Harnessing Machine Learning to Analyze Single-Cell Data: Insights on Cancer and Covid

Self-Supervised Learning Artificial Intelligence in Biomedicine: A key to Analyzing Millions of Individual Cells

2025-01-25 Source: Technical University of Munich (TUM) 2 min Reading Time

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Unlocking the secrets of individual cells, researchers are harnessing the power of self-supervised learning to analyze massive single-cell datasets. A study from TUM reveals how innovative machine learning methods can reshape our understanding of diseases like cancer and Covid.

Fabian Theis, Professor of Mathematical Modeling of Biological Systems(Source: Astrid Eckert / TUM) — Fabian Theis, Professor of Mathematical Modeling of Biological Systems
(Source: Astrid Eckert / TUM)

In recent years, researchers have made considerable progress with single-cell technology. This makes it possible to investigate tissue on the basis of individual cells and simply to determine the various functions of the individual cell types. The analysis can be used, for instance, to make comparisons with healthy cells to find out how smoking, lung cancer or a Covid infection change individual cell structures in the lung.

At the same time, the analysis is generating ever-increasing quantities of data. The researchers intend to apply machine learning methods to support the process of re-interpreting existing datasets, deriving conclusive statements from the patterns and applying the results to other areas.

Fabian Theis holds the Chair of Mathematical Modelling of Biological Systems at TUM. With his team, he has investigated whether self-supervised learning is more suitable for the analysis of large data quantities than other methods. The study was recently published in Nature Machine Intelligence. This form of machine learning works with unlabelled data. No classified sample data are required in advance. That means that it is not necessary to pre-assign the data to certain groups in advance. Unlabelled data are available in large quantities and permit the robust representation of enormous data volumes.

Using the Mutrank framework trained with Evorank, Danny Diaz and professor Andrew Ellington’s team are developing an improved version of a protein critical for the biomanufacturing of mRNA therapeutics and vaccines. In this example, the model recommends keeping the blue parts the same as the natural version of the protein and strongly considering mutating the red parts. (Source: Danny Diaz/University of Texas at Austin)

Self-supervised learning is based on two methods. In masked learning — as the name suggests — a portion of the input data is masked and the model is trained to be able to reconstruct the missing elements. In addition, the researchers apply contrastive learning in which the model learns to combine similar data and separate dissimilar data.

The team used both methods of self-supervised learning to test more than 20 million individual cells and compared them with the results of classical learning methods. In their assessment of the different methods, the researchers focused on tasks such as predicting cell types and the reconstruction of gene expression.

Prospects for the Development of Virtual Cells

The results of the study show that self-supervised learning improves performance especially with transfer tasks — that is, when analyzing smaller datasets informed by insights from a larger auxiliary dataset. In addition, the results of zero-shot cell predictions — in other words, tasks performed without pre-training — are also promising. The comparison between masked and contrastive learning shows that masked learning is better suited for applications with large single-cell data sets.

The researchers are using the data to work on the development of virtual cells. These are comprehensive computer models that reflect the diversity of cells in different datasets. These models are promising for the analysis of cellular changes as seen with diseases, for example. The results of the study offer valuable insights into how such models could be trained more efficiently and further optimized.

Original Article: Delineating the effective use of self-supervised learning in single-cell genomics; Nature Machine Intelligence; DOI:10.1038/s42256-024-00934-3

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Date: 08.12.2025

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