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Integration analysis of m6A regulators and m6A-related genes in hepatocellular carcinoma

Announcing a new article publication for BIO Integration journal. In this article the authors Jingdun Xie, Zhenhua Qi, Xiaolin Luo, Fang Yan, Wei Xing, Weian Zeng, Dongtai Chen and Qiang Li; from Sun Yat-sen University, Guangzhou, Guangdong, China discuss integration analysis of m6A regulators and m6A-related genes in hepatocellular carcinoma (HCC). N6-Methyladenosine (m6A) RNA methylation of eukaryotic mRNA is involved in the progression of various tumors. This study comprehensively analyzed m6A regulators and m6A-related genes through an integrated bioinformatic analysis, including expression, clustering, protein-protein interaction, and prognosis, thus providing novel insights into the roles of m6A regulators and m6A-related genes in HCC.

Qiang liWei xingDongtai chenFang yanZhenhua qiXiaolin luoJingdun xieWeian zengSun yat sen universityIntegration analysisRelated genesMedicine healthகியாங் லிவெய் க்ஷிங்ஃப்யாஂக் யான்சூரியன் யத் சென் பல்கலைக்கழகம்

Assessing patients kidney health may help predict their risk of cardiovascular disease

Assessing patients kidney health may help predict their risk of cardiovascular disease
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United statesTao yangQiang liChao liuDi zhangGang chenXyu xuJieli luGuixia wangZuojie luoQing suMeng daiMian liLixin shiYuhong chenZhengnan gao

Light-Induced Lattice Twisting can Photogenerate Giant Electric Current

Light-Induced Lattice Twisting can Photogenerate Giant Electric Current Written by AZoOpticsJan 20 2021 Scientists at the U.S. Department of Energy s Ames Laboratory and collaborators at Brookhaven National Laboratory and the University of Alabama at Birmingham have discovered a new light-induced switch that twists the crystal lattice of the material, switching on a giant electron current that appears to be nearly dissipationless. The discovery was made in a category of topological materials that holds great promise for spintronics, topological effect transistors, and quantum computing. Weyl and Dirac semimetals can host exotic, nearly dissipationless, electron conduction properties that take advantage of the unique state in the crystal lattice and electronic structure of the material that protects the electrons from doing so.

United statesQiang liLiang luoIlias perakisJigang wangEnergy frontier research centerUs department of energy ames laboratoryAmes laboratoryBrookhaven national laboratory advanced energy materials groupIowa state universityUniversity of alabama at birminghamUs department of energyOffice of scienceBrookhaven national laboratoryIowa stateAdvanced energy materials

Nearly Dissipationless Current Achieved Through Light-Induced Switch | Research & Technology | Jan 2021

Nearly Dissipationless Current Achieved Through Light-Induced Switch | Research & Technology | Jan 2021
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Iowa state universityUnited statesQiang liLiang luoIlias perakisJigang wangUs department of energy ames laboratoryCourtesy of ames laboratoryAmes laboratoryBrookhaven national laboratory advanced energy materials groupUniversity of alabama at birminghamUs department of energyBrookhaven national laboratoryIowa stateAdvanced energy materials groupNature materials

Light-induced Twisting of Weyl Nodes Switches on Giant Electron Current

share: This news release, written by Laura Millsaps at Ames Laboratory, is being jointly issued by the U.S. Department of Energy’s Ames Laboratory and Brookhaven National Laboratory. Brookhaven Lab media contacts: Ariana Manglaviti, 631-344-2347, amanglaviti@bnl.gov or Peter Genzer, 631-344-3174, genzer@bnl.gov; Ames Lab media contact: Laura Millsaps, 515-294-3474, millsaps@ameslab.gov. Light-induced Twisting of Weyl Nodes Switches on Giant Electron Current January 18, 2021 Collaborating scientists at the U.S. Department of Energy s Ames Laboratory, Brookhaven Laboratory and the University of Alabama Birmingham used laser pulses to twist the crystal lattice of a Weyl semimetal, switching on a giant electron current that appears to be nearly dissipationless. The discovery and control of such properties brings these materials another step closer to use in applications such as quantum computing.

University of alabama at birminghamUnited statesQiang liPeter genzerAriana manglavitiLiang luoIlias perakisLaura millsapsJigang wangBrookhaven labUniversity of alabama birminghamEnergy frontier research centerUs department of energy ames laboratoryAmes laboratoryBrookhaven national laboratory advanced energy materials groupIowa state university