DOI: 10.1002/nep3.70047 ISSN: 2770-7296

An open‐source pipeline for longitudinal single‐cell tracking and cell‐cycle/migration coupling analysis for neurotherapeutic screening

Neha Chandra, Matthew Yang, Hailey Wang, Miroslaw Janowski, Piotr Walczak, Cedric Allier, Yajie Liang

Abstract

Background

Imaging‐based phenotypic assays are widely used in neuroprotection, drug discovery, and neurorepair studies, but long‐term, high‐throughput time‐lapse datasets remain difficult to analyze because of segmentation noise, photobleaching, crowded fields, cell division, and tracking errors. Fluorescent ubiquitination‐based cell cycle indicator (FUCCI) reporters enable live visualization of cell‐cycle phases, but their integration with migration behaviors remains limited. This study aimed to developed an open workflow for tracking cycle and motility

Methods

We combined Fiji/ImageJ preprocessing, Cellpose‐based deep learning segmentation, and TrackMate‐based cell tracking. FUCCI‐expressing HEK293 cells were imaged using a Tecan Spark Cyto (Männedorf, Switzerland) every 15 min for 24 h. Cellpose models were retrained using manually corrected masks from brightfield and fluorescence images, and TrackMate parameters were optimized using manually curated tracks. Statistical analyses were conducted using Paleontological Statistics (PAST) software (version 4.0, Natural History Museum, University of Oslo, Oslo, Norway).

Results

Iterative cellpose retraining improved segmentation accuracy in both brightfield and fluorescent datasets by reducing false‐positive and false‐negative errors (Brightfield Type I error improvement: t (10) = 33.323, p  = 1.400 × 10 −11 , Brightfield Type II error improvement: t (10) = 16.066, p  = 1.805 × 10 −8 , Fluorescent Type II errors: U  = 0, p  = 0.00077). TrackMate optimization improved trajectory continuity, especially through adjustment of frame‐to‐frame linking distances (Brightfield: χ 2 (2) = 10, p  = 0.00077, Fluorescent: χ 2 (2) = 10, p  = 0.00077). The workflow enabled single‐cell and population‐level analysis of migration distance, turning behavior, morphology, division events, and FUCCI‐defined cell‐cycle progression. Cells showed heterogeneous motility, with lower displacement trends during green‐dominant S/G2/M phases than red‐dominant G1 phases.

Conclusion

This workflow links cell‐cycle state with migration dynamics and can be adapted for neuroprotective screening, neural cultures, organoids, and neuron–glia co‐culture studies.

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