Optimal acquisition sequence for AI-assisted brain tumor segmentation under the constraint of largest information gain per additional MRI sequence

Neuroscience informatics Pub Date : 2022-12-01 DOI:10.1016/j.neuri.2022.100053

Raphael M. Kronberg , Dziugas Meskelevicius , Michael Sabel , Markus Kollmann , Christian Rubbert , Igor Fischer

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引用次数: 6

Abstract

Purpose

Different imaging sequences (T1 etc.) depict different aspects of a brain tumor. As clinical MRI examinations of the brain might be terminated prematurely, not all sequences may be acquired, decreasing the performance of automated tumor segmentation. We attempt to optimize the order of sequences, to maximize information gain in case of incomplete examination.

Methods

For segmentation we used the winner algorithm of the Brain Tumor Segmentation challenge 2018, trained on the BraTS 2020 dataset, with the objective to segment necrotic core, peritumoral edema, and enhancing tumor. We compared the segmentation performance for all combinations of sequences, using the Dice score (DS) as the primary metric. We compare the results with those which would be obtained by attempting to follow the consensus recommendations for brain tumor imaging [T1, FLAIR, T2, T1CE].

Results

The average segmentation accuracy varies between 0.476 for T1 only and 0.751 for the full set of sequences. T1CE has a high information content, even regarding peritumoral edema and information of T2 and FLAIR were highly redundant. The optimal order of sequences appears to be [T1, T2, T1CE, FLAIR]. Comparing segmentation accuracy after each fully acquired sequence, the first sequence (T1) is the same for both, DS for [T1, T2] (proposed) is 6.2% higher than [T1, FLAIR] (aborted recommendations), and [T1, T2, T1CE] (proposed) is 34.8% higher than [T1, FLAIR, T2] (aborted recommendations).

Conclusion

For the purpose of optimal deep-learning-based segmentation purposes in potentially incomplete MRI examinations, the T1CE sequence should be acquired as early as possible.

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以每附加MRI序列信息增益最大为约束的人工智能辅助脑肿瘤分割的最佳采集序列

不同的成像序列(T1等)描绘脑肿瘤的不同方面。由于大脑的临床MRI检查可能过早终止，因此可能无法获得所有序列，从而降低了自动肿瘤分割的性能。我们试图优化序列的顺序，以在不完全检查的情况下最大化信息增益。方法使用BraTS 2020数据集训练的2018脑肿瘤分割挑战赛优胜者算法进行分割，目的是分割坏死核心、肿瘤周围水肿和增强肿瘤。我们比较了所有序列组合的分割性能，使用Dice分数(DS)作为主要指标。我们将结果与试图遵循一致建议的脑肿瘤成像[T1, FLAIR, T2, T1CE]所获得的结果进行比较。结果该方法的平均分割准确率为0.476 (T1)和0.751(全序列)。T1CE信息含量高，甚至关于肿瘤周围水肿，T2和FLAIR信息高度冗余。序列的最优顺序为[T1, T2, T1CE, FLAIR]。比较每个完全获取序列后的分割精度，两者的第一个序列(T1)的分割精度相同，[T1, T2](建议)的分割精度比[T1, FLAIR](放弃推荐)高6.2%，[T1, T2, T1CE](建议)的分割精度比[T1, FLAIR, T2](放弃推荐)高34.8%。结论为了在可能不完整的MRI检查中实现最佳的深度学习分割目的，应尽早获取T1CE序列。

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

Neuroscience informatics Surgery, Radiology and Imaging, Information Systems, Neurology, Artificial Intelligence, Computer Science Applications, Signal Processing, Critical Care and Intensive Care Medicine, Health Informatics, Clinical Neurology, Pathology and Medical Technology

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57 days