Towards multiple kernel principal component analysis for integrative analysis of tumor samples
This work addresses the need for better integrative analysis of tumor samples to improve personalized cancer treatment, though it appears incremental as it builds on existing kernel PCA methods.
The authors tackled the problem of integrating multiple data sources for cancer subtype identification by proposing an unsupervised multiple kernel principal component analysis method with a scoring function to weigh each data source, and demonstrated its advantages on five cancer datasets.
Personalized treatment of patients based on tissue-specific cancer subtypes has strongly increased the efficacy of the chosen therapies. Even though the amount of data measured for cancer patients has increased over the last years, most cancer subtypes are still diagnosed based on individual data sources (e.g. gene expression data). We propose an unsupervised data integration method based on kernel principal component analysis. Principal component analysis is one of the most widely used techniques in data analysis. Unfortunately, the straight-forward multiple-kernel extension of this method leads to the use of only one of the input matrices, which does not fit the goal of gaining information from all data sources. Therefore, we present a scoring function to determine the impact of each input matrix. The approach enables visualizing the integrated data and subsequent clustering for cancer subtype identification. Due to the nature of the method, no free parameters have to be set. We apply the methodology to five different cancer data sets and demonstrate its advantages in terms of results and usability.