
Scientists Decode Diet From Stool DNA – No Questions Asked
ISB’s Gibbons Lab developed a breakthrough method that analyzes food-derived DNA in fecal metagenomes, allowing for data-driven diet tracking without the need for burdensome questionnaires.
ISB’s Gibbons Lab developed a breakthrough method that analyzes food-derived DNA in fecal metagenomes, allowing for data-driven diet tracking without the need for burdensome questionnaires.
We are deeply saddened to share the passing of renowned artist Ginny Ruffner earlier this year at 72. Ginny has long been an integral part of ISB’s community. Her vibrant artwork continues to bring life to our spaces, and her advocacy as a Foundation Board member leaves a lasting legacy.
ISB hosted the Systems Biology of Aging Virtual Workshop in May 2024 for graduate students, postdocs, principal investigators, industry scientists, and educators. The course provided practical tools for performing multi-omic systems biology analyses to advance the study of aging.
Dr. Sean Gibbons is creating a new precision nutrition platform called My Digital Gut that leverages the gut microbiome to make nutrition and healthcare personalized, predictive, and preventive. In an ISB Research Roundtable presentation, Gibbons spoke about My Digital Gut and other microbiome-related projects studied in his lab.
A new study unveils important insights and actionable protocols into providing equitable STEM experiences for high school students from historically marginalized communities. The research highlights the transformative power of informal STEM learning and the ease with which many organizations could provide these opportunities.
Infection, autoimmunity and cancer account for 40 percent of deaths worldwide. In a Cell Reports paper, ISB researchers detail how the human immune system works in common ways across diseases – findings that offer promising avenues for exploring multi-disease therapeutic strategies.
ISB hosted a free one-day Spatial Multi-Omics for Cancer Systems Biology virtual workshop. The event consisted of sessions on four topics: experimental methods, computational algorithms, applications of spatial multi-omics and a practical methods tutorial.
In a breakthrough discovery that changes how we understand T cells and with implications of how we can better engineer custom immune responses to fight disease, Institute for Systems Biology researchers showed that the different disease-fighting functions of different T cells are determined by the genetically encoded T-cell receptor sequence that are unique to those cells.