Browse our latest Stem Cells and Regenerative Medicine articles

The IRE1/XBP1 signaling in myofibers is essential for robust skeletal muscle regeneration in response to injury.

Comparative analysis of cardiac mitogenic pathways identified a potent human gene that is effective at driving in vitro cell cycle activation across species and cell culture systems.

Somatic stem and niche cells in the Drosophila ovary develop from common precursors through regulated proliferative expansion, followed by acquisition of position-specific behaviors, rather than through rigid early specification events.

Lineage tracing and genetic experiments resolve a long-standing controversy by showing that retinoic acid signaling is active in cardiomyocytes, both during development and after myocardial infarction, and protects damaged hearts from apoptosis.

The nutrient composition of food alters both the size of gut epithelial cells and the ability of the stem cell niche to control tissue turnover, resulting in changes in size at the organ level.

Filopodia driven by class X myosin promote the fusion of mammalian myoblasts in the development of skeletal muscle and are important for the regeneration of skeletal muscle following muscle injury.

A new genetically engineered mouse strain is described in which miRNA activity can be acutely and reversibly inhibited, showing that in a subset of adult tissues miRNA activity is dispensable under homeostatic conditions but becomes essential during tissue regeneration.

An integrated stem cell-based disease modeling and computational approach demonstrates how proximal airway epithelium is critical for SARS-CoV-2 infectivity and distal alveolar cells are critical for simulating the host responses.

Systemic but not locally produced thrombopoietin promotes hematopoietic stem cell regeneration after myeloablation.

IL6ST (gp130) binding proteins, such as HyperIL6, promote liver regrowth in a STAT3-indpependent manner through competitive inhibition of anti-regenerative IL11 signaling.