Statistical Mechanics and Computer Simulations with Applications in Micro- and Nano-Fluidics and Biological Physics

统计力学和计算机模拟在微纳米流体和生物物理学中的应用

• 批准号: 46434-2013
• 负责人: Slater, Gary
• 金额: $ 1.82万
• 依托单位: University of Ottawa
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2020
• 资助国家: 加拿大
• 起止时间: 2020-01-01 至 2021-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=695136
• 关键词: Statistical; Mechanics; Computer; Simulations; Applications

Over the last 10-15 years, we have witnessed a remarkable convergence of the experimental and computational sciences. Indeed, while experimentalists can now study single molecules such as DNA or proteins, or even build nanoscopic systems (e.g., nanochannels) made of a very small number of molecules, theoreticians now possess the theoretical and computational tools to study the very same systems, molecule by molecule. Massive computers make it possible to make molecular movies and detailed predictions. This convergence opens incredible possibilities in a number of disciplines, including biophysics and the separation sciences. In this grant application, we propose to investigate several problems at the interfaces between soft matter physics, analytical chemistry, biotechnology, computational science, and biophysics: (1) We will use molecular-level computer simulations to study micro- and nanofluidic systems used to separate and analyze DNA and proteins (what is often called lab-on-a-chip systems in the media). (2) We will continue the development of our revolutionary lattice model of diffusion and drift. We will extend our work to study the separation of biomolecules with high and pulsed electric fields, ratchet systems, networks of cavities, drug-delivery systems (e.g., gel-based pills), complex geometries, ... (3) We will continue the study and development of new microfluidic technologies. In particular, we will examine the separation of long DNA molecules, the use of artificial media as a substitute to fragile gels, and the design of devices based on thermodynamic ratchet systems. (4) We will model the passage of DNA through narrow pores, the process that will most likely be behind the next generation of DNA sequencers. We will examine the role of noise, the utilization of pulsed electric fields, and finally some biological aspects of this process as it occurs in live cells. (5) Finally, we will model the collective motion of swimming bacteria in asymmetric devices to see if these devices can be used to separate the cells according to their biophysical properties.

在过去的10 - 15年中，我们目睹了实验和计算科学的显着融合。实际上，尽管实验者现在可以研究诸如DNA或蛋白质之类的单分子，甚至可以研究由少数分子制成的纳米镜系统（例如纳米通道），但理论家现在拥有理论和计算工具来研究分子的理论和计算工具。大型计算机使制作分子电影和详细预测成为可能。这种融合在包括生物物理学和分离科学在内的许多学科中打开了令人难以置信的可能性。在此赠款应用中，我们建议在软物质物理学，分析化学，生物技术，计算科学和生物物理学之间研究几个问题： （1）我们将使用分子级计算机模拟来研究用于分离和分析DNA和蛋白质（通常在培养基中使用实验室的芯片系统）的微流体系统和纳米流体系统。 （2）我们将继续开发革命性的扩散和漂移晶格模型。我们将扩展工作，以研究具有高电场和脉冲电场，棘轮系统，腔网络，药物交付系统（例如，基于凝胶的药丸），复杂几何形状的生物分子的分离，... （3）我们将继续研究和开发新的微流体技术。特别是，我们将检查长DNA分子的分离，人工培养基作为脆弱凝胶的替代品，以及基于热力学棘轮系统的设备设计。 （4）我们将建模DNA通过狭窄的孔的通道，该过程很可能是下一代DNA测序仪的落后的过程。我们将研究噪声的作用，脉冲电场的利用，最后是该过程中的某些生物学方面，因为它发生在活细胞中。 （5）最后，我们将在非对称设备中游泳细菌的集体运动对这些装置的集体运动进行建模，以查看这些设备是否可以根据其生物物理特性来分离细胞。