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Pathologic Intimal Thickening Plaque Phenotype: Not as Innocent as Previously Thought. A Serial 3D Intravascular Ultrasound Virtual Histology Study.病理性内膜增厚斑块表型:并非如先前认为的那般无害。一项三维血管内超声虚拟组织学系列研究
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Impact of statin therapy on coronary plaque composition: a systematic review and meta-analysis of virtual histology intravascular ultrasound studies.他汀类药物治疗对冠状动脉斑块成分的影响:虚拟组织学血管内超声研究的系统评价和荟萃分析
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The vulnerable atherosclerotic plaque: in vivo identification and potential therapeutic avenues.易损性动脉粥样硬化斑块:体内识别与潜在治疗途径
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Robustness-Driven Feature Selection in Classification of Fibrotic Interstitial Lung Disease Patterns in Computed Tomography Using 3D Texture Features.基于 3D 纹理特征的计算机断层扫描肺纤维化间质性肺病模式分类中的稳健性驱动特征选择。
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Science. 2015 Jul 17;349(6245):255-60. doi: 10.1126/science.aaa8415.
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Imaging plaques to predict and better manage patients with acute coronary events.通过影像学检查斑块以预测和更好地管理急性冠脉事件患者。
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预测接受他汀类药物治疗的患者冠状动脉中高危斑块的位置。

Predicting Locations of High-Risk Plaques in Coronary Arteries in Patients Receiving Statin Therapy.

出版信息

IEEE Trans Med Imaging. 2018 Jan;37(1):151-161. doi: 10.1109/TMI.2017.2725443. Epub 2017 Jul 11.

DOI:10.1109/TMI.2017.2725443
PMID:28708548
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5765985/
Abstract

Features of high-risk coronary artery plaques prone to major adverse cardiac events (MACE) were identified by intravascular ultrasound (IVUS) virtual histology (VH). These plaque features are: thin-cap fibroatheroma (TCFA), plaque burden PB ≥ 70%, or minimal luminal area MLA ≤ 4 mm. Identification of arterial locations likely to later develop such high-risk plaques may help prevent MACE. We report a machine learning method for prediction of future high-risk coronary plaque locations and types in patients under statin therapy. Sixty-one patients with stable angina on statin therapy underwent baseline and one-year follow-up VH-IVUS non-culprit vessel examinations followed by quantitative image analysis. For each segmented and registered VH-IVUS frame pair ( ), location-specific ( mm) vascular features and demographic information at baseline were identified. Seven independent support vector machine classifiers with seven different feature subsets were trained to predict high-risk plaque types one year later. A leave-one-patient-out cross-validation was used to evaluate the prediction power of different feature subsets. The experimental results showed that our machine learning method predicted future TCFA with correctness of 85.9%, 81.7%, and 77.0% (G-mean) for baseline plaque phenotypes of TCFA, thick-cap fibroatheroma, and non-fibroatheroma, respectively. For predicting PB ≥ 70%, correctness was 80.8% for baseline PB ≥ 70% and 85.6% for 50% ≤ PB < 70%. Accuracy of predicted MLA ≤ 4 mm was 81.6% for baseline MLA ≤ 4 mm and 80.2% for 4 mm < MLA ≤ 6 mm. Location-specific prediction of future high-risk coronary artery plaques is feasible through machine learning using focal vascular features and demographic variables. Our approach outperforms previously reported results and shows the importance of local factors on high-risk coronary artery plaque development.

摘要

采用血管内超声(IVUS)虚拟组织学(VH)识别易发生重大不良心脏事件(MACE)的高危冠状动脉斑块特征。这些斑块特征包括:薄帽纤维粥样斑块(TCFA)、斑块负荷 PB≥70%,或最小管腔面积 MLA≤4mm。识别可能会发生此类高危斑块的动脉位置有助于预防 MACE。我们报告了一种用于预测他汀类药物治疗患者未来高危冠状动脉斑块位置和类型的机器学习方法。61 例稳定型心绞痛他汀类药物治疗患者接受基线和一年随访的非罪犯血管 VH-IVUS 检查,随后进行定量图像分析。对于每对分段和注册的 VH-IVUS 帧(),在基线时确定位置特异性(mm)血管特征和人口统计学信息。使用七种不同的特征子集训练了七个独立的支持向量机分类器,以预测一年后高危斑块类型。采用留一患者交叉验证评估不同特征子集的预测能力。实验结果表明,我们的机器学习方法预测未来 TCFA 的正确率分别为 85.9%、81.7%和 77.0%(G-mean),对于基线 TCFA、厚帽纤维粥样斑块和非纤维粥样斑块的斑块表型分别为 81.7%和 77.0%。对于预测 PB≥70%,基线 PB≥70%的正确率为 80.8%,50%≤PB<70%的正确率为 85.6%。预测 MLA≤4mm 的准确率分别为基线 MLA≤4mm 的 81.6%和 4mm<MLA≤6mm 的 80.2%。通过使用局灶性血管特征和人口统计学变量进行机器学习,可以对未来高危冠状动脉斑块进行位置特异性预测。我们的方法优于以前的报告结果,表明局部因素对高危冠状动脉斑块形成的重要性。