74 “Landscape of adenosine-to-inosine RNA recoding across human tissues”. Nature Communications, 2022. · Tomer Mann, Eli Eisenberg, Erez Levanon. “PO-675-08 AG RNA EDITING AS A MEDIATOR OF ATRIAL FIBRILLATION”. Heart Rhythm, 2022. · Nina Schneider, Yogapriya Sundaresan, Prakadeeswari Gopalakrishnan, Avigail Beryozkin, Mor Hanany, Erez Y Levanon, Eyal Banin, Shay Ben-Aroya2, Dror Sharon. “Inherited retinal diseases: Linking genes, disease-causing variants, and relevant therapeutic modalities”. Progress in Retinal and Eye Research, 101029, 2021. · Warhaftig Gal, Sokolik Chaya Mushka, Khermesh Khen, Lichtenstein Yehuda, Barak Michal, Bareli Tzofnat, Erez Y Levanon, Yadid Gal. “RNA editing of the 5-HT2C receptor in the central nucleus of the amygdala is involved in resilience behavior”. Translational Psychiatry, 2021. · Franz J Gassner, Nadja Zaborsky, Ilana Buchumenski, Erez Y Levanon, Matthias Gatterbauer, Maria Schubert, Stefanie Rauscher, Daniel Hebenstreit, Ferran Nadeu, Elias Campo, Alexander Egle, Richard Greil, Roland Geisberger. “RNA editing contributes to epitranscriptome diversity in chronic lymphocytic leukemia”. Leukemia, 2021. · Azgad Gold, Erez Y Levanon, Eli Eisenberg. “688 Plant to Insect Horizontal Gene Transfer: Empowering Whiteflies”. Genetics, 2021. · Roni Cohen-Fultheim, Erez Y Levanon. “Detection of A-to-I Hyper-edited RNA Sequences”. RNA Editing, 213-227, 2021. · Amos A Schaffer, Erez Y Levanon. “ALU A-to-I RNA Editing: Millions of sites and many open questions”. RNA Editing, 149162, 2021. · Ilana Buchumenski, Shalom Hillel Roth, Eli Kopel, Efrat Katsman, Ariel Feiglin, Erez Y Levanon, Eli Eisenberg. “Global quantification exposes abundant lowlevel off-target activity by base editors”. Genome Research, 2021. · Ilana Buchumenski, Karoline Holler, Lior Appelbaum, Eli Eisenberg, Jan Philipp Junker, Erez Y Levanon. “Systematic identification of A-to-I RNA editing in zebrafish development and adult organs”. Nucleic acids research, 2021. · Azgad Gold, Erez Y Levanon, Eli Eisenberg. “The New RNA-Editing Era–Ethical Considerations”. Trends in Genetics, 2021. · Anna Uzonyi, Ronit Nir, Ofir Shliefer, Noam Stern-Ginossar, Yaron Antebi, Yonatan Stelzer, Erez Y Levanon, Schraga Schwartz. “Deciphering the principles of the RNA editing code via large-scale systematic probing”. Molecular cell, 2021. Dr. Levy Amikam Department of Chemistry Member of BINA Photonics Center Quantum Center Research Areas Non-equilibrium quantum dynamics Abstract Progress in quantum technologies relies on understanding how quantum phenomena govern the dynamics of quantum systems far from equilibrium and on identifying the available quantum resources. This knowledge then allows us to manipulate the systems in order to obtain a desired outcome. Our group seeks to: (i) Develop dynamical descriptions that capture effects of quantum phenomena on the single-atom/molecule level and for systems far-from-equilibrium. (ii) Identify quantum resources and utilize them in controlling quantum transport processes and quantum state preparation. (iii) Thoroughly define the relationship between quantum effects and concepts from non-equilibrium thermodynamics. The negativity of the quasiprobabilities (shaded areas) and the violation of classical Inequality (yellow and green shaded area). Strong heat flows can only happen in the presence of negativities. Dr. Lewi Tomer Faculty of Engineering Member of BINA Nano & Advanced Materials Center Photonics Center Research Areas • Light-matter interactions • Nanophotonics • Metamaterials • Plasmonics • IR nanospectroscopy • 2D materials Abstract Nano-optics and Light–matter interactions in metamaterials Our group studies fundamental aspects of nano-optics and light-matter interactions in nanostructures, 2D quantum materials and nanophotonic platforms. We investigate exotic materials for manipulating optical processes from the single ‘meta-atom’ level to full metasurface arrays. We design and fabricate tunable 2D nanophotonic platforms that enable the control of fundamental light properties such as emission, absorption, directional scattering, polarization, lasing etc. Utilizing these investigations we ultimately strive to make novel integrated, active nanophotonic devices.
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