Preserving Derivative Information while Transforming Neuronal Curves.

IF 2.7 4区 医学 Q2 COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS
Neuroinformatics Pub Date : 2024-01-01 Epub Date: 2023-11-30 DOI:10.1007/s12021-023-09648-0
Thomas L Athey, Daniel J Tward, Ulrich Mueller, Laurent Younes, Joshua T Vogelstein, Michael I Miller
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引用次数: 0

Abstract

The international neuroscience community is building the first comprehensive atlases of brain cell types to understand how the brain functions from a higher resolution, and more integrated perspective than ever before. In order to build these atlases, subsets of neurons (e.g. serotonergic neurons, prefrontal cortical neurons etc.) are traced in individual brain samples by placing points along dendrites and axons. Then, the traces are mapped to common coordinate systems by transforming the positions of their points, which neglects how the transformation bends the line segments in between. In this work, we apply the theory of jets to describe how to preserve derivatives of neuron traces up to any order. We provide a framework to compute possible error introduced by standard mapping methods, which involves the Jacobian of the mapping transformation. We show how our first order method improves mapping accuracy in both simulated and real neuron traces under random diffeomorphisms. Our method is freely available in our open-source Python package brainlit.

Abstract Image

神经元曲线变换时导数信息的保持。
国际神经科学界正在建立第一个全面的脑细胞类型地图集,以从一个比以往更高的分辨率和更综合的角度来理解大脑是如何运作的。为了建立这些图谱,神经元亚群(如血清素能神经元、前额皮质神经元等)通过沿树突和轴突放置点在个体大脑样本中进行追踪。然后,通过变换其点的位置将轨迹映射到公共坐标系,这忽略了变换如何弯曲中间的线段。在这项工作中,我们应用射流理论来描述如何保持神经元轨迹的导数到任何阶。我们提供了一个计算标准映射方法可能引入的误差的框架,其中涉及映射变换的雅可比矩阵。我们展示了我们的一阶方法如何在随机微分同态下提高模拟和真实神经元轨迹的映射精度。我们的方法可以在我们的开源Python包brainlit中免费获得。
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
Neuroinformatics
Neuroinformatics 医学-计算机:跨学科应用
CiteScore
6.00
自引率
6.70%
发文量
54
审稿时长
3 months
期刊介绍: Neuroinformatics publishes original articles and reviews with an emphasis on data structure and software tools related to analysis, modeling, integration, and sharing in all areas of neuroscience research. The editors particularly invite contributions on: (1) Theory and methodology, including discussions on ontologies, modeling approaches, database design, and meta-analyses; (2) Descriptions of developed databases and software tools, and of the methods for their distribution; (3) Relevant experimental results, such as reports accompanie by the release of massive data sets; (4) Computational simulations of models integrating and organizing complex data; and (5) Neuroengineering approaches, including hardware, robotics, and information theory studies.
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