Litcius/Paper detail

Deciphering anomalous heterogeneous intracellular transport with neural networks

Daniel Han, Nickolay Korabel, Runze Chen, Mark Johnston, Anna Gavrilova, Viki Allan, Sergei Fedotov, Thomas Andrew Waigh

2020eLife75 citationsDOIOpen Access PDF

Abstract

Intracellular transport is predominantly heterogeneous in both time and space, exhibiting varying non-Brownian behavior. Characterization of this movement through averaging methods over an ensemble of trajectories or over the course of a single trajectory often fails to capture this heterogeneity. Here, we developed a deep learning feedforward neural network trained on fractional Brownian motion, providing a novel, accurate and efficient method for resolving heterogeneous behavior of intracellular transport in space and time. The neural network requires significantly fewer data points compared to established methods. This enables robust estimation of Hurst exponents for very short time series data, making possible direct, dynamic segmentation and analysis of experimental tracks of rapidly moving cellular structures such as endosomes and lysosomes. By using this analysis, fractional Brownian motion with a stochastic Hurst exponent was used to interpret, for the first time, anomalous intracellular dynamics, revealing unexpected differences in behavior between closely related endocytic organelles.

Topics & Concepts

Hurst exponentFractional Brownian motionBrownian motionTrajectoryArtificial neural networkComputer scienceBiological systemEndocytic cycleStatistical physicsPhysicsArtificial intelligenceMathematicsBiologyEndocytosisStatisticsAstronomyQuantum mechanicsGeneticsCellPlant Water Relations and Carbon DynamicsLipid Membrane Structure and BehaviorPlant Molecular Biology Research