Tracking calcium dynamics from individual neurons in behaving animals

Thibault Lagache; Alison Hanson; Jesús E Pérez-Ortega; Adrienne Fairhall; Rafael Yuste

doi:10.1371/journal.pcbi.1009432

Back

Tracking calcium dynamics from individual neurons in behaving animals

Journal article

Peer reviewed

Tracking calcium dynamics from individual neurons in behaving animals

Thibault Lagache, Alison Hanson, Jesús E Pérez-Ortega, Adrienne Fairhall and Rafael Yuste

PLoS computational biology, Vol.17(10), pp.e1009432-e1009432

10/01/2021

DOI: 10.1371/journal.pcbi.1009432

PMCID: PMC8528277

PMID: 34624016

View Online

Abstract

Measuring the activity of neuronal populations with calcium imaging can capture emergent functional properties of neuronal circuits with single cell resolution. However, the motion of freely behaving animals, together with the intermittent detectability of calcium sensors, can hinder automatic monitoring of neuronal activity and their subsequent functional characterization. We report the development and open-source implementation of a multi-step cellular tracking algorithm (Elastic Motion Correction and Concatenation or EMC2) that compensates for the intermittent disappearance of moving neurons by integrating local deformation information from detectable neurons. We demonstrate the accuracy and versatility of our algorithm using calcium imaging data from two-photon volumetric microscopy in visual cortex of awake mice, and from confocal microscopy in behaving Hydra, which experiences major body deformation during its contractions. We quantify the performance of our algorithm using ground truth manual tracking of neurons, along with synthetic time-lapse sequences, covering a wide range of particle motions and detectability parameters. As a demonstration of the utility of the algorithm, we monitor for several days calcium activity of the same neurons in layer 2/3 of mouse visual cortex in vivo, finding significant turnover within the active neurons across days, with only few neurons that remained active across days. Also, combining automatic tracking of single neuron activity with statistical clustering, we characterize and map neuronal ensembles in behaving Hydra, finding three major non-overlapping ensembles of neurons (CB, RP1 and RP2) whose activity correlates with contractions and elongations. Our results show that the EMC2 algorithm can be used as a robust and versatile platform for neuronal tracking in behaving animals.

Algorithms

Animals

Behavior, Animal - physiology

Calcium - metabolism

Cell Tracking - methods

Computational Biology

Mice

Neurons - cytology

Neurons - metabolism

Visual Cortex - cytology

Visual Cortex - diagnostic imaging

Visual Cortex - physiology

Details

Title: Subtitle: Tracking calcium dynamics from individual neurons in behaving animals
Creators: Thibault Lagache - Marine Biological Laboratory
Alison Hanson - Columbia University
Jesús E Pérez-Ortega - Columbia University
Adrienne Fairhall - University of Washington
Rafael Yuste - Donostia International Physics Center
Resource Type: Journal article
Publication Details: PLoS computational biology, Vol.17(10), pp.e1009432-e1009432
DOI: 10.1371/journal.pcbi.1009432
PMID: 34624016
PMCID: PMC8528277
NLM abbreviation: PLoS Comput Biol
ISSN: 1553-7358
eISSN: 1553-7358
Grant note: R01 EY011787 / NEI NIH HHS R01 MH115900 / NIMH NIH HHS T32 MH018870 / NIMH NIH HHS
Language: English
Date published: 10/01/2021
Academic Unit: Psychiatry
Record Identifier: 9984822992502771

Metrics

4 Record Views

21 Times Cited - Web of Science

See more details