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深度学习在磁共振成像脑肿瘤自动分割中的应用:临床场景中的启发式方法。

Application of deep learning for automatic segmentation of brain tumors on magnetic resonance imaging: a heuristic approach in the clinical scenario.

机构信息

Department of Clinical Medicine, Faculty of Medicine, Human and Health Sciences, Macquarie University, Sydney, Australia.

Computational NeuroSurgery (CNS) Lab, Department of Clinical Medicine, Faculty of Medicine, Human and Health Sciences, Macquarie University, Sydney, Australia.

出版信息

Neuroradiology. 2021 Aug;63(8):1253-1262. doi: 10.1007/s00234-021-02649-3. Epub 2021 Jan 26.

DOI:10.1007/s00234-021-02649-3
PMID:33501512
Abstract

PURPOSE

Accurate brain tumor segmentation on magnetic resonance imaging (MRI) has wide-ranging applications such as radiosurgery planning. Advances in artificial intelligence, especially deep learning (DL), allow development of automatic segmentation that overcome the labor-intensive and operator-dependent manual segmentation. We aimed to evaluate the accuracy of the top-performing DL model from the 2018 Brain Tumor Segmentation (BraTS) challenge, the impact of missing MRI sequences, and whether a model trained on gliomas can accurately segment other brain tumor types.

METHODS

We trained the model using Medical Decathlon dataset, applied it to the BraTS 2019 glioma dataset, and developed additional models using individual and multimodal MRI sequences. The Dice score was calculated to assess the model's accuracy compared to ground truth labels by neuroradiologists on BraTS dataset. The model was then applied to a local dataset of 105 brain tumors, performance of which was qualitatively evaluated.

RESULTS

The DL model using pre- and post-gadolinium contrast T1 and T2 FLAIR sequences performed best, with a Dice score 0.878 for whole tumor, 0.732 tumor core, and 0.699 active tumor. Lack of T1 or T2 sequences did not significantly degrade performance, but FLAIR and T1C were important contributors. All segmentations performed by the model in the local dataset, including non-glioma cases, were considered accurate by a pool of specialists.

CONCLUSION

The DL model could use available MRI sequences to optimize glioma segmentation and adopt transfer learning to segment non-glioma tumors, thereby serving as a useful tool to improve treatment planning and personalized surveillance of patients.

摘要

目的

磁共振成像(MRI)上精确的脑肿瘤分割具有广泛的应用,例如放射外科计划。人工智能的进步,尤其是深度学习(DL),使得自动分割得以发展,克服了劳动密集型和依赖操作人员的手动分割。我们旨在评估 2018 年脑肿瘤分割(BraTS)挑战赛中表现最佳的 DL 模型的准确性、缺失 MRI 序列的影响,以及一个在神经胶质瘤上训练的模型是否可以准确地分割其他脑肿瘤类型。

方法

我们使用 Medical Decathlon 数据集对模型进行训练,将其应用于 BraTS 2019 神经胶质瘤数据集,并使用单个和多模态 MRI 序列开发了额外的模型。我们通过神经放射科医生在 BraTS 数据集上计算 Dice 评分来评估模型与地面真实标签相比的准确性。然后,我们将模型应用于 105 例脑部肿瘤的本地数据集,并对其性能进行了定性评估。

结果

使用钆前和后对比 T1 和 T2 FLAIR 序列的 DL 模型表现最佳,整体肿瘤、肿瘤核心和活跃肿瘤的 Dice 评分分别为 0.878、0.732 和 0.699。缺乏 T1 或 T2 序列不会显著降低性能,但 FLAIR 和 T1C 是重要的贡献者。模型在本地数据集上的所有分割,包括非神经胶质瘤病例,都被一组专家认为是准确的。

结论

DL 模型可以使用现有的 MRI 序列来优化神经胶质瘤的分割,并采用迁移学习来分割非神经胶质瘤肿瘤,从而成为改善治疗计划和患者个性化监测的有用工具。

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