NeuroBox: Computational Mathematics in Multiscale Neuroscience.

Q1 Engineering
Computing and Visualization in Science Pub Date : 2019-09-01 Epub Date: 2019-06-14 DOI:10.1007/s00791-019-00314-0
M Stepniewski, M Breit, M Hoffer, G Queisser
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引用次数: 5

Abstract

The brain is a complex organ operating on multiple scales. From molecular events that inform electrical and biochemical cellular responses, the brain interconnects processes all the way up to the massive network size of billions of brain cells. This strongly coupled, nonlinear, system has been subject to research that has turned increasingly multidisciplinary. The seminal work of Hodgkin and Huxley in the 1950s made use of experimental data to derive a coherent physical model of electrical signaling in neurons, which can be solved using mathematical and computational methods, thus bringing together neuroscience, physics, mathematics, and computer science. Over the last decades numerous projects have been dedicated to modeling and simulation of specific parts of molecular dynamics, neuronal signaling, and neural network behavior. Simulators have been developed around a specific objective and scale, in order to cope with the underlying computational complexity. Often times a dimension reduction approach allows larger scale simulations, this however has the inherent drawback of losing insight into structure-function interplay at the cellular level. This paper gives an overview of the project NeuroBox that has the objective of integrating multiple brain scales and associated physical models into one unified framework. NeuroBox hosts geometry and anatomical reconstruction methods, such that detailed three-dimensional domains can be integrated into numerical simulations of models based on partial differential equations. The project further focusses on deriving numerical methods for handling complex computational domains, and to couple multiple spatial dimensions. The latter allows the user to specify in which parts of the biological problem high-dimensional representations are necessary and where low-dimensional approximations are acceptable. NeuroBox offers workflow user interfaces that are automatically generated with VRL-Studio and can be controlled by non-experts. The project further uses uG4 as the numerical backend, and therefore accesses highly advanced discretization methods as well as hierarchical and scalable numerical solvers for very large neurobiological problems.

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神经盒:多尺度神经科学中的计算数学。
大脑是一个复杂的器官,在多个尺度上运作。从分子事件通知电和生化细胞反应,大脑相互连接的过程一直到数十亿脑细胞的庞大网络大小。这种强耦合的非线性系统已经成为越来越多学科研究的主题。霍奇金和赫胥黎在20世纪50年代的开创性工作利用实验数据推导出神经元电信号的连贯物理模型,可以使用数学和计算方法来解决,从而将神经科学,物理学,数学和计算机科学结合在一起。在过去的几十年里,许多项目都致力于分子动力学、神经元信号和神经网络行为的特定部分的建模和模拟。为了应对潜在的计算复杂性,围绕特定的目标和规模开发了模拟器。通常情况下,降维方法允许更大规模的模拟,然而,这有固有的缺点,即在细胞水平上失去对结构-功能相互作用的洞察力。本文概述了NeuroBox项目,该项目的目标是将多个大脑尺度和相关物理模型集成到一个统一的框架中。NeuroBox拥有几何和解剖重建方法,因此详细的三维领域可以集成到基于偏微分方程的数值模拟模型中。该项目进一步侧重于推导处理复杂计算域的数值方法,并耦合多个空间维度。后者允许用户指定生物问题的哪些部分需要高维表示,哪些部分可以接受低维近似。NeuroBox提供使用VRL-Studio自动生成的工作流用户界面,可以由非专家控制。该项目进一步使用uG4作为数值后端,因此可以访问非常先进的离散化方法以及用于非常大的神经生物学问题的分层和可扩展数值解算器。
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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来源期刊
Computing and Visualization in Science
Computing and Visualization in Science Engineering-Engineering (all)
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期刊介绍: Devoted to computational sciences, this journal publishes pioneering methods and applications that bring about the solution of complex problems, or even make such solutions possible at all. Since visualization has become an important scientific tool, especially in the analysis of complex situations, it is treated in close connection with the other areas covered by the journal.
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