. This suggests healthier eating plus improved glucose uptake in the brain might lead to enhanced lifespans. ....

Kanae Ando , National Center , Research Fellows , Research Funding For Longevity Science , Scientific Research On Challenging Exploratory , Tokyo Metropolitan University , Japan Foundation For , Associate Professor Kanae Ando , Japan Foundation , Scientific Research , Challenging Research , Research Funding , Longevity Science , Cell Biology , Nutrition Nutrients , Mortality Longevity , தேசிய மையம் , ஆராய்ச்சி கூட்டாளிகள் , ஆராய்ச்சி நிதி க்கு நீண்ட ஆயுள் அறிவியல் , அறிவியல் ஆராய்ச்சி ஆன் சவாலானது ஆய்வு , டோக்கியோ பெருநகர பல்கலைக்கழகம் , ஜப்பான் அடித்தளம் க்கு , ஜப்பான் அடித்தளம் , அறிவியல் ஆராய்ச்சி , சவாலானது ஆராய்ச்சி , ஆராய்ச்சி நிதி ,

Researchers use Chemical Vapor Deposition to Create Self-Assembled Nanowires


Researchers use Chemical Vapor Deposition to Create Self-Assembled Nanowires
Researchers from Tokyo Metropolitan University have discovered a way to make self-assembled nanowires of transition metal chalcogenides
at scale using chemical vapor deposition.
By changing the substrate where the wires form, they can tune how these wires are arranged, from aligned configurations of atomically thin sheets to random networks of bundles. This paves the way to industrial deployment in next-gen industrial electronics, including energy harvesting, and transparent, efficient, even flexible devices.
Electronics is all about making things smaller. Smaller features on a chip, for example, means more computing power in the same amount of space and better efficiency, essential to feeding the increasingly heavy demands of a modern IT infrastructure powered by machine learning and artificial intelligence. And as devices get smaller, the same demands are made of the intricate wiring t ....

Nano Lett , Yasumitsu Miyata , Scientific Research On Innovative Areas , Scientific Research , Japan Society For The Promotion Of Science , Challenging Research Exploratory , Murata Science Foundation , Tokyo Metropolitan University , Japan Keirin Autorace Foundation , Hong En Lim , Associate Professor Yasumitsu Miyata , Scale Growth , One Dimensional Transition Metal Telluride , Japan Society , Young Scientists , Innovative Areas , Specially Promoted Research , Challenging Research , Processing Facility , Grant Number , நானோ லெட் , அறிவியல் ஆராய்ச்சி ஆன் புதுமையானது பகுதிகள் , அறிவியல் ஆராய்ச்சி , ஜப்பான் சமூகம் க்கு தி ப்ரமோஶந் ஆஃப் அறிவியல் , சவாலானது ஆராய்ச்சி ஆய்வு , முரட்டா அறிவியல் அடித்தளம் ,

Atomic-scale nanowires can now be produced at scale


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IMAGE: (a) Illustration of a TMC nanowire (b) Chemical vapor deposition. The ingredients are vaporized in a hydrogen/nitrogen atmosphere and allowed to deposit and self-assemble on a substrate. Reprinted with permission.
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Credit: Copyright 2020 American Chemical Society (ACS)
Tokyo, Japan - Researchers from Tokyo Metropolitan University have discovered a way to make self-assembled nanowires of transition metal chalcogenides
at scale using chemical vapor deposition. By changing the substrate where the wires form, they can tune how these wires are arranged, from aligned configurations of atomically thin sheets to random networks of bundles. This paves the way to industrial deployment in next-gen industrial electronics, including energy harvesting, and transparent, efficient, even flexible devices. ....

Nano Lett , Yasumitsu Miyata , Scientific Research On Innovative Areas , Scientific Research , Japan Society For The Promotion Of Science , Challenging Research Exploratory , Murata Science Foundation , Tokyo Metropolitan University , Japan Keirin Autorace Foundation , Hong En Lim , Associate Professor Yasumitsu Miyata , Scale Growth , One Dimensional Transition Metal Telluride , Japan Society , Young Scientists , Innovative Areas , Specially Promoted Research , Challenging Research , Processing Facility , Grant Number , Chemistry Physics Materials Sciences , Industrial Engineering Chemistry , Technology Engineering Computer Science , Electrical Engineering Electronics , Nanotechnology Micromachines , Atomic Physics ,