“During tissue formation, dynamic cell shape changes drive morphogenesis while asymmetric divisions create cellular diversity ...

Single-cell biology has transformed how we decode cellular heterogeneity, but a new frontier is emerging: understanding what ...

New research reveals that cells don't always become round before dividing, challenging over a century of textbook biology.

The unusual molecular makeup of Borrelia burgdorferi, which causes Lyme disease, may hold clues for understanding and treating the tick-borne disease.

An innovative imaging technique developed at Carnegie Mellon University reveals single bacterial cells leaving their biofilm ...

Researchers revealed that mitosis doesn’t always feature cell rounding (when a parent cell becomes spherical), meaning that ...

A recent study marks the first reported instance of generative AI designing synthetic molecules that can successfully control gene expression in healthy mammalian cells. As a proof-of-concept, the ...

Influenza viruses are among the most likely triggers of future pandemics. A research team from the Helmholtz Center for Infection Research (HZI) and the Medical Center—University of Freiburg has ...

A study of human tumor cells implanted in mice from the MacPherson Lab at Fred Hutch describes a new way to screen for the ...

Malek Elsayyid is UD's first student to complete the Lerner College's Generative AI for Business graduate certificate program ...

The mitochondrion, often referred to as the powerhouse of the cell, plays critical roles in cellular function, making it a prime organelle to target for fundamental studies, metabolic engineering, and ...

Until now, cells dividing by mitosis were thought to grow round and then split into two identical, spherical daughter cells. New research has found that some cells are isomorphic, meaning they ...