A Perspective on AI-Guided Molecular Simulations in VR: Exploring Strategies for Imitation Learning in Hyperdimensional Molecular Systems

arXiv - QuanBio - Biomolecules Pub Date : 2024-09-11 DOI:arxiv-2409.07189

Mohamed Dhouioui, Jonathan Barnoud, Rhoslyn Roebuck Williams, Harry J. Stroud, Phil Bates, David R. Glowacki

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引用次数: 0

Abstract

Molecular dynamics simulations are a crucial computational tool for researchers to understand and engineer molecular structure and function in areas such as drug discovery, protein engineering, and material design. Despite their utility, MD simulations are expensive, owing to the high dimensionality of molecular systems. Interactive molecular dynamics in virtual reality (iMD-VR) has recently been developed as a 'human-in-the-loop' strategy, which leverages high-performance computing to accelerate the researcher's ability to solve the hyperdimensional sampling problem. By providing an immersive 3D environment that enables visualization and manipulation of real-time molecular motion, iMD-VR enables researchers and students to efficiently and intuitively explore and navigate these complex, high-dimensional systems. iMD-VR platforms offer a unique opportunity to quickly generate rich datasets that capture human experts' spatial insight regarding molecular structure and function. This paper explores the possibility of employing user-generated iMD-VR datasets to train AI agents via imitation learning (IL). IL is an important technique in robotics that enables agents to mimic complex behaviors from expert demonstrations, thus circumventing the need for explicit programming or intricate reward design. We review the utilization of IL for manipulation tasks in robotics and discuss how iMD-VR recordings could be used to train IL models for solving specific molecular 'tasks'. We then investigate how such approaches could be applied to the data captured from iMD-VR recordings. Finally, we outline the future research directions and potential challenges of using AI agents to augment human expertise to efficiently navigate conformational spaces, highlighting how this approach could provide valuable insight across domains such as materials science, protein engineering, and computer-aided drug design.

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透视人工智能引导的 VR 分子模拟：探索超维分子系统中的模仿学习策略

分子动力学模拟是研究人员在药物发现、蛋白质工程和材料设计等领域了解和设计分子结构与功能的重要计算工具。尽管分子动力学模拟很有用，但由于分子系统的高维性，其成本也很高。最近，虚拟现实中的交互式分子动力学（iMD-VR）作为一种 "人在回路中 "的策略被开发出来，它利用高性能计算加快了研究人员解决超维度采样问题的能力。iMD-VR 平台提供了一个独特的机会，可以快速生成丰富的数据集，捕捉人类专家对分子结构和功能的空间洞察力。本论文探讨了利用用户生成的 iMD-VR 数据集通过模仿学习（IL）训练人工智能代理的可能性。模仿学习是机器人领域的一项重要技术，它使人工智能代理能够模仿专家示范的复杂行为，从而避免了明确编程或复杂奖励设计的需要。我们探讨了机器人操纵任务中对 IL 的利用，并讨论了如何利用 iMD-VR 记录来训练 IL 模型，以解决特定的分子 "任务"。然后，我们研究了如何将此类方法应用于 iMD-VR 记录中捕获的数据。最后，我们概述了使用人工智能代理来增强人类高效导航构象空间的专业知识的未来研究方向和潜在挑战，并强调了这种方法如何能够在材料科学、蛋白质工程和计算机辅助药物设计等领域提供有价值的见解。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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arXiv - QuanBio - Biomolecules

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