TL;DR
This paper systematically evaluates recent graph embedding methods on biomedical networks, demonstrating their effectiveness in various biomedical link prediction and node classification tasks without relying on biological features.
Contribution
It provides a comprehensive comparison of 11 graph embedding methods on biomedical tasks, offering guidelines for their selection and hyper-parameter tuning.
Findings
Recent graph embedding methods achieve competitive results in biomedical tasks.
Embeddings can complement traditional biological features.
Guidelines for method selection and hyper-parameter tuning are provided.
Abstract
Graph embedding learning that aims to automatically learn low-dimensional node representations, has drawn increasing attention in recent years. To date, most recent graph embedding methods are evaluated on social and information networks and are not comprehensively studied on biomedical networks under systematic experiments and analyses. On the other hand, for a variety of biomedical network analysis tasks, traditional techniques such as matrix factorization (which can be seen as a type of graph embedding methods) have shown promising results, and hence there is a need to systematically evaluate the more recent graph embedding methods (e.g. random walk-based and neural network-based) in terms of their usability and potential to further the state-of-the-art. We select 11 representative graph embedding methods and conduct a systematic comparison on 3 important biomedical link prediction…
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