Deep learning assisted cancer disease prediction from gene expression data using WT-GAN.

IF 4.3 3区 材料科学 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC
U Ravindran, C Gunavathi
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Abstract

Several diverse fields including the healthcare system and drug development sectors have benefited immensely through the adoption of deep learning (DL), which is a subset of artificial intelligence (AI) and machine learning (ML). Cancer makes up a significant percentage of the illnesses that cause early human mortality across the globe, and this situation is likely to rise in the coming years, especially when non-communicable illnesses are not considered. As a result, cancer patients would greatly benefit from precise and timely diagnosis and prediction. Deep learning (DL) has become a common technique in healthcare due to the abundance of computational power. Gene expression datasets are frequently used in major DL-based applications for illness detection, notably in cancer therapy. The quantity of medical data, on the other hand, is often insufficient to fulfill deep learning requirements. Microarray gene expression datasets are used for training procedures despite their extreme dimensionality, limited volume of data samples, and sparsely available information. Data augmentation is commonly used to expand the training sample size for gene data. The Wasserstein Tabular Generative Adversarial Network (WT-GAN) model is used for the data augmentation process for generating synthetic data in this proposed work. The correlation-based feature selection technique selects the most relevant characteristics based on threshold values. Deep FNN and ML algorithms train and classify the gene expression samples. The augmented data give better classification results (> 97%) when using WT-GAN for cancer diagnosis.

利用 WT-GAN 从基因表达数据中进行深度学习辅助癌症疾病预测。
深度学习是人工智能(AI)和机器学习(ML)的一个子集,包括医疗保健系统和药物开发部门在内的多个领域都因采用深度学习而受益匪浅。在全球导致人类早期死亡的疾病中,癌症占了很大比例,而且这种情况在未来几年可能还会上升,尤其是在不考虑非传染性疾病的情况下。因此,精确、及时的诊断和预测将使癌症患者受益匪浅。由于计算能力丰富,深度学习(DL)已成为医疗保健领域的常用技术。基因表达数据集经常被用于基于深度学习的主要疾病检测应用中,尤其是癌症治疗中。另一方面,医疗数据的数量往往不足以满足深度学习的要求。微阵列基因表达数据集尽管维度极高、数据样本量有限、可用信息稀少,但仍被用于训练程序。数据扩增通常用于扩大基因数据的训练样本规模。在本研究中,数据扩增过程中使用了 Wasserstein 表生成对抗网络(WT-GAN)模型来生成合成数据。基于相关性的特征选择技术根据阈值选择最相关的特征。深度 FNN 和 ML 算法对基因表达样本进行训练和分类。在使用 WT-GAN 进行癌症诊断时,增强数据能提供更好的分类结果(> 97%)。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
7.20
自引率
4.30%
发文量
567
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