Machine learning-assisted quantification of organelle abundance
Machine learning-assisted quantification of organelle abundance
Organelle abundance is a key microscopic readout of organelle formation and, in many cases, function. Quantification of organelle abundance using confocal microscopy requires estimating their area based on the fluorescence intensity of compartment-specific markers. This analysis usually depends on a user-defined intensity threshold to distinguish organelle regions from the surrounding cytoplasm, which introduces potential bias and variability. To address this issue, we present a machine learning-assisted algorithm that allows for the quantification of organelle density using the open-source Fiji platform and WEKA segmentation. Our method enables the automated quantification of organelle number, area, and density by learning from training data. This standardizes threshold selection and minimizes user intervention. We demonstrate the utility of this approach for both membrane and non-membrane organelles, such as peroxisomes, lipid droplets, and stress granules, in human cells and whole fish samples. Key features • The organelle abundance algorithm is an automated, open-source, Fiji-based tool that extracts organelle number and area and calculates abundance based on a single marker. • The macro measures the average intensity of all the segmented areas and quantifies their area. • The algorithm is applicable to cellular compartments, including membrane-bound and membrane-less organelles. • The training is performed on a sample dataset, enabling the algorithm to be applied to all images obtained with the same imaging parameters.
Abundance, Density, Fiji, Machine learning, Organelle, PeroxiSPY, Peroxisome, Quantification, Stress granule, WEKA segmentation
Long, Alexander James
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Candeias, Diogo
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Coveña, Nicki Frederick
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Reymond, Luc
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Schuhmacher, Milena
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Kemp, Stephan
2e2cc7d8-4e1c-4393-b4bf-f25c5df9fe5b
Hamilton, Noémie
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Amen, Triana
388dc540-e819-4d07-8f1e-ee0f3949a54b
5 March 2026
Long, Alexander James
62c8ce35-361e-4e3e-a59f-874388d75d3a
Candeias, Diogo
ac0f62fa-1baa-4f0f-bcaa-fb36ccce9eb2
Coveña, Nicki Frederick
ddddae7a-5c51-45f4-908e-3bbf47c45eaa
Reymond, Luc
9e7a8adb-3553-4b10-ba71-5f2225c00a7c
Schuhmacher, Milena
3168a43b-4011-4819-bd13-6fda8df901a7
Kemp, Stephan
2e2cc7d8-4e1c-4393-b4bf-f25c5df9fe5b
Hamilton, Noémie
263e8a45-59b3-41c3-be95-223ee369252c
Amen, Triana
388dc540-e819-4d07-8f1e-ee0f3949a54b
Long, Alexander James, Candeias, Diogo, Coveña, Nicki Frederick, Reymond, Luc, Schuhmacher, Milena, Kemp, Stephan, Hamilton, Noémie and Amen, Triana
(2026)
Machine learning-assisted quantification of organelle abundance.
Bio-protocol, 16 (5), [e5626].
(doi:10.21769/BioProtoc.5626).
Abstract
Organelle abundance is a key microscopic readout of organelle formation and, in many cases, function. Quantification of organelle abundance using confocal microscopy requires estimating their area based on the fluorescence intensity of compartment-specific markers. This analysis usually depends on a user-defined intensity threshold to distinguish organelle regions from the surrounding cytoplasm, which introduces potential bias and variability. To address this issue, we present a machine learning-assisted algorithm that allows for the quantification of organelle density using the open-source Fiji platform and WEKA segmentation. Our method enables the automated quantification of organelle number, area, and density by learning from training data. This standardizes threshold selection and minimizes user intervention. We demonstrate the utility of this approach for both membrane and non-membrane organelles, such as peroxisomes, lipid droplets, and stress granules, in human cells and whole fish samples. Key features • The organelle abundance algorithm is an automated, open-source, Fiji-based tool that extracts organelle number and area and calculates abundance based on a single marker. • The macro measures the average intensity of all the segmented areas and quantifies their area. • The algorithm is applicable to cellular compartments, including membrane-bound and membrane-less organelles. • The training is performed on a sample dataset, enabling the algorithm to be applied to all images obtained with the same imaging parameters.
Text
Bio-protocol5626
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More information
Accepted/In Press date: 28 January 2026
e-pub ahead of print date: 12 February 2026
Published date: 5 March 2026
Keywords:
Abundance, Density, Fiji, Machine learning, Organelle, PeroxiSPY, Peroxisome, Quantification, Stress granule, WEKA segmentation
Identifiers
Local EPrints ID: 511704
URI: http://eprints.soton.ac.uk/id/eprint/511704
ISSN: 2331-8325
PURE UUID: c68e6ebd-c76d-4d7b-93e2-fd8580807729
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Date deposited: 28 May 2026 16:47
Last modified: 29 May 2026 02:09
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Contributors
Author:
Alexander James Long
Author:
Diogo Candeias
Author:
Nicki Frederick Coveña
Author:
Luc Reymond
Author:
Milena Schuhmacher
Author:
Stephan Kemp
Author:
Noémie Hamilton
Author:
Triana Amen
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