Spatial assessments in texture analysis: what the radiologist needs to know.

Frontiers in radiology Pub Date : 2023-08-24 eCollection Date: 2023-01-01 DOI:10.3389/fradi.2023.1240544
Bino A Varghese, Brandon K K Fields, Darryl H Hwang, Vinay A Duddalwar, George R Matcuk, Steven Y Cen
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Abstract

To date, studies investigating radiomics-based predictive models have tended to err on the side of data-driven or exploratory analysis of many thousands of extracted features. In particular, spatial assessments of texture have proven to be especially adept at assessing for features of intratumoral heterogeneity in oncologic imaging, which likewise may correspond with tumor biology and behavior. These spatial assessments can be generally classified as spatial filters, which detect areas of rapid change within the grayscale in order to enhance edges and/or textures within an image, or neighborhood-based methods, which quantify gray-level differences of neighboring pixels/voxels within a set distance. Given the high dimensionality of radiomics datasets, data dimensionality reduction methods have been proposed in an attempt to optimize model performance in machine learning studies; however, it should be noted that these approaches should only be applied to training data in order to avoid information leakage and model overfitting. While area under the curve of the receiver operating characteristic is perhaps the most commonly reported assessment of model performance, it is prone to overestimation when output classifications are unbalanced. In such cases, confusion matrices may be additionally reported, whereby diagnostic cut points for model predicted probability may hold more clinical significance to clinical colleagues with respect to related forms of diagnostic testing.

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纹理分析中的空间评估:放射科医生须知。
迄今为止,基于放射组学预测模型的研究往往偏向于数据驱动或对数千个提取特征进行探索性分析。特别是,纹理的空间评估已被证明特别擅长评估肿瘤成像中的瘤内异质性特征,这同样可能与肿瘤生物学和行为学相对应。这些空间评估一般可分为空间滤波器和基于邻域的方法,前者可检测灰度范围内的快速变化区域,以增强图像中的边缘和/或纹理;后者可量化设定距离内相邻像素/体素的灰度差异。鉴于放射组学数据集的高维性,人们提出了数据降维方法,试图优化机器学习研究中的模型性能;但需要注意的是,这些方法只能应用于训练数据,以避免信息泄露和模型过拟合。虽然接收者操作特征曲线下面积可能是最常报道的模型性能评估方法,但当输出分类不平衡时,它很容易被高估。在这种情况下,可能会额外报告混淆矩阵,据此,模型预测概率的诊断切点可能对临床同事来说,与相关形式的诊断测试相比,具有更多的临床意义。
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