Developmental biology

This Review highlights the recent emergence of stem-cell-derived embryo models for the purpose of advancing our understanding of mammalian embryology as well as their potential uses in regenerative and reproductive medicine.

Epithelial tissues behave as pre-tensed viscoelastic sheets that can buffer against compression and rapidly recover from buckling. Epithelial mechanical properties define a tissue-intrinsic buckling threshold that dictates the compressive strain above which tissue folds become permanent.

A method to accelerate the generation of kidney organoids from human pluripotent stem cells cultured in a three-dimensional environment and exposed to inductive stimuli has been developed, with the organoids capable of recapitulating kidney organogenesis.

Mechanical cues play critical roles in embryonic development. A micropatterned neuroectoderm developmental model based on human pluripotent stem cells now reveals how morophogenetic signals such as cell shape and contractility regulate neural tissue development.

N-cadherin can alter how the stiffening extracellular microenvironment is interpreted by mesenchymal stem cells, leading to subsequent changes in downstream cell proliferation and differentiation.

Structure–property relationships between material properties and stem cell behaviour are investigated using high-throughput methods. The data identify the optimal substrates within a range of different polymeric surfaces to support the growth and self-renewal of human embryonic stem cells from fully dissociated single cells.