Multi-Omics Data Fusion for Cancer Molecular Subtyping Using Sparse Canonical Correlation Analysis

Lin, Qi; Wang, Wei; Wu, Tan; Zhu, Lina; He, Lingli; Wang, Xin

doi:10.3389/fgene.2021.607817

Cited by 15 publications

(10 citation statements)

References 54 publications

(80 reference statements)

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“…Lin et al proposed a cancer classification sparse canonical correlation analysis (SCCA-CC), in which each type of univariate data is projected into a unified space for data fusion and then clustering and classification analysis are performed. The findings demonstrate that SCCA-CC has distinct advantages in classifying multi-omics data [12].…”

Section: 、Introductionmentioning

confidence: 82%

Explore the prognostic characteristics of immunogenic cell death- related genes in colon carcinoma based on multi-constraint canonical correlation analysis

Xiong

Cao

Tang

et al. 2023

Preprint

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The prognosis for colon carcinoma is poor, it is a highly aggressive tumor, and its early symptoms are subtle. Hence, the need for more colon cancer prognostic indicators is urgent. Many long non-coding RNAs (lncRNAs) are known to actively contribute to the detection, prognosis, and treatment of tumors. On the other hand, immunogenic cell death (ICD) is vital for the prevention of tumors. This study seeks to research the mechanism of action of ICD-related lncRNAs in colon cancer and integrate ICD-related genes with lncRNAs. In order to investigate ICD-related lncRNAs, this research suggests a multi-constraint canonical correlation analysis. The prognostic model of the most significant lncRNAs is also constructed and verified in this paper using univariate and Lasso-Cox regression. In this study, colon cancer samples are split into high-risk and low-risk groups based on the model's risk score, and the impact of the model is assessed using the TCGA queue and the GEO queue, respectively. Also, we thoroughly examined the parallels and discrepancies in immune infiltration, functional enrichment, and medication sensitivity across the two risk groups. In conclusion, the ICD-related lncRNAs risk model developed in this research can serve as a guide for predicting the prognosis and therapeutic sensitivity of colon cancer patients.

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Section: 、Introductionmentioning

confidence: 82%

Explore the prognostic characteristics of immunogenic cell death- related genes in colon carcinoma based on multi-constraint canonical correlation analysis

Xiong

Cao

Tang

et al. 2023

Preprint

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“…Next, they took the average of these matrices as a fused matrix and applied it to a spectral clustering algorithm for cancer subtype discovery. Qi et al (2021) proposed a sparse canonical correlation analysis for cancer classification where each single omics data is first projected into a unified space and then integrated by weighted averaging strategy. Multiple kernel learning (MKL) is an extension to kernel support vector machine (SVM) which has received great popularity in the omics integration field ( Gönen and Alpaydin, 2011 ).…”

Section: Introductionmentioning

confidence: 99%

Pancancer survival prediction using a deep learning architecture with multimodal representation and integration

Fan

Jiang

Liang³

et al. 2023

Bioinformatics Advances

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Motivation Use of multi-omics data carrying comprehensive signals about the disease is strongly desirable for understanding and predicting disease progression, cancer particularly as a serious disease with a high mortality rate. However, recent methods currently fail to effectively utilize the multi-omics data for cancer survival prediction and thus significantly limiting the accuracy of survival prediction using omics data. Results In this work, we constructed a deep learning model with multimodal representation and integration to predict the survival of patients using multi-omics data. We first developed an unsupervised learning part to extract high-level feature representations from omics data of different modalities. Then, we employed an attention-based method to integrate feature representations, produced by the unsupervised learning part, into a single compact vector and finally we fed the vector into fully connected layers for survival prediction. We used multimodal data to train the model and predict pancancer survival, and the results show that using multimodal data can lead to higher prediction accuracy compared to using single modal data. Furthermore, we used the concordance index and the 5-fold cross-validation method for comparing our proposed method with current state-of-the-art methods and our results show that our model achieves better performance on the majority of cancer types in our testing datasets. Availability https://github.com/ZhangqiJiang07/MultimodalSurvivalPrediction

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“…Recent advances in high-throughput technologies, particularly next-generation sequencing, have been allowing the extraction of an increasing quantity of biological data, which is not limited to one but instead includes multiple omics modalities collected from the same individuals. The joint integrative study of the different but linked layers of genetic regulation (e.g., genome, epigenome, transcriptome, proteome, metabolome) offers an opportunity to build a more comprehensive landscape of biological systems and further enhance the molecular understanding of disease, where research has relied mostly on single-omics data [9].…”

Section: Introductionmentioning

confidence: 99%

Integration of Multi-omics Data for the Classification of Glioma Types and Identification of Novel Biomarkers

Vieira,

Bispo,

Lopes

2023

Preprint

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Glioma is currently one of the most prevalent types of primary brain cancer. Given its high level of heterogeneity along with the complex biological molecular markers, many efforts have been made to accurately classify the type of glioma in each patient, which, in turn, is critical to improve early diagnosis and increase survival. Nonetheless, as a result of the fast-growing technological advances in high throughput sequencing and evolving molecular understanding of glioma biology, its classification has been recently subject to significant alterations. In this study, we integrate multiple glioma omics modalities (including mRNA, DNA methylation, and miRNA) from The Cancer Genome Atlas (TCGA), while using the revised glioma reclassified labels, with a supervised method based on sparse canonical correlation analysis (DIABLO) to discriminate between glioma types. We were able to find a set of highly correlated features distinguishing glioblastoma from lower-grade gliomas (LGG) that were mainly associated with the disruption of receptor tyrosine kinases signaling pathways and extracellular matrix organization and remodeling. On the other hand, the discrimination of the LGG types was characterized primarily by features involved in ubiquitination and DNA transcription processes. Furthermore, we could identify several novel glioma biomarkers likely helpful in both diagnosis and prognosis of the patients, including the genesPPP1R8, GPBP1L1, KIAA1614, C14orf23, CCDC77, BVES, EXD3, CD300AandHEPN1. Overall, this classification method allowed to discriminate the different TCGA glioma patients with very high performance, while seeking for common information across multiple data types, ultimately enabling the understanding of essential mechanisms driving glioma heterogeneity and unveiling potential therapeutic targets.

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Multi-Omics Data Fusion for Cancer Molecular Subtyping Using Sparse Canonical Correlation Analysis

Cited by 15 publications

References 54 publications

Explore the prognostic characteristics of immunogenic cell death- related genes in colon carcinoma based on multi-constraint canonical correlation analysis

Explore the prognostic characteristics of immunogenic cell death- related genes in colon carcinoma based on multi-constraint canonical correlation analysis

Pancancer survival prediction using a deep learning architecture with multimodal representation and integration

Integration of Multi-omics Data for the Classification of Glioma Types and Identification of Novel Biomarkers

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