Anatomical Modeling of Brain Vasculature in Two-Photon Microscopy by Generalizable Deep Learning

IF 5 Q1 ENGINEERING, BIOMEDICAL

BME frontiers Pub Date : 2020-08-10 DOI:10.1101/2020.08.09.243394

Waleed Tahir, Sreekanth Kura, Jiabei Zhu, Xiaojun Cheng, R. Damseh, Fetsum Tadesse, Alex J. Seibel, Blaire S. Lee, F. Lesage, Sava Sakadžié, D. Boas, L. Tian

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引用次数: 16

Abstract

Objective and Impact Statement Segmentation of blood vessels from two-photon microscopy (2PM) angiograms of brains has important applications in hemodynamic analysis and disease diagnosis. Here we develop a generalizable deep learning technique for accurate 2PM vascular segmentation of sizable regions in mouse brains acquired from multiple 2PM setups. The technique is computationally efficient, thus ideal for large-scale neurovascular analysis. Introduction Vascular segmentation from 2PM angiograms is an important first step in hemodynamic modeling of brain vasculature. Existing segmentation methods based on deep learning either lack the ability to generalize to data from different imaging systems, or are computationally infeasible for large-scale angiograms. In this work, we overcome both these limitations by a method that is generalizable to various imaging systems, and is able to segment large-scale angiograms. Methods We employ a computationally efficient deep learning framework with a loss function that incorporates a balanced binary-cross-entropy loss and a total variation regularization on the network’s output. Its effectiveness is demonstrated on experimentally acquired in-vivo angiograms from mouse brains of dimensions up to 808×808×702 μm. Results To demonstrate the superior generalizability of our framework, we train on data from only one 2PM microscope, and demonstrate high-quality segmentation on data from a different microscope without any network tuning. Overall, our method demonstrates 10× faster computation in terms of voxels-segmented-per-second and 3× larger depth compared to the state-of-the-art. Conclusion Our work provides a generalizable and computationally efficient anatomical modeling framework for brain vasculature, which consists of deep learning based vascular segmentation followed by graphing. It paves the way for future modeling and analysis of hemodynamic response at much greater scales that were inaccessible before.

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基于广义深度学习的双光子显微镜下脑血管解剖建模

目的与影响双光子显微镜(2PM)脑血管图像的血管分割在血流动力学分析和疾病诊断中具有重要的应用价值。在这里，我们开发了一种可推广的深度学习技术，用于从多个2PM设置中获得的小鼠大脑中相当大的区域进行精确的2PM血管分割。该技术计算效率高，因此是大规模神经血管分析的理想选择。从2PM血管造影中进行血管分割是脑血管血流动力学建模的重要第一步。现有的基于深度学习的分割方法要么缺乏泛化到不同成像系统数据的能力，要么在计算上不适合大规模血管造影。在这项工作中，我们通过一种可推广到各种成像系统的方法克服了这两个限制，并且能够分割大规模血管造影。我们采用了一个计算效率高的深度学习框架，其损失函数结合了平衡的二元交叉熵损失和网络输出的总变分正则化。其有效性在实验中获得的小鼠大脑血管造影(尺寸高达808×808×702 μm)上得到了证明。为了证明我们的框架具有优越的通用性，我们只对一台2PM显微镜的数据进行训练，并在没有任何网络调优的情况下对来自另一台显微镜的数据进行了高质量的分割。总的来说，我们的方法在每秒分割体素方面的计算速度提高了10倍，与最先进的方法相比，深度提高了3倍。我们的工作提供了一个可推广且计算效率高的脑血管解剖学建模框架，该框架由基于深度学习的血管分割和绘图组成。它为将来在更大的尺度上建模和分析血液动力学反应铺平了道路，这在以前是无法实现的。

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

BME frontiers

CiteScore

7.10

自引率

0.00%

发文量

审稿时长

16 weeks