Your search keyword '"Deeks, Helen M."' showing total 6 results

1. Exploring human-guided strategies for reaction network exploration: Interactive molecular dynamics in virtual reality as a tool for citizen scientists.

Author

Shannon, Robin J., Deeks, Helen M., Burfoot, Eleanor, Clark, Edward, Jones, Alex J., Mulholland, Adrian J., and Glowacki, David R.

Subjects

MOLECULAR dynamics, CHEMICAL systems, VIRTUAL reality, CITIZEN science

Abstract

The emerging fields of citizen science and gamification reformulate scientific problems as games or puzzles to be solved. Through engaging the wider non-scientific community, significant breakthroughs may be made by analyzing citizen-gathered data. In parallel, recent advances in virtual reality (VR) technology are increasingly being used within a scientific context and the burgeoning field of interactive molecular dynamics in VR (iMD-VR) allows users to interact with dynamical chemistry simulations in real time. Here, we demonstrate the utility of iMD-VR as a medium for gamification of chemistry research tasks. An iMD-VR "game" was designed to encourage users to explore the reactivity of a particular chemical system, and a cohort of 18 participants was recruited to playtest this game as part of a user study. The reaction game encouraged users to experiment with making chemical reactions between a propyne molecule and an OH radical, and "molecular snapshots" from each game session were then compiled and used to map out reaction pathways. The reaction network generated by users was compared to existing literature networks demonstrating that users in VR capture almost all the important reaction pathways. Further comparisons between humans and an algorithmic method for guiding molecular dynamics show that through using citizen science to explore these kinds of chemical problems, new approaches and strategies start to emerge. [ABSTRACT FROM AUTHOR]

Published

2021

2. Free energy along drug-protein binding pathways interactively sampled in virtual reality.

Author

Deeks, Helen M., Zinovjev, Kirill, Barnoud, Jonathan, Mulholland, Adrian J., van der Kamp, Marc W., and Glowacki, David R.

Subjects

GIBBS' energy diagram, TRYPSIN, METASTABLE states, MOLECULAR dynamics, ENERGY consumption, RESEARCH personnel

Abstract

We describe a two-step approach for combining interactive molecular dynamics in virtual reality (iMD-VR) with free energy (FE) calculation to explore the dynamics of biological processes at the molecular level. We refer to this combined approach as iMD-VR-FE. Stage one involves using a state-of-the-art 'human-in-the-loop' iMD-VR framework to generate a diverse range of protein–ligand unbinding pathways, benefitting from the sophistication of human spatial and chemical intuition. Stage two involves using the iMD-VR-sampled pathways as initial guesses for defining a path-based reaction coordinate from which we can obtain a corresponding free energy profile using FE methods. To investigate the performance of the method, we apply iMD-VR-FE to investigate the unbinding of a benzamidine ligand from a trypsin protein. The binding free energy calculated using iMD-VR-FE is similar for each pathway, indicating internal consistency. Moreover, the resulting free energy profiles can distinguish energetic differences between pathways corresponding to various protein–ligand conformations (e.g., helping to identify pathways that are more favourable) and enable identification of metastable states along the pathways. The two-step iMD-VR-FE approach offers an intuitive way for researchers to test hypotheses for candidate pathways in biomolecular systems, quickly obtaining both qualitative and quantitative insight. [ABSTRACT FROM AUTHOR]

Published

2023

3. Free energy along drug-protein binding pathways interactively sampled in virtual reality.

Author

Deeks, Helen M., Zinovjev, Kirill, Barnoud, Jonathan, Mulholland, Adrian J., van der Kamp, Marc W., and Glowacki, David R.

Subjects

GIBBS' energy diagram, TRYPSIN, METASTABLE states, MOLECULAR dynamics, ENERGY consumption, RESEARCH personnel

Abstract

We describe a two-step approach for combining interactive molecular dynamics in virtual reality (iMD-VR) with free energy (FE) calculation to explore the dynamics of biological processes at the molecular level. We refer to this combined approach as iMD-VR-FE. Stage one involves using a state-of-the-art 'human-in-the-loop' iMD-VR framework to generate a diverse range of protein–ligand unbinding pathways, benefitting from the sophistication of human spatial and chemical intuition. Stage two involves using the iMD-VR-sampled pathways as initial guesses for defining a path-based reaction coordinate from which we can obtain a corresponding free energy profile using FE methods. To investigate the performance of the method, we apply iMD-VR-FE to investigate the unbinding of a benzamidine ligand from a trypsin protein. The binding free energy calculated using iMD-VR-FE is similar for each pathway, indicating internal consistency. Moreover, the resulting free energy profiles can distinguish energetic differences between pathways corresponding to various protein–ligand conformations (e.g., helping to identify pathways that are more favourable) and enable identification of metastable states along the pathways. The two-step iMD-VR-FE approach offers an intuitive way for researchers to test hypotheses for candidate pathways in biomolecular systems, quickly obtaining both qualitative and quantitative insight. [ABSTRACT FROM AUTHOR]

Published

2023

4. Interactive molecular dynamics in virtual reality from quantum chemistry to drug binding: An open-source multi-person framework.

Author

O'Connor, Michael B., Bennie, Simon J., Deeks, Helen M., Jamieson-Binnie, Alexander, Jones, Alex J., Shannon, Robin J., Walters, Rebecca, Mitchell, Thomas J., Mulholland, Adrian J., and Glowacki, David R.

Subjects

QUANTUM chemistry, MOLECULAR dynamics, PHARMACEUTICAL chemistry, VIRTUAL reality, NANOTECHNOLOGY

Abstract

As molecular scientists have made progress in their ability to engineer nanoscale molecular structure, we face new challenges in our ability to engineer molecular dynamics (MD) and flexibility. Dynamics at the molecular scale differs from the familiar mechanics of everyday objects because it involves a complicated, highly correlated, and three-dimensional many-body dynamical choreography which is often nonintuitive even for highly trained researchers. We recently described how interactive molecular dynamics in virtual reality (iMD-VR) can help to meet this challenge, enabling researchers to manipulate real-time MD simulations of flexible structures in 3D. In this article, we outline various efforts to extend immersive technologies to the molecular sciences, and we introduce "Narupa," a flexible, open-source, multiperson iMD-VR software framework which enables groups of researchers to simultaneously cohabit real-time simulation environments to interactively visualize and manipulate the dynamics of molecular structures with atomic-level precision. We outline several application domains where iMD-VR is facilitating research, communication, and creative approaches within the molecular sciences, including training machines to learn potential energy functions, biomolecular conformational sampling, protein-ligand binding, reaction discovery using "on-the-fly" quantum chemistry, and transport dynamics in materials. We touch on iMD-VR's various cognitive and perceptual affordances and outline how these provide research insight for molecular systems. By synergistically combining human spatial reasoning and design insight with computational automation, technologies such as iMD-VR have the potential to improve our ability to understand, engineer, and communicate microscopic dynamical behavior, offering the potential to usher in a new paradigm for engineering molecules and nano-architectures. [ABSTRACT FROM AUTHOR]

Published

2019

5. Discovery of SARS-CoV-2 Mpro peptide inhibitors from modelling substrate and ligand binding.

Author

Chan, H. T. Henry, Moesser, Marc A., Walters, Rebecca K., Malla, Tika R., Twidale, Rebecca M., John, Tobias, Deeks, Helen M., Johnston-Wood, Tristan, Mikhailov, Victor, Sessions, Richard B., Dawson, William, Salah, Eidarus, Lukacik, Petra, Strain-Damerell, Claire, Owen, C. David, Nakajima, Takahito, Świderek, Katarzyna, Lodola, Alessio, Moliner, Vicent, and Glowacki, David R.

Published

2021

6. Interactive molecular dynamics in virtual reality for accurate flexible protein-ligand docking.

Author

Deeks, Helen M., Walters, Rebecca K., Hare, Stephanie R., O'Connor, Michael B., Mulholland, Adrian J., and Glowacki, David R.

Subjects

MOLECULAR dynamics, VIRTUAL reality, BINDING sites, PROTEOLYTIC enzymes, MOLECULAR docking, NEURAMINIDASE, BOUND states, TRYPSIN

Abstract

Simulating drug binding and unbinding is a challenge, as the rugged energy landscapes that separate bound and unbound states require extensive sampling that consumes significant computational resources. Here, we describe the use of interactive molecular dynamics in virtual reality (iMD-VR) as an accurate low-cost strategy for flexible protein-ligand docking. We outline an experimental protocol which enables expert iMD-VR users to guide ligands into and out of the binding pockets of trypsin, neuraminidase, and HIV-1 protease, and recreate their respective crystallographic protein-ligand binding poses within 5–10 minutes. Following a brief training phase, our studies shown that iMD-VR novices were able to generate unbinding and rebinding pathways on similar timescales as iMD-VR experts, with the majority able to recover binding poses within 2.15 Å RMSD of the crystallographic binding pose. These results indicate that iMD-VR affords sufficient control for users to carry out the detailed atomic manipulations required to dock flexible ligands into dynamic enzyme active sites and recover crystallographic poses, offering an interesting new approach for simulating drug docking and generating binding hypotheses. [ABSTRACT FROM AUTHOR]

Published

2020