20 articles
New technique simultaneously tracks cell division and gene activity in living tissues, revealing hidden repair mechanisms.
A new nanopore-based approach aims to sequence peptides by reversing the translation process, potentially transforming proteomics.
Comprehensive review of emerging single-cell technologies that simultaneously analyze DNA, RNA, and proteins from individual cells, revolutionizing cancer diagnosis and treatment.
Revolutionary technique sequences individual protein molecules by converting them to DNA, enabling precise protein analysis.
Revolutionary pathology technique reveals how diseases spread and interact across different tissues in unprecedented detail.
New spatial mapping reveals how gene therapy vectors differently affect male and female liver function and metabolism.
Scientists discover muscle cells bypass normal nuclear pores to export oversized RNA transcripts via a newly identified budding pathway.
A new AI tool called SIGnature decodes gene importance in single cells, linking a severe COVID-19 signature to Kawasaki disease.
A new technique called PIVOT enables single-cell functional genetic screens in plants, opening doors to precision crop and botanical medicine research.
A landmark multi-omics atlas of human kidney tissue reveals how proximal tubule cells shift between repair and disease states after injury.
Advanced protein analysis methods could revolutionize early disease detection and personalized medicine approaches.
Breakthrough gene editing technique dramatically increases plant protein production, potentially revolutionizing crop nutrition.
Revolutionary sequencing method uncovers complete bacterial genomes from gut samples, revealing previously invisible microbes.
A UC Berkeley spinout is developing a one-time gene therapy using transposons to sustain GLP-1 activity โ potentially replacing daily weight loss drugs.
A landmark review maps the three pillars of modern lineage tracing and how they're reshaping our understanding of cell fate decisions.
New biotechnology breakthrough enables cells to store mRNA data for later retrieval, opening possibilities for advanced health monitoring.
Revolutionary AI can interpret and generate DNA, RNA, and proteins simultaneously, potentially transforming disease research and drug discovery.
Revolutionary nanoneedle technology creates molecular replicas of living brain tissue, enabling repeated monitoring of glioma progression and treatment response.
Go deeper into how exosomes are built, what they carry, and how their molecular cargo rewires receiving cells โ with implications for regeneration, aging, and emerging therapies.
A rigorous mechanistic deep-dive into the molecular logic of partial reprogramming โ from chromatin dynamics and epigenetic clock reversal to in vivo delivery strategies, oncogenic risks, and the path to clinical translation.
