Khagi Bijen, Belousova Tatiana, Short Christina M, Taylor Addison A, Bismuth Jean, Shah Dipan J, Brunner Gerd
Penn State Heart and Vascular Institute, College of Medicine, Pennsylvania State University, 500 University Drive H047, Hershey, PA, 17033, USA.
Methodist DeBakey Heart and Vascular Center, Houston Methodist Hospital, Houston, USA.
Sci Rep. 2025 Feb 10;15(1):4996. doi: 10.1038/s41598-025-87747-5.
Peripheral artery disease (PAD) remains underdiagnosed and undertreated and is associated with an increased risk for adverse cardiovascular outcomes. Imaging provides an approach to identifying patients with PAD. However, the role of integrating imaging with machine learning to identify PAD patients and potentially assess disease severity remains understudied. A total of 56 participants, including 36 PAD patients with intermittent claudication and 20 matched controls, underwent contrast-enhanced magnetic resonance imaging (CE-MRI) calf muscle perfusion scanning. CE-MRI-derived dynamic muscle perfusion maps were developed to quantify alterations of the microvascular circulation in the calf muscles based on voxel contrast enhancement. These dynamic muscle perfusion maps categorized voxels as hyper-, iso-, or hypo-enhanced and were generated for the anterior (AM), lateral (LM), and deep posterior (DM) muscle groups, and the soleus (SM) and gastrocnemius muscles (GM). An unsupervised block-search algorithm was developed to identify heterogeneous regions of interest based on homogeneity. Machine learning methods were utilized to classify PAD patients from controls, with subgroup analyses performed based on lower extremity function and diabetes. The hypo-enhanced and hyper-enhanced voxel percentages obtained from the dynamic muscle perfusion maps were used to train a decision tree classifier to distinguish PAD patients from controls. The two-group classifier obtained a leave-one-out cross-validation (LOOCV) F1-score of 87.6 and 76.7% with hyper-enhanced and hypo-enhanced perfusion features averaged over all muscle groups, respectively. Hypo-enhanced perfusion features, a marker of microvascular perfusion abnormalities, classified PAD patients who completed a 6-minute treadmill walking test compared to those who did not, with an LOOCV F1-score of 67.6%. Using the same method, hypo-enhanced perfusion features differentiated PAD patients with diabetes versus those without with an LOOCV F1-score of 70.3%. In conclusion, CE-MRI derived measures of skeletal calf muscle perfusion can be used with a decision tree classifier to differentiate PAD patients from matched controls. Machine learning can also identify PAD patients with lower exercise capacity and those with concomitant diabetes. Machine learning and CE-MRI derived measures of the calf microcirculation could be of interest in the study of PAD and disease severity.
外周动脉疾病(PAD)仍然诊断不足且治疗不充分,并且与不良心血管结局风险增加相关。影像学提供了一种识别PAD患者的方法。然而,将影像学与机器学习相结合以识别PAD患者并潜在评估疾病严重程度的作用仍未得到充分研究。共有56名参与者,包括36名患有间歇性跛行的PAD患者和20名匹配的对照,接受了对比增强磁共振成像(CE-MRI)小腿肌肉灌注扫描。基于体素对比增强,开发了源自CE-MRI的动态肌肉灌注图,以量化小腿肌肉微血管循环的改变。这些动态肌肉灌注图将体素分类为高增强、等增强或低增强,并针对前侧(AM)、外侧(LM)和深部后侧(DM)肌肉群以及比目鱼肌(SM)和腓肠肌(GM)生成。开发了一种无监督的块搜索算法,以基于同质性识别异质感兴趣区域。利用机器学习方法将PAD患者与对照进行分类,并根据下肢功能和糖尿病进行亚组分析。从动态肌肉灌注图获得的低增强和高增强体素百分比用于训练决策树分类器,以区分PAD患者与对照。两组分类器在所有肌肉群平均的高增强和低增强灌注特征下,留一法交叉验证(LOOCV)的F1分数分别为87.6%和76.7%。低增强灌注特征是微血管灌注异常的标志物,与未完成6分钟跑步机步行试验的PAD患者相比,对完成该试验的PAD患者进行分类,LOOCV的F1分数为67.6%。使用相同方法,低增强灌注特征区分了患有糖尿病的PAD患者与未患糖尿病的患者,LOOCV的F1分数为70.3%。总之,源自CE-MRI的小腿骨骼肌灌注测量可与决策树分类器一起用于区分PAD患者与匹配的对照。机器学习还可以识别运动能力较低的PAD患者和伴有糖尿病的患者。机器学习和源自CE-MRI的小腿微循环测量可能在PAD及其疾病严重程度的研究中具有重要意义。
