https://www.selleckchem.com/products/Nafamostat-mesylate.html Bacterial biofilms represent a basic form of multicellular organization that confers survival advantages to constituent cells. The sequential stages of cell ordering during biofilm development have been studied in the pathogen and model biofilm-former Vibrio cholerae How do the spatial trajectories of individual cells and the collective motions of many cells drive biofilm expansion? We developed dual-view light-sheet microscopy to investigate biofilm developmental dynamics from a founder cell to a mature three-dimensional community. Tracking of individual cells revealed two distinct fates one set of biofilm cells expanded ballistically outward, while the other became trapped at the substrate. A collective fountain-like flow transported cells to the biofilm front, bypassing members trapped at the substrate and facilitating lateral biofilm expansion. This collective flow pattern was quantitatively captured by a continuum model of biofilm growth against substrate friction. Coordinated cell movement required the matrix protein RbmA, without which cells expanded erratically. Thus, tracking cell lineages and trajectories in space and time revealed how multicellular structures form from a single founder cell.Cerebrospinal fluid (CSF) is a vital liquid, providing nutrients, signaling molecules, and clearing out toxic byproducts from the brain. The CSF is produced by the choroid plexus (ChP), a protective epithelial barrier that also prevents free entry from the blood. Here, we establish human ChP organoids with a selective barrier and CSF-like fluid secretion in self-contained compartments. We show that this in vitro barrier exhibits the same selectivity to small molecules as in vivo, and that ChP-CSF organoids can predict CNS permeability of novel compounds. The transcriptomic and proteomic signature of ChP-CSF organoids reveal a high degree of similarity to in vivo. Finally, the intersection of single cell tran