基于像素对关联和超像素级特征的 CRF（条件随机场）框架中的脑肿瘤检测与分割。

Brain tumor detection and segmentation in a CRF (conditional random fields) framework with pixel-pairwise affinity and superpixel-level features.

机构信息

Department of Computer Science and Engineering, SUNY at Buffalo, Buffalo, NY, USA,

出版信息

Int J Comput Assist Radiol Surg. 2014 Mar;9(2):241-53. doi: 10.1007/s11548-013-0922-7. Epub 2013 Jul 17.

DOI:10.1007/s11548-013-0922-7

PMID:23860630

Abstract

PURPOSE

Detection and segmentation of a brain tumor such as glioblastoma multiforme (GBM) in magnetic resonance (MR) images are often challenging due to its intrinsically heterogeneous signal characteristics. A robust segmentation method for brain tumor MRI scans was developed and tested.

METHODS

Simple thresholds and statistical methods are unable to adequately segment the various elements of the GBM, such as local contrast enhancement, necrosis, and edema. Most voxel-based methods cannot achieve satisfactory results in larger data sets, and the methods based on generative or discriminative models have intrinsic limitations during application, such as small sample set learning and transfer. A new method was developed to overcome these challenges. Multimodal MR images are segmented into superpixels using algorithms to alleviate the sampling issue and to improve the sample representativeness. Next, features were extracted from the superpixels using multi-level Gabor wavelet filters. Based on the features, a support vector machine (SVM) model and an affinity metric model for tumors were trained to overcome the limitations of previous generative models. Based on the output of the SVM and spatial affinity models, conditional random fields theory was applied to segment the tumor in a maximum a posteriori fashion given the smoothness prior defined by our affinity model. Finally, labeling noise was removed using "structural knowledge" such as the symmetrical and continuous characteristics of the tumor in spatial domain.

RESULTS

The system was evaluated with 20 GBM cases and the BraTS challenge data set. Dice coefficients were computed, and the results were highly consistent with those reported by Zikic et al. (MICCAI 2012, Lecture notes in computer science. vol 7512, pp 369-376, 2012).

CONCLUSION

A brain tumor segmentation method using model-aware affinity demonstrates comparable performance with other state-of-the art algorithms.

摘要

目的

由于脑肿瘤（如多形性胶质母细胞瘤 [GBM]）信号特征固有存在异质性，因此在磁共振（MR）图像中检测和分割脑肿瘤常常具有挑战性。本文开发并测试了一种用于脑肿瘤 MRI 扫描的稳健分割方法。

方法

简单的阈值和统计方法无法充分分割 GBM 的各个元素，例如局部对比增强、坏死和水肿。大多数基于体素的方法在更大的数据集上无法获得满意的结果，而基于生成或判别模型的方法在应用中存在内在局限性，例如小样本集学习和转移。本文开发了一种新方法来克服这些挑战。多模态 MR 图像使用算法分割成超像素，以减轻采样问题并提高样本代表性。接下来，使用多级 Gabor 小波滤波器从超像素中提取特征。基于这些特征，训练支持向量机（SVM）模型和肿瘤亲和度度量模型，以克服以前生成模型的局限性。基于 SVM 和空间亲和度模型的输出，应用条件随机场理论以最大后验概率方式对肿瘤进行分割，该概率由我们的亲和度模型定义的平滑先验给出。最后，使用“结构知识”（例如肿瘤在空间域中的对称和连续特征）去除标注噪声。

结果

使用 20 例 GBM 病例和 BraTS 挑战赛数据集对该系统进行了评估。计算了 Dice 系数，结果与 Zikic 等人的报告高度一致（MICCAI 2012，计算机科学讲义。第 7512 卷，第 369-376 页，2012 年）。

结论

使用模型感知亲和度的脑肿瘤分割方法具有与其他最先进算法相当的性能。

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基于像素对关联和超像素级特征的 CRF（条件随机场）框架中的脑肿瘤检测与分割。

Brain tumor detection and segmentation in a CRF (conditional random fields) framework with pixel-pairwise affinity and superpixel-level features.

机构信息

出版信息

PURPOSE

METHODS

RESULTS

CONCLUSION

目的

方法

结果

结论

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