Department of Data Science and Engineering, Silesian University of Technology, Akademicka 16, 44-100, Gliwice, Poland.
State Key Laboratory of Genetic Engineering, Human Phenome Institute, School of Life Sciences, Fudan University, Songhu Road, 2005, Shanghai, China; Taizhou Institute of Health Sciences, Fudan University, Yaocheng Road 799, Taizhou, Jiangsu, China.
Comput Biol Med. 2022 Dec;151(Pt A):106233. doi: 10.1016/j.compbiomed.2022.106233. Epub 2022 Oct 27.
Cerebral microbleeds (CMBs) are gaining increasing interest due to their importance in diagnosing cerebral small vessel diseases. However, manual inspection of CMBs is time-consuming and prone to human error. Existing automated or semi-automated solutions still have insufficient detection sensitivity and specificity. Furthermore, they frequently use more than one magnetic resonance imaging modality, but these are not always available. The majority of AI-based solutions use either numeric or image data, which may not provide sufficient information about the true nature of CMBs. This paper proposes a deep neural network with multi-type input data for automated CMB detection (CMB-HUNT) using only susceptibility-weighted imaging data (SWI). Combination of SWIs and radiomic-type numerical features allowed us to identify CMBs with high accuracy without the need for additional imaging modalities or complex predictive models. Two independent datasets were used: one with 304 patients (39 with CMBs) for training and internal system validation and one with 61 patients (21 with CMBs) for external validation. For the hold-out testing dataset, CMB-HUNT reached a sensitivity of 90.0%. As results of testing showed, CMB-HUNT outperforms existing methods in terms of the number of FPs per case, which is the lowest reported thus far (0.54 FPs/patient). The proposed system was successfully applied to the independent validation set, reaching a sensitivity of 91.5% with 1.9 false positives per patient and proving its generalization potential. The results were comparable to previous studies. Our research confirms the usefulness of deep learning solutions for CMB detection based only on one MRI modality.
脑微出血(CMB)因其在诊断脑小血管疾病中的重要性而引起越来越多的关注。然而,CMB 的手动检查既费时又容易出错。现有的自动化或半自动解决方案仍然存在检测灵敏度和特异性不足的问题。此外,它们经常使用超过一种磁共振成像模式,但这些模式并非总是可用。大多数基于人工智能的解决方案使用数字或图像数据,但这些数据可能无法提供有关 CMB 真实性质的足够信息。本文提出了一种使用仅磁化率加权成像数据(SWI)进行自动 CMB 检测的多类型输入数据的深度神经网络(CMB-HUNT)。SWI 与放射组学类型的数值特征相结合,使我们能够在无需额外成像模式或复杂预测模型的情况下,以高精度识别 CMB。我们使用了两个独立的数据集:一个包含 304 名患者(39 名有 CMB)的数据集用于训练和内部系统验证,另一个包含 61 名患者(21 名有 CMB)的数据集用于外部验证。对于保留测试数据集,CMB-HUNT 的灵敏度达到 90.0%。测试结果表明,CMB-HUNT 在每个病例的 FP 数方面优于现有方法,这是迄今为止报告的最低值(0.54 FP/患者)。该系统成功应用于独立验证集,灵敏度达到 91.5%,每个患者有 1.9 个假阳性,证明了其泛化能力。结果与之前的研究相当。我们的研究证实了基于单一 MRI 模式的深度学习解决方案在 CMB 检测中的有用性。
