Abstract
Identifying relevant disease modules such as target cell types is a significant step for studying diseases. High-throughput single-cell RNA-Seq (scRNA-seq) technologies have advanced in recent years, enabling researchers to investigate cells individually and understand their biological mechanisms. Computational techniques such as clustering, are the most suitable approach in scRNA-seq data analysis when the cell types have not been well-characterized. These techniques can be used to identify a group of genes that belong to a specific cell type based on their similar gene expression patterns. However, due to the sparsity and high-dimensionality of scRNA-seq data, classical clustering methods are not efficient. Therefore, the use of non-linear dimensionality reduction techniques to improve clustering results is crucial. We introduce a method that is used to identify representative clusters of different cell types by combining non-linear dimensionality reduction techniques and clustering algorithms. We assess the impact of different dimensionality reduction techniques combined with the clustering of thirteen publicly available scRNA-seq datasets of different tissues, sizes, and technologies. We further performed gene set enrichment analysis to evaluate the proposed method’s performance. As such, our results show that modified locally linear embedding combined with independent component analysis yields overall the best performance relative to the existing unsupervised methods across different datasets.
Highlights
Identifying relevant disease modules such as target cell types is a significant step for studying diseases
We developed a well-constructed pipeline that can be applied to scRNA-seq data to discover individual cell types
We found optimal parameters for both dimensionality reduction and clustering that achieve the meaningful separation of cell types and compact clusters
Summary
Identifying relevant disease modules such as target cell types is a significant step for studying diseases. High-throughput single-cell RNA-Seq (scRNA-seq) technologies have advanced in recent years, enabling researchers to investigate cells individually and understand their biological mechanisms Computational techniques such as clustering, are the most suitable approach in scRNAseq data analysis when the cell types have not been well-characterized. Arranging cells into clusters to find the data’s heterogeneity is arguably the most significant step of any scRNA-seq data downstream analysis This step could be used to distinguish tissue-specific sub-types based on identified gene sets. The hierarchical clustering algorithm divides large clusters into smaller ones or progressively merges each data point into larger clusters This algorithm has been employed to analyze scRNA-seq data by BackSPIN8 and pcaReduce[9], through dimensionality reduction after each division or combination in an iterative manner. The authors o f11 used the Louvain algorithm, which is based on community detection techniques to analyze complex n etworks[12]
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
