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TinGa: fast and flexible trajectory inference with Growing Neural Gas

Helena Todorov, Robrecht Cannoodt, Wouter Saelens, Yvan Saeys

2020Bioinformatics32 citationsDOIOpen Access PDF

Abstract

MOTIVATION: During the last decade, trajectory inference (TI) methods have emerged as a novel framework to model cell developmental dynamics, most notably in the area of single-cell transcriptomics. At present, more than 70 TI methods have been published, and recent benchmarks showed that even state-of-the-art methods only perform well for certain trajectory types but not others. RESULTS: In this work, we present TinGa, a new TI model that is fast and flexible, and that is based on Growing Neural Graphs. We performed an extensive comparison of TinGa to five state-of-the-art methods for TI on a set of 250 datasets, including both synthetic as well as real datasets. Overall, TinGa improves the state-of-the-art by producing accurate models (comparable to or an improvement on the state-of-the-art) on the whole spectrum of data complexity, from the simplest linear datasets to the most complex disconnected graphs. In addition, TinGa obtained the fastest execution times, showing that our method is thus one of the most versatile methods up to date. AVAILABILITY AND IMPLEMENTATION: R scripts for running TinGa, comparing it to top existing methods and generating the figures of this article are available at https://github.com/Helena-todd/TinGa.

Topics & Concepts

TrajectoryComputer scienceScripting languageSet (abstract data type)InferenceState (computer science)Artificial intelligenceData miningMachine learningAlgorithmTheoretical computer scienceProgramming languagePhysicsAstronomySingle-cell and spatial transcriptomicsCell Image Analysis TechniquesMachine Learning in Bioinformatics
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