Bahado-Singh Ray O, Vishweswaraiah Sangeetha, Aydas Buket, Yilmaz Ali, Saiyed Nazia M, Mishra Nitish K, Guda Chittibabu, Radhakrishna Uppala
Department of Obstetrics and Gynecology, Oakland University William Beaumont School of Medicine, Royal Oak, Michigan, USA.
Department of Mathematics & Computer Science, Albion College, Albion, Michigan, USA.
J Matern Fetal Neonatal Med. 2022 Feb;35(3):457-464. doi: 10.1080/14767058.2020.1722995. Epub 2020 Feb 4.
Advances in omics and computational Artificial Intelligence (AI) have been said to be key to meeting the objectives of precision cardiovascular medicine. The focus of precision medicine includes a better assessment of disease risk and understanding of disease mechanisms. Our objective was to determine whether significant epigenetic changes occur in isolated, non-syndromic CoA. Further, we evaluated the AI analysis of DNA methylation for the prediction of CoA.
Genome-wide DNA methylation analysis of newborn blood DNA was performed in 24 isolated, non-syndromic CoA cases and 16 controls using the Illumina HumanMethylation450 BeadChip arrays. Cytosine nucleotide (CpG) methylation changes in CoA in each of 450,000 CpG loci were determined. Ingenuity pathway analysis (IPA) was performed to identify molecular and disease pathways that were epigenetically dysregulated. Using methylation data, six artificial intelligence (AI) platforms including deep learning (DL) was used for CoA detection.
We identified significant (FDR -value ≤ .05) methylation changes in 65 different CpG sites located in 75 genes in CoA subjects. DL achieved an AUC (95% CI) = 0.97 (0.80-1) with 95% sensitivity and 98% specificity. Gene ontology (GO) analysis yielded epigenetic alterations in important cardiovascular developmental genes and biological processes: abnormal morphology of cardiovascular system, left ventricular dysfunction, heart conduction disorder, thrombus formation, and coronary artery disease.
In an exploratory study we report the use of AI and epigenomics to achieve important objectives of precision cardiovascular medicine. Accurate prediction of CoA was achieved using a newborn blood spot. Further, we provided evidence of a significant epigenetic etiology in isolated CoA development.
有人认为组学和计算人工智能(AI)的进展是实现精准心血管医学目标的关键。精准医学的重点包括更好地评估疾病风险和理解疾病机制。我们的目标是确定在孤立的、非综合征性主动脉缩窄(CoA)中是否发生显著的表观遗传变化。此外,我们评估了用于预测CoA的DNA甲基化的AI分析。
使用Illumina HumanMethylation450 BeadChip芯片对24例孤立的、非综合征性CoA病例和16例对照的新生儿血液DNA进行全基因组DNA甲基化分析。确定了450,000个CpG位点中每个位点在CoA中的胞嘧啶核苷酸(CpG)甲基化变化。进行了 Ingenuity 通路分析(IPA)以识别表观遗传失调的分子和疾病通路。使用甲基化数据,包括深度学习(DL)在内的六个人工智能(AI)平台用于CoA检测。
我们在CoA受试者中位于75个基因的65个不同CpG位点鉴定出显著(FDR值≤0.05)的甲基化变化。DL的AUC(95%CI)=0.97(0.80-1),灵敏度为95%,特异性为98%。基因本体(GO)分析在重要的心血管发育基因和生物学过程中产生了表观遗传改变:心血管系统形态异常、左心室功能障碍、心脏传导障碍、血栓形成和冠状动脉疾病。
在一项探索性研究中,我们报告了使用AI和表观基因组学来实现精准心血管医学的重要目标。使用新生儿血斑实现了对CoA的准确预测。此外,我们提供了孤立性CoA发育中显著表观遗传病因的证据。
