Cell type prioritization in single-cell data
Nature biotechnology, 2021•nature.com
We present Augur, a method to prioritize the cell types most responsive to biological
perturbations in single-cell data. Augur employs a machine-learning framework to quantify
the separability of perturbed and unperturbed cells within a high-dimensional space. We
validate our method on single-cell RNA sequencing, chromatin accessibility and imaging
transcriptomics datasets, and show that Augur outperforms existing methods based on
differential gene expression. Augur identified the neural circuits restoring locomotion in mice …
perturbations in single-cell data. Augur employs a machine-learning framework to quantify
the separability of perturbed and unperturbed cells within a high-dimensional space. We
validate our method on single-cell RNA sequencing, chromatin accessibility and imaging
transcriptomics datasets, and show that Augur outperforms existing methods based on
differential gene expression. Augur identified the neural circuits restoring locomotion in mice …
Abstract
We present Augur, a method to prioritize the cell types most responsive to biological perturbations in single-cell data. Augur employs a machine-learning framework to quantify the separability of perturbed and unperturbed cells within a high-dimensional space. We validate our method on single-cell RNA sequencing, chromatin accessibility and imaging transcriptomics datasets, and show that Augur outperforms existing methods based on differential gene expression. Augur identified the neural circuits restoring locomotion in mice following spinal cord neurostimulation.
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