Covers how bacteria sense and respond to forces, exploring bacterial cell structures, adhesion mechanisms, motility, and mechanotransduction.
Explores the mechanobiology of biofilms, focusing on Piezo channels, biofilm architecture, and matrix components.
Explores the mechanobiology of cell growth, focusing on essential components, force curve-based sample characterization, and the impact of turgor pressure on growth.
Explores the mechanics of animal cells, including actin assembly and retrograde flow.
Covers the structure and mechanics of mammalian cells, adhesion, mechanosensation, mechanotransduction, Rho signaling, actin dynamics, specialized actin organizations, integrins, and nuclear mechanotransduction.
Explores methods to measure cell mechanics using various substrates and discusses the mechanics of cell clusters and epithelial tissues.
Delves into how mechanical forces impact cancer progression through nuclear size control, matrix stiffness, and metastasis.
Covers the formation and applications of organoids, including brain, skin, and intestinal organoids, as well as the engineering of tissues and the concept of organ-on-a-chip.
