From the University of Toronto, Toronto.
McMaster University, Hamilton.
Clin Nucl Med. 2019 Oct;44(10):784-788. doi: 10.1097/RLU.0000000000002747.
To evaluate random forests (RFs) as a supervised machine learning algorithm to classify amyloid brain PET as positive or negative for amyloid deposition and identify key regions of interest for stratification.
The data set included 57 baseline F-florbetapir (Amyvid; Lilly, Indianapolis, IN) brain PET scans in participants with severe white matter disease, presenting with either transient ischemic attack/lacunar stroke or mild cognitive impairment from early Alzheimer disease, enrolled in a multicenter prospective observational trial. Scans were processed using the MINC toolkit to generate SUV ratios, normalized to cerebellar gray matter, and clinically read by 2 nuclear medicine physicians with interpretation based on consensus (35 negative, 22 positive). SUV ratio data and clinical reads were used for supervised training of an RF classifier programmed in MATLAB.
A 10,000-tree RF, each tree using 15 randomly selected cases and 20 randomly selected features (SUV ratio per region of interest), with 37 cases for training and 20 cases for testing, had sensitivity = 86% (95% confidence interval [CI], 42%-100%), specificity = 92% (CI, 64%-100%), and classification accuracy = 90% (CI, 68%-99%). The most common features at the root node (key regions for stratification) were (1) left posterior cingulate (1039 trees), (2) left middle frontal gyrus (1038 trees), (3) left precuneus (857 trees), (4) right anterior cingulate gyrus (655 trees), and (5) right posterior cingulate (588 trees).
Random forests can classify brain PET as positive or negative for amyloid deposition and suggest key clinically relevant, regional features for classification.
评估随机森林(RF)作为一种有监督的机器学习算法,以对淀粉样蛋白脑 PET 进行分类,判断是否存在淀粉样蛋白沉积,并确定分层的关键感兴趣区域。
该数据集包括 57 例处于严重脑白质疾病期的参与者的基线 F-氟比洛芬(Amyvid;印第安纳波利斯,Lilly)脑 PET 扫描,他们要么患有短暂性脑缺血发作/腔隙性卒中,要么患有早期阿尔茨海默病引起的轻度认知障碍,他们参与了一项多中心前瞻性观察性试验。扫描采用 MINC 工具包进行处理,生成 SUV 比值,用小脑灰质进行标准化,并由 2 名核医学医师进行临床解读,解读基于共识(35 例阴性,22 例阳性)。SUV 比值数据和临床解读用于在 MATLAB 中编程的 RF 分类器的监督训练。
一个 10000 棵树的 RF,每棵树使用 15 个随机选择的病例和 20 个随机选择的特征(每个感兴趣区域的 SUV 比值),其中 37 个病例用于训练,20 个病例用于测试,具有 86%的敏感性(95%置信区间[CI],42%-100%),92%的特异性(CI,64%-100%)和 90%的分类准确率(CI,68%-99%)。根节点(分层的关键区域)最常见的特征是:(1)左后扣带回(1039 棵树);(2)左额中回(1038 棵树);(3)左楔前叶(857 棵树);(4)右前扣带回(655 棵树);(5)右后扣带回(588 棵树)。
随机森林可以对脑 PET 进行分类,判断是否存在淀粉样蛋白沉积,并提示关键的、与临床相关的分类区域特征。
