Teaching Enzyme Catalysis Using Interactive Molecular Dynamics in Virtual Reality

The reemergence of virtual reality (VR) in the past few years has led to affordable, high-quality commodity hardware that can offer new ways to teach, communicate, and engage with complex concepts. In a higher-education context, these immersive technologies make it possible to teach complex molecula...

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Veröffentlicht in:	Journal of chemical education 2019-11, Vol.96 (11), p.2488-2496
Hauptverfasser:	Bennie, Simon J, Ranaghan, Kara E, Deeks, Helen, Goldsmith, Heather E, O’Connor, Michael B, Mulholland, Adrian J, Glowacki, David R
Format:	Artikel
Sprache:	eng
Schlagworte:	Biochemistry Catalysis College students Computation Computational chemistry Computer Simulation Density functional theory Education Educational Objectives Enzymes Foreign Countries Learner Engagement Mechanics (physics) Molecular Biology Molecular dynamics Organic chemistry Outcomes of Education Preferences Real time Science education Science Instruction Student Attitudes Student Surveys Students Teaching Methods Time Undergraduate Students Virtual reality
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creator	Bennie, Simon J Ranaghan, Kara E Deeks, Helen Goldsmith, Heather E O’Connor, Michael B Mulholland, Adrian J Glowacki, David R
description	The reemergence of virtual reality (VR) in the past few years has led to affordable, high-quality commodity hardware that can offer new ways to teach, communicate, and engage with complex concepts. In a higher-education context, these immersive technologies make it possible to teach complex molecular topics in a way that may aid or even supersede traditional approaches such as molecular models, textbook images, and traditional screen-based computational environments. In this work we describe a study involving 22 third-year UK undergraduate chemistry students who undertook a traditional computational chemistry class complemented by an additional component which we designed to utilize real-time interactive molecular dynamics simulations in VR (iMD-VR). Exploiting the flexibility of an open-source iMD-VR framework which we recently described, the students were given three short tasks to complete in iMD-VR: (1) interactive rearrangement of the chorismate molecule to prephenate using forces obtained from density functional theory calculations; (2) unbinding of chorismate from the active site chorismate mutase enzyme using molecular mechanics forces calculated in real-time; and (3) docking of chorismate with chorismate mutase using real-time molecular mechanics forces. A student survey indicated that most students found the iMD-VR component more engaging than the traditional approach, and also that it improved their perceived educational outcomes and their interest in continuing on in the field of computational sciences.
doi_str_mv	10.1021/acs.jchemed.9b00181
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subjects	Biochemistry Catalysis College students Computation Computational chemistry Computer Simulation Density functional theory Education Educational Objectives Enzymes Foreign Countries Learner Engagement Mechanics (physics) Molecular Biology Molecular dynamics Organic chemistry Outcomes of Education Preferences Real time Science education Science Instruction Student Attitudes Student Surveys Students Teaching Methods Time Undergraduate Students Virtual reality
title	Teaching Enzyme Catalysis Using Interactive Molecular Dynamics in Virtual Reality
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