Scientists employ deep learning to analyze and compare gene regulation across various cell types in human and chicken brains.

The following is a summary of “GPX4 expression changes in proximal tubule cells highlight the role of ferroptosis in IgAN,” published in the January 2025 issue of Scientific Reports by Qing et al.

Some of the funds will be used to develop multiomics solutions based on Atrandi's proprietary technology for single-cell ...

This study provides evidence that single-cell multi-omics profiling can reveal key regulators of HIV-1 persistence and early immune dysregulation, particularly implicating KLF2 and Th17 cells as major ...

One-shot’ approach that uses machine learning to screen immune cells could help to detect conditions with overlapping ...

This valuable work presents how PRDM16 plays a critical role during colloid plexus development, through regulating BMP signaling. Solid evidence supports the context-dependent gene regulatory ...

Cell-to-cell communication is essential throughout all forms and stages of life, and many communication mechanisms are well ...

A groundbreaking study in Nature Medicine reveals that GD2 CAR-T cell therapy can lead to long-term remission in children ...

Thousands of single changes in the nucleotides that make up the human genome have been associated with an increased risk of ...

Max Planck Institute for Biological Intelligence researchers have identified over 60 transcriptomic neuron types in the ...

A new study reveals how AI-driven deep learning models can decode the genetic regulatory switches that define brain cell ...