Automatic Detection and Classification of Cerebral Microbleeds Using 3D CNN.

Journal of image and graphics. Pub Date : 2025-01-01 Epub Date: 2025-06-12 DOI:10.18178/joig.13.3.275-285

M Mohsin Jadoon, Victor Torres-Lopez, Sharjeel A Butt, Santosh B Murthy, Guido J Falcone, Seyedmehdi Payabvash

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Abstract

Cerebral Microbleeds (CMBs) are referred to tiny foci of hemorrhage in brain parenchyma which are smaller than 5 (to 10) mm in size. The presence of CMBs is implicated in pathophysiology of cognitive impairment, dementia, radiation-induced vascular injury, traumatic brain injury, hypertensive microangiopathy, and aging. On brain Magnetic Resonance Imaging (MRI) scans, CMBs appear as hypointense foci, most notable on T2*-weighted or Susceptibility-Weighted Imaging (SWI). Detecting these tiny microbleeds with naked eye is a difficult and time-consuming task for radiologists. In this study we developed an algorithm for automatic detection of CMBs. We applied a two-step strategy: at first, we applied pre-processed 2D image dataset to You Only Look Once (YOLO V2) for detection of CMBs. Then, these detected CMBs locations are used to segment 3D patches from their original SWI volume in the datasets. Next, these patches are used as inputs for Convolution Neural Network (CNN). In the second step, we reduced the number of False Positives (FP) and improved our classification accuracy using 3D CNN. We used two datasets consisting of 979 patients: 879 of whom for training of models, and the remainder for independent validation. We were able to achieve an accuracy of 81% and reduce the $F P_{avg}$ to 0.16.

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基于3D CNN的脑微出血自动检测与分类。

脑微出血（CMBs）是指脑实质出血的微小病灶，其大小小于5（至10）mm。CMBs的存在与认知障碍、痴呆、辐射诱导的血管损伤、创伤性脑损伤、高血压微血管病和衰老的病理生理有关。在脑磁共振成像（MRI）扫描中，CMBs表现为低信号灶，在T2*加权或敏感性加权成像（SWI）上最明显。对于放射科医生来说，用肉眼检测这些微小的微出血是一项困难而耗时的任务。在这项研究中，我们开发了一种自动检测CMBs的算法。我们采用了两步策略：首先，我们将预处理的二维图像数据集应用于You Only Look Once （YOLO V2）中进行CMBs检测。然后，这些检测到的cmb位置用于从数据集中的原始SWI体积中分割3D斑块。接下来，这些patch被用作卷积神经网络（CNN）的输入。在第二步，我们减少了假阳性（FP）的数量，并使用3D CNN提高了我们的分类精度。我们使用了由979名患者组成的两个数据集：其中879名用于模型训练，其余用于独立验证。我们能够达到81%的精度，并将平均F值降低到0.16。

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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Journal of image and graphics.

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