J
Jack A. Tuszynski
Researcher at University of Alberta
Publications - 556
Citations - 12142
Jack A. Tuszynski is an academic researcher from University of Alberta. The author has contributed to research in topics: Tubulin & Microtubule. The author has an hindex of 48, co-authored 516 publications receiving 10132 citations. Previous affiliations of Jack A. Tuszynski include Polytechnic University of Turin & National Institute of Standards and Technology.
Papers
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Journal ArticleDOI
Software for molecular docking: a review
TL;DR: Docking against homology-modeled targets also becomes possible for proteins whose structures are not known, and the druggability of the compounds and their specificity against a particular target can be calculated for further lead optimization processes.
Journal ArticleDOI
Quantum computation in brain microtubules: decoherence and biological feasibility.
TL;DR: In this article, the decoherence mechanisms likely to dominate in a biological setting were examined, and it was shown that a hybrid of the Penrose-Hameroff orchestrated objective reduction (orch. OR) model with a soliton in superposition along the microtubule can significantly increase the quantum coherence of microtubules.
Patent
Process for treating a biological organism
TL;DR: In this paper, a process for treating cells within a biological organism in which sonic energy is focused on cells within an organism while the frequency and/or the power level of such energy is varied is described.
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Three-Dimensional Molecular Theory of Solvation Coupled with Molecular Dynamics in Amber
Tyler Luchko,Sergey Gusarov,Daniel R. Roe,Carlos Simmerling,David A. Case,Jack A. Tuszynski,Andriy Kovalenko +6 more
TL;DR: The three-dimensional molecular theory of solvation coupled with molecular dynamics simulation by contracting solvent degrees of freedom, accelerated by extrapolating solvent-induced forces and applying them in large multi-time steps to enable simulation of large biomolecules is presented.
Journal ArticleDOI
Ferroelectric behavior in microtubule dipole lattices: Implications for information processing, signaling and assembly/disassembly
TL;DR: This paper considers microtubules as lattice arrays of coupled local dipole states that interact with their immediate neighbors that assume a ferroelectric phase with long-range order and alignment with capabilities to propagate kink-like excitations.